* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Document
Hydrogen atom wikipedia , lookup
Electromagnetism wikipedia , lookup
Renormalization wikipedia , lookup
Electromagnetic mass wikipedia , lookup
Work (physics) wikipedia , lookup
Anti-gravity wikipedia , lookup
Photon polarization wikipedia , lookup
Quantum chromodynamics wikipedia , lookup
Negative mass wikipedia , lookup
Fundamental interaction wikipedia , lookup
Conservation of energy wikipedia , lookup
Nuclear drip line wikipedia , lookup
Strangeness production wikipedia , lookup
Standard Model wikipedia , lookup
History of subatomic physics wikipedia , lookup
Wave–particle duality wikipedia , lookup
Atomic nucleus wikipedia , lookup
Theoretical and experimental justification for the Schrödinger equation wikipedia , lookup
Elementary particle wikipedia , lookup
Conservation Laws Conservation Laws Conservation laws in Physics can give explanations as to why some things occur and other do not. Three very important Conservation Laws are: I. Conservation of Energy II. Conservation of Momentum III. Conservation of Charge Energy Conservation (I) There are many forms of energy. For now, we’ll focus on two types 1. Kinetic Energy (KE) – Energy of motion KE = ½ mv2 if v is much less than c (v << c) 2. Mass Energy m = mass c = speed of light = 3x108 [m/sec] E = mc2 That is, mass is a form of energy, and the “conversion” is to just multiply the mass by a constant number (the speed of light squared)! Conservation of Energy (II) Total Energy (initially) = ED = mDc2 D Suppose D “decays” into 2 particles A and B, what is the energy of the system afterward? vA A B vB Total Energy (after decay) = EA + EB = (KEA+mAc2) + (KEB+mBc2) Since energy must be conserved in the “decay” process, mDc2 = (KEA+mAc2) + (KEB+mBc2) Conservation of Energy (III) mDc2 = (KEA+mAc2) + (KEB+mBc2) ED Before Decay EA EB After Decay Important points here: 1) This equation DOES NOT say that kinetic energy is conserved 2) This equation DOES NOT say that mass is conserved 3) This equation states that the total energy is conserved è Total energy before decay = Total energy after decay Conservation of Energy (IV) mDc2 = (KEA+mAc2) + (KEB+mBc2) KEA = ½ mAvA2 >0 KEB = ½ mBvB2 > 0 Since mA and mB must be larger than zero, and vA2>0 and vB2>0, the KE can only be positive (KE cannot be negative!) If I subtract off the KE terms from the RHS* of the top equation, I will no longer have an equality, but rather an inequality: mDc2 … mAc2 + mBc2 and dividing both sides by c2, mD … mA + mB This is also true if particle D has KE>0 also! Conservation of Energy (V) KEA MAc2 MBc2 KEB MDc2 LHS = RHS MAc2 MBc2 MDc2 LHS > RHS Energy Conservation (VI) Consider some particle (call it “D”) at rest which has a mass of 0.5 kg D Which of the following reactions do you think can/cannot occur? I A D B mB=0.1 kg mA=0.2 kg II A D B mA=0.2 kg mB=0.4 kg III A mA=0.49 kg IV A B D D B mB=0.0 kg mA=0.1 kg mB=0.1 kg Energy Conservation (VII) A particle (q) and an anti-particle (q) of equal mass each having 1 [TeV] of energy collide and produce two other particles t and t (of equal mass) as shown in Fig. A. (1 [TeV] = 1012 [eV]) Fig. A t q Bam t q Energy Conservation (VIII) q What is the total energy in the collision ? A) 0 B) 2 [TeV] C) 1 [TeV] D) 0.5 [TeV] q What is total energy of the t and t (individually)? A) 0 B) 2 [TeV] C) 1 [TeV] D) 0.5 [TeV] q What can be said about the mass energy of the “t” particle ? A) It’s equal to the mass of “q” B) It must be less than 0.5 TeV C) It must be less than 1 [TeV] D) It’s equal but opposite in direction to that of the t particle Momentum Conservation (I) Momentum (p) = mass x velocity = mv p = mv Momentum has a direction, given by the direction of v m1 v1 p2 = -m2v2 p1 = m1v1 v2 m2 Note that particles moving in opposite directions have momenta which are opposite sign! Momentum Conservation: In any process, the value of the total momentum is conserved. Momentum Conservation (II) Consider a head-on collision of two particles m1 v1 v2 m2 What is the total momentum before the collision ? A) m1v1+m2v2 B) m1v2-m2v1 C) zero D) (m1+m2)(v1+v2) If m1= m2, what can be said about the total momentum? A) it’s zero B) it’s positive C) it’s negative D) can’t say? If m1= m2 and v1 > v2, what can be said about the total momentum? A) it’s zero B) it’s positive C) it’s negative D) can’t say? Momentum Conservation (III) Consider a head-on collision of two particles m1 v1 v2 m2 If m1< m2 and v1 > v2, what can be said about the total momentum? A) it’s zero B) it’s positive C) it’s negative D) can’t say? If m1= m2 and v1 = v2 (in magnitude), what can be said about the total momentum? A) it’s zero B) it’s positive C) it’s negative D) can’t say? In this previous case, what can be said about the final velocities of particles 1 and 2 ? A) their zero B) equal and opposite C) both in the same direction D) can’t say? Momentum Conservation (IV) Consider a particle D at rest which decays into two lighter particles A and B, whose combined mass is less than D. I vA A D mA mB B vB If mA > mB, answer the following questions: q What can be said about the total momentum after the decay? A) Zero B) Equal and Opposite C) Equal D) Opposite, but not equal q If mA= mB, what can be said about the magnitudes of the velocities of A and B? A) vA>vB B) Equal and Opposite C) vB>vA D) Same direction but different magnitudes Momentum Conservation (V) I vA A D mA mB B vB q Which statement is most accurate about the momentum of A ? A) Zero B) Equal to B C) Equal and opposite to B D) Opposite, but not equal q Can mA+mB exceed mD ? A) Not enough data C) No B) Yes, if vA and vB are zero D) Yes, if vA and vB are in opposite directions Momentum Conservation (VI) p mP e me n ν Consider a neutron, n, which is at rest, and then decays. mp+me < mn Can this process occur? a) No, momentum is not conserved b) Yes, since mn is larger than the sum of mP and me c) No, energy cannot be conserved d) Yes, but only between 8 pm and 4 am The observation that momentum was not conserved in neutron decay lead to the profound hypothesis of the existence of a particle called the neutrino neutron à proton + electron + neutrino (n à p + e + ν) When the neutrino is included, in fact momentum is conserved. Discovery of the Neutrino p mP e me n ν The observation that momentum conservation appeared to be violated in neutron decay lead to the profound hypothesis of the existence of a particle called the neutrino neutron à proton + electron + neutrino (n à p + e + ν) When the neutrino is included, in fact momentum is conserved. Charge Conservation The total electric charge of a system does not change. Consider the previous example of neutron decay: Charge n 0 à p +1 + e -1 ν 0 + Can these processes occur? p + p Charge +1 +1 p + e Charge +1 0 0 p + +1 à -1 n + n Charge à ν 0 + 0 à p +1 n n 0 + NO YES p +1 NO Summary of Conservation Laws q Total Energy of an isolated system is conserved D à A+B cannot occur if mA+mB > mD q Total momentum of an isolated system is conserved - missing momentum in neutron decay signaled the existence of a new undiscovered particle q Total Charge of an isolated system is conserved - the sum of the charges before a process occurs must be the same as after the process We will encounter more conservation laws later which will help explain why some processes occur and others do not. Matter and energy “Mass and energy are two different aspects of the same thin Atoms An atoms, a basic unit of matter, is a packet of energy with el The Vibration of Matter he energy contained in atoms and molecules makes them vibrate a this vibration produces heat. Matter expands with heat. Plasma n a gas atom like hydrogen, when the vibration increases the hea makes the atom expand more and lose its electron. Thanks for Attention! Clause Types … and … Independent & Dependent Let’s start with a simple sentence… I bought a book. This sentence has the three basic elements required of either a simple sentence or a clause: Subject = I Verb = bought Object = a book Now, let’s add another clause … While herher coffee, I bought Whilemy mymother motherdrank drank coffee, I abought book. a book. Now we have a two clause sentence, but these clauses are not the same. The original clause I bought a book can stand on its own as a simple sentence. It expresses a complete thought by itself. Therefore, it is called an independent clause. Independent Clause (IC) An independent clause is a S + V / O bject or C omplement or A dverbial unit that expresses a complete thought and could stand on its own as a simple sentence. Whether you find an independent clause by itself as a simple sentence or joined with other clauses, you will be able to identify it because it: – is a S+V/ unit that – expresses a complete thought But what about the other clause? While my mother drank her coffee, I bought a book. If we only consider the first clause, while my mother drank her coffee, we are left with a question in our minds, “What happened while your mother drank her coffee?!” This clause can not stand on its own as a simple sentence. It requires another clause to a complete its meaning. Therefore, it is called an dependent clause. Dependent Clause (DC) A dependent clause is a S + V / O bject or C omplement or A dverbial unit that does not express a complete thought and can not stand on its own as a simple sentence. A dependent clause must always be connected to an independent clause. You will be able to identify it because it: – is a S+V/ unit that – does not express a complete thought on its own Dependent Clauses There are 3 different types of dependent clauses. • Noun Clause (NC) • Adjective Clause (AdjC) • Adverb Clause (AdvC) Noun Clause (NC) • [S+V/] that acts like a noun I think [you sick]. • Example: I think [you areare sick]. S V O Objects are nouns; this entire clause acts like a singular noun, so it is a noun clause. • NCs usually follow verbs as objects or complements •“Answers” the question “What?” • Example: • Q: What do you think? • A: I think Spiderman is the best Noun Clause (NC) -- continued • NCs can begin with “that” • “that” is a subordinating conjunction that • joins it to an IC • makes the clause it begins depend on the IC to complete its meaning. • “that” is often omitted by native speakers: • Example: thinkthat Spiderman is the bestbest superhero. I Ithink Spiderman is the superhero. Adjective Clause (AdjC) • [S+V/] that acts like an adjective • Example: The story [that [that I am reading] is sad. I am reading] S V relative pronoun This entire clause acts like an adjective, so it is an adjective clause. • AdjCs follow nouns • Often start with relative pronouns • but the relative pronoun can be omitted • if the clause has another noun to serve as the subject Adverb Clause (AdvC) • [S+V/] that acts like an adverb • Example: [After we drove to the mall] , we looked for a bookstore. This clause gives information about how or why the action happened, so it acts like an adverb. • AdvCs always begin with a subordinating conjunction • after although even though when if as since because unless before until Clauses: Building Blocks for Sentences A clause is a group of related words containing a subject and a verb. It is different from a phrase in that a phrase does not include a subject and a verb relationship. There are many different kinds of clauses. It would be helpful to review some of the grammar vocabulary we use to talk about clauses. Words and phrases in this color are hyperlinks to the Guide to Grammar & Writing. Clauses: Building Blocks for Sentences Clauses go by many names. Here are some definitions: 1. Independent: A clause that can stand by itself and still make sense. An independent clause could be its own sentence, but is often part of a larger structure, combined with other independent clauses and with dependent clauses. Independent clauses are sometimes called essential or restrictive clauses. 2. Dependent: A clause that cannot stand by itself. It depends on something else, an independent clause, for its meaning. A dependent clause trying to stand by itself would be a sentence fragment. Dependent clauses are sometimes called subordinate, nonessential, or nonrestrictive clauses. We will review the different kinds of dependent clauses. Clauses: Building Blocks for Sentences And here are some examples of independent clauses . . . . 1. Independent clauses: • Glaciers often leave behind holes in the ground. • These holes are called kettles, and they look just like scooped-out pots. • Glaciers also leave behind enormous deposits of glacial “garbage”; these deposits are called morains. •Kettle holes result when a large block of ice is left behind the glacier and then melts away, leaving a large depression. This last sentence deserves further attention . . . . Clauses: Building Blocks for Sentences Notice that this sentence consists of a very brief independent clause followed by a long and complex dependent clause. •Kettle holes result when a large block of ice is left behind the glacier and then melts away, leaving a large depression. The dependent clause begins with what is called a subordinating conjunction. This causes the clause to be dependent upon the rest of the sentence for its meaning; it cannot stand by itself. More on dependent clauses in a moment. . . . Clauses: Building Blocks for Sentences Independent clauses can be connected in a variety of ways: 1. By a comma and little conjunction (and, but, or, nor, for, yet, and sometimes so). 2. By a semicolon, by itself. 3. By a semicolon accompanied by a conjunctive adverb (such as however, moreover, nevertheless, as a result, consequently, etc.). 4. And, of course, independent clauses are often not connected by punctuation at all but are separated by a period. Clauses: Building Blocks for Sentences Dependent clauses can be identified and classified according to their role in the sentence. Noun clauses do anything that a noun can do. They can be subjects, objects, and objects of prepositions. • What Turveydrop has forgotten about American politics could fill entire libraries. • President Johnson finally revealed what he had in mind for his congressional leaders. • Sheila Thistlethwaite has written a marvelous book about how American politics and economic processes often run counter to common sense. Clauses: Building Blocks for Sentences Dependent clauses can be identified and classified according to their role in the sentence. ADVERB CLAUSES tend to tell us something about the sentence’s main verb: when, why, under what conditions. • After Jubal Early invaded the outskirts of Washington, Congressional leaders took the southern threat more seriously. • Lincoln insisted on attending the theater that night because it was important to demonstrate domestic tranquility. Notice how the dependent clauses begin with “dependent words,” words that subordinate what follows to the rest of the sentence. These words are also called subordinating conjunctions. Clauses: Building Blocks for Sentences Dependent clauses can be identified and classified according to their role in the sentence. ADJECTIVE CLAUSES modify nouns or pronouns in the rest of the sentence.. • The Internet, which started out as a means for military and academic types to share documents, has become a household necessity. • Tim Berners-Lee, who developed the World Wide Web, could never have foreseen the popularity of his invention. •The graphical user interface (GUI) that we all take for granted nowadays is actually a late development in the World Wide Web. Notice, now, how the subject is often separated from its verb by information represented by the dependent clause. Clauses: Building Blocks for Sentences Sometimes an adjective clause has no subject other than the relative pronoun that introduces the clauses. The Internet was started in 1969 under a contract let by the Advanced Research Projects Agency (ARPA) which connected four major computers at universities in the southwestern US (UCLA, Stanford Research Institute, UCSB, and the University of Utah). Such clauses — all beginning with “which,” “that,” or a form of “who” — are also known as RELATIVE CLAUSES. The relative pronoun serves as the subject of the dependent clause and relates to some word or idea in the independent clause. Clauses: Building Blocks for Sentences Understanding CLAUSES and how they are connected within the larger structure of your sentence will help you avoid Sentence Fragments Run-on Sentences and make it possible for you to punctuate your sentences properly and write confidently with a variety of sentence structures. Don’t forget to take the quizzes listed at the end of the section on clauses. This PowerPoint presentation was created by Charles Darling, PhD Professor of English and Webmaster Capital Community College Hartford, Connecticut copyright November 1999 DISCOVERIES The Picture by ~1932 q Electrons were discovered ~1900 by J. J. Thomson q Protons being confined in a nucleus was put forth ~1905 q Neutrons discovered 1932 by James Chadwick q Quantum theory of radiation had become “widely accepted”, although even Einstein had his doubts Quick recap on radiation from atoms q Energetic gamma rays come from excited nuclei (Co60, for example) These photons emerge from the nucleus of the atom !!! q They are generally in the gamma ray region of the EM spectrum -----------------------------------------------------------------------------q Ordinary atoms also radiate photons when their atomic electrons “fall” from a higher energy state to a lower one. (The configuration where all the electrons are in their lowest energy state is referred to as the ground state) q The transitions of atomic electrons from a high energy state to a lower energy state produces radiation (light)! q The radiation which emerges when electrons make these transitions (ie., quantum transitions) is generally the visible X-ray region. Let’s continue on this issue of in transitions in or atoms… Bohr Atom & Radiation Before Electrons circle the nucleus due to the Electric force After Radiated photon n= 5 4 3 2 Electron in lowest “allowed” energy level (n=1) 5 4 3 2 1 Electron in excited state (n=5) Allowed Orbits 1 Electron falls to the lowest energy level Note: There are many more energy levels beyond n=5, they are omitted for simplicity Atomic Radiation It is now “known” that when an electron is in an “excited state”, it spontaneously decays to a lower-energy stable state. The difference in energy, ∆E, is given by: E5 > E4 > E3 > E2 > E1 ∆E = E5 – E1 = hν = Εphoton One example could be: Energy E5 Electron in excited state (higher PE) Energy Electron in lowest state (lower PE) n=5 E5 n=5 E4 n=4 E4 n=4 E3 n=3 E3 n=3 E2 n=2 E2 n=2 E1 n=1 E1 n=1 Before After h = Planck’s constant = 6.6x10-34 [J s] ν = frequency of light [hz] The energy of the light is DIRECTLY PROPORTIONAL to the frequency, ν. Recall that the frequency, ν, is related to the wavelength by: c=νλ (ν = c / λ) So, higher frequency è higher energy è lower wavelength This is why UV radiation browns your skin but visible light does not ! Hydrogen atom energy “levels” Quantum physics provides the tools to compute the values of E1, E2, E3, etc…The results are: 2 En = -13.6 / n 5 4 3 2 1 Energy Level Energy En (eV) 1 -13.6 2 -3.4 3 -1.51 4 -0.85 5 -0.54 These results DO DEPEND ON THE TYPE OF ATOM OR MOLECULE So, the difference in energy between the 3rd and 1st quantum state is: Ediff = E3 – E1 = -1.51 – (-13.6) = 12.09 (eV) When this 3à 1 atomic transition occurs, this energy is released in the form of electromagnetic energy. Example 4 In the preceding example, what is the frequency, wavelength of the emitted photon, and in what part of the EM spectrum is it in? E = 12.1 [eV]. First convert this to [J]. 1.6x10-19 [J] −18 12.1 [eV] = 1.94 x10 [J] 1 [eV] Since E = hν è ν = E/h, so: ν = E/h = 1.94x10-18 [J] / 6.6x10-34 [J s] = 2.9x1015 [1/s] = 2.9x1015 [hz] λ = c/ν = (3x108 [m/s]) / (2.9x1015 [1/s]) = 1.02x10-7 [m] = 102 [nm] This corresponds to low energy X-rays ! Some Other Quantum Transitions Initial State 2 Final State 1 Energy diff. [eV] 10.2 Energy diff. Wavelength Region [J] [nm] 1.6x10-18 121 X-ray 3 1 12.1 1.9x10-18 102 X-ray 4 1 12.8 2.0x10-18 97 X-ray 3 2 1.89 3.0x10-19 654 Red 4 2 2.55 4.1x10-19 485 Aqua 5 2 2.86 4.6x10-19 432 Violet This completed the picture, or did it… q Electrons were discovered ~1900 by J. J. Thomson q Protons being confined in a nucleus was put forth ~1905 q Neutrons discovered 1932 by James Chadwick q Quantum theory of radiation had become “widely accepted”, although even Einstein had his doubts q Radiation is produced when atomic electrons fall from a state of high energy à low energy. Yields photons in the visible/ X-ray region. q A nucleus can also be excited, and when it “de-excites” it also gives Cosmic Rays q Cosmic Rays are energetic particles that impinge on our atmosphere (could be from sun or other faraway places in the Cosmos) q They come from all directions. q When these high energy particles strike atoms/molecules in our atmosphere, they produce a spray of particles. q Many “exotic” particles can be created. As long as they are not so massive as to violate energy conservation they can be created. q Some of these particles are unstable and “decay” quickly into other stable particles. q Any of these exotic particles which live long enough to reach the surface of the earth can be detected ! Discoveries in Cosmic Rays Ø 1932 : Discovery of the antiparticle of the electron, the positron. Confirmed the existence and prediction that anti-matter does exist!!! Ø 1937 : Discovery of the muon. It’s very much like a “heavy electron”. Ø 1947 : Discovery of the pion. We’ll touch on these today… and some other things… Positron Discovery in Cosmic Rays (1932) Cloud Chamber Photograph A “Cloud Chamber” is capable of detecting charged particles as they pass through it. The chamber is surrounded by a magnet. The magnet bends positively charged particles in one direction, and negatively charged particles in the other direction. Lead plate Positron Larger curvature of particle above plate means it’s moving slower (lost energy as it passed through) By examining the curvature above and below the lead plate, we can deduce: (a) the particle is traveling upward in this photograph. (b) it’s charge is positive It’s a particle who’s mass is same Using other information about howasfarelectron it but has positive è it’s POSITRON ! traveled, it can becharge deduced not a proton. Significance of Positron Discovery The positron discovery was the first evidence for ANTIMATTER. That is, the positron has essentially all the same properties as an electron, except, it’s charge is positive ! Carl Anderson award Nobel prize for the discovery of the positron Carl Anderson 1905-1991 If an electron and a positron collide, they ANNIHILATE and form pure energy (EM Radiation). This conversion of matter into energy is a common event in the life of physicists that studies these little rascals… Example: Matter à Energy E=5 [MeV] E=5 [MeV] ee++ E=5 [MeV] e+ e+ %*&* e+ e- e- E=5 [MeV] e- e- An electron and positron, each with energy 5 [MeV] collide, and annihilate into pure energy in the form of 2 photons. Each photon carries away ½ of the total energy available. Example follow-up In the preceding example, what are the wavelengths of the photons which emerge from this interaction, and from what part of the spectrum are they? Since E=hc / λ, We can get wavelength using: λ = hc/ E First we need to convert the 5 [MeV] to the equivalent number of [J] First note that: 5 [MeV] = 5x106 [eV] -19 1.6x10 [J] = 8.0 x10−13[J] 5x106 [eV] 1 [eV] =1 λ = hc/ E = (6.6x10-34)(3x108) / 8.0x10-13 = 2.5x10-13 [m] You will find that this corresponds to gamma rays ! Very energetic photons !!! Discovery of the muon q The muon was discovered in 1937 by J. C. Street and E. C. Stevenson in a cloud chamber. q Again, the source is cosmic rays produced in the atmosphere. q The muon behaves identally to an electron, except: It is about 200 times as massive on these ν guys later ! q It’s unstable, and decays in about 2x10-6 [s]More = 2 [µs] q Note that many muons are able to reach the earth from the upper (µ à e + νdilation + ν) ! Because of their large speed, we atmosphere because of time observe that their “clocks” run slow è they can live longer !!! Discovery of the Pion q Cecil Powell and colleagues at Bristol University used alternate types of detection devices to see charged tracks (called “emulsions”) in the upper atmosphere. q In 1947, they annouced the discovery of a particle called the π-meson or pion (π) for short. Pion (π) comes to rest here, and then decays: πàµ+ν+ν Muon (µ) comes to rest here, and then decays: µàe+ν+ν Two neutrinos are also produces but escape undetected. Two more neutrinos are also produced but also escape undetected. µ e π Cecil Powell 1903-1969 1950 Nobel Prize winner The Plethora of Particles Because one has no control over cosmic rays (energy, types of particles, location, etc), scientists focused their efforts on accelerating particles in the lab and smashing them together. Generically people refer to them as “particle accelerators”. (We’ll come back to the particle accelerators later…) Circa 1950, these particle accelerators began to uncover many new particles. Most of these particles are unstable and decay very quickly, and hence had not been seen in cosmic rays. Notice the discovery of the proton’s antiparticle, the antiproton, in 1955 ! Energy What is Energy From Merriam Webster: Energy: The capacity for doing work (or to produce heat) What are some forms/types of energy? 1. Energy of motion (kinetic energy) É 2. Heat 3. Electricity É 4. Electromagnetic waves - like visible light, x-rays, UV rays, microwaves, etc É 5. Mass É Huh, what do you mean mass is a form of energy? We’ll get to this later…. i The thing about energy is that it cannot be created or destroyed, it can only be transformed from one form into another Energy Conservation Like momentum, energy is a conserved quantity. This provides powerful constraints on what can and cannot happen in nature. This is an extremely important concept, and we will come back to this over and over throughout the remainder of the course. Kinetic Energy – Energy of Motion Kinetic energy (KE) refers to the energy associated with the motion of an object. The kinetic energy is simply: KE = (½)mv2 where m = mass in [kg], v = velocity of object in [m/sec] and What are the units of KE? [KE] = [mass] [velocity]2 = [kg*m2/s2] == [Joule] or just, [J] A Joule is a substantial amount of energy! Energy q The unit, [Joules] applies to all forms of energy, not just KE. q As we’ll see later, there are sometimes more convenient units to use for energy. q You have probably heard of the unit “Watt”. For example, a 100 Watt light bulb? A Watt [W] is simply energy usage per unit time, or [J/s]. q So, 100 [W] means the bulb uses 100 [J] per second! q How many [J] are used by a 100 [W] bulb in 2 minute? A) 200 [J] B) 1200 [J] C) 12000 [J] D) 2000 [J] Kinetic Energy Examples What is the kinetic energy of a 1 [kg] mass moving at 4 [m/sec] ? 1 kg A) 4 [J] 4 m/sec B) 0.25 [J] C) 2 [J] D) 8 [J] KE = ½ (1)(4)2 = 8 [J] What if the mass was going in the opposite direction (v = - 4 [m/sec])? 1 kg -4 m/sec A) 4 [J] B) 0.25 [J] C) 2 [J] D) 8 [J] KE = ½ (1)(- 4)2= 8 [J] KE Examples (cont) q An electron has a mass of 9.1x10-31 [kg]. If it is moving at one-tenth of the speed of light, what is it’s kinetic energy? The speed of light is 3x108 [m/sec]. The electron’s velocity is v = (1/10)*(3x108) = 3x107 [m/sec] So, KE = ½ (9.1x10-31 )(3x107 )2 = 8.2x10-16 [J] qHow does this compare to the 1 [kg] block moving at 4 [m/sec] ? KE(electron) / KE(block) = 8.2x10-16/8 = 2.6x10-17 [J] (Wow, this is a small number. We’ll come back to this fact in a bit…) Electricity q Electricity generally refers to the flow of charges. q In most cases, electrons are the charges which are actually moving. q The units of charge is a Coulomb or simply [C]. q 1 [C] = 6.25x1018 charges (such as electrons or protons) q Alternately, 1 electron = (1 / 6.25x1018) [C] = 1.6x10-19 [C] q Charges are made to flow by applying a voltage q Batteries q Power Supplies q Electrical generators Electrical Current q Electrical current is the rate of flow of charges, that is [C/sec] q The units of current are Amperes, or just Amps == [A] q 1 [A] = 1 [C/sec] q 1 [A] = 6.25x1018 charges/sec q Lightening bolts can contain several thousand amps of current ! Electrical Energy and the Electron-Volt q How much energy does an electron gain as it is accelerated across a voltage? (Length of arrow is proportional to velocity) -1000 [V] e e e e e e +1000 [V] q It’s energy is the product of the charge times the voltage. That is, E = q(∆V) = (1.6x10-19)(2000) = 3.2x10-16 [J] Charge: q is in [C] Voltage: ∆V is in [Volts] ([V]) Energy: E is in [Joules] ([J]). q Because 1 electron is only a tiny fraction of a Coulomb, the energy is also tiny ! This is a pain, but …. The Electron-Volt (eV) qHow much energy does an electron gain as it crosses 1 volt. Energy = q*(∆V) = (1.6x10-19 [C]) * (1 [Volt]) = 1.6x10-19 [J] q Since this amount of energy is so small, we define a more convenient unit of evergy, called the “Electron-Volt” Define the electron-Volt: 1 [eV] = 1.6x10-19 [J] q An electron-volt is defined as the amount of energy an electron would gain as it accelerates across 1 Volt. q In most cases, we will use the [eV] as our unit of energy. To convert back to [J], you need only multiply by 1.6x10-19. Examples An electron is accelerated across a gap which has a voltage of 5000 [V] across it. How much kinetic energy does it have after crossing the gap? E = (1 electron)(5000 V) = 5000 [eV] A proton is accelerated across a gap which has a voltage of 10,000 [V] across it. How much kinetic energy does it have after crossing the gap? E = (1 proton)(10000 V) = 10,000 [eV] (we don’t refer to them as “proton-volts” !) Electromagnetic Waves • Electromagnetic (EM) waves are another form of energy. • In the “classical” picture, they are just transverse waves... The speed of EM waves in “vacuum” is always c = 3 x 108 [m/sec] The wavelength (λ) is the distance from crest-to-crest In vacuum c = 3x108 [m/sec] for all wavelengths ! (~3x108 [m/sec] in air too) The Electromagnetic Spectrum (EM) Shortest wavelengths (Most energetic) Recall 109 [nm] = 1 [m] 106 [µm] = 1 [m] Longest wavelengths (Least energetic) Frequency Consider two waves moving to the right at the speed c, and count the number of waves which pass a line per second 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 … 14 waves 7 waves q Since all EM waves move at the same speed, they would measure twice as many waves for the top wave as the bottom wave. q We call the number of waves that pass a given point per second the frequency Frequency (cont) q The frequency is usually symbolized by the greek letter, ν (“nu”) ν == frequency q Frequency has units of [number/sec], or just [1/sec], or [hertz] == [hz] q A MegaHertz [Mhz] is 1 million hertz, or 1 million waves/second! q There is a simple relation between the speed of light, c, the wavelength, λ, and the frequency ν. c = λν c = 3x108 [m/sec] Example I What is the frequency of a gamma-ray with λ=10-6 [nm] ? I want to use c = λν, but we need λ in [m]… So, first convert [nm] to [meters] 10-6 [nm] * ( 1 [m]) ( 109 [nm] ) = 10-15 [m] ν = c / λ = (3x108) / (1x10-15) = 3 x 1023 [hz] = 300,000,000,000,000,000,000,000 waves/sec ! That’s A LOT of waves! Example II What is the frequency of a gamma-ray with λ=0.5 [km] ? First, convert [km] to [m]… 0.5 [km] * ( 103 [ m ] ) ( 1 [km] ) = 5x102 [m] ν = c / λ = (3x108) / (5x102) = 6 x 105 [hz] = 0.6 [Mhz] This is AM Radio! this is the case… FM Radio waves are typically around 80 Mhz. Show that Mass Energy According to Einstein’s Theory of Special Relativity, Mass is a form of Energy, and they are related by the simple and well-known formula: E= 2 mc The units of energy, E can be expressed in [J], as before, but it is more convenient to use the electron-volt [eV]. Recall that 1 [eV] = 1.6x10-19 [J] E=mc2 q The important point here is that energy and mass are really equivalent, and are related to one another by simply the speed of light (c) squared! q This equation implies that even if a particle is at rest, it in fact does have a “rest-mass energy” given by this formula. Example I q What is the rest-mass energy of a 1 [kg] block in [J]. E = mc2 = (1 [kg])(3x108 [m/sec])2 = 9x1016 [J] . This is a HUGE amount of energy stored in the rest mass! q Really, how much energy is this? To put it in context, you could power a 100 [Watt] light bulb for 29 million years if you could convert all of this rest mass to energy !!!! Unfortunately, this is not possible at this point… Example II q What would be the kinetic energy of this 1 [kg] block if it were moving at 200 [m/sec] (about 430 [mi/hr]) ? KE = ½ (1 [kg]) (200 [m/sec])2 = 2x104 [J] q What fraction of the rest mass energy is this ? Fraction = (2x104 [J] ) / (9x1016 [J] ) = 2.2x10-13 ( or 0.000000000022%) è That is, the KE is only a tiny fraction of the rest mass energy. Alternately, it gives you a flavor for how much energy is bottled up in the rest mass !!! Example III qWhat is the rest mass energy of a neutron, which has a mass of 1.68x10-27 [kg]? Express the result in [eV]. E = mc2 = (1.68x10-27 [kg])(3x108 [m/sec])2 = 1.5x10-10 [J] q Now convert to [eV]. 1.5x10-10 [J] * ( 1 [ eV ] ) = 9.4x108 [eV] ( 1.6x10-19 [J] ) = 940 [MeV] Example IV An electron and positron (a positively-charged electron) each having 10 [keV] collide and annihilate into pure energy. How much energy is carried away after the collision? Total energy is conserved, so it must be the same as before the collision. 10 keV + 10 keV = 20 keV Summary q There are many forms of energy, including: Energy of motion Electrical energy Electromagnetic energy (EM waves) Mass energy q Energy of motion is given by KE=(1/2)mv2 q One of the most important forms of energy which we’ll deal with is mass energy. q Mass IS a form of energy. q Mass can be converted into energy. If you convert all of the mass of some object with mass M to energy, the corresponding energy will be E=Mc2. LIGHT – PHOTONS The Wave – Particle Duality OR Light Waves Until about 1900, the classical wave theory of light described most observed phenomenon. Light waves: Characterized by: Ø Amplitude (A) Ø Frequency (ν) Ø Wavelength (λ) Energy α A2 And then there was a problem… However, in the early 20th century, several effects were observed which could not be understood using the wave theory of light. Two of the more influential observations were: 1) The Photo-Electric Effect 2) The Compton Effect I will describe each of these today… Photoelectric Effect (I) “Classical” Method What if we try this ? Increase energy by increasing amplitude Vary wavelength, fixed amplitude electrons emitted ? No No No No electrons emitted ? No Yes, with low KE Yes, with high KE No electrons were emitted until the frequency of the light exceeded a critical frequency, at which point electrons were emitted from the surface! (Recall: small λ è large ν) Photoelectric Effect (II) q Electrons are attracted to the (positively charged) nucleus by the electrical force q In metals, the outermost electrons are not tightly bound, and can be easily “liberated” from the shackles of its atom. q It just takes sufficient energy… Classically, we increase the energy of an EM wave by increasing the intensity (e.g. brightness) Energy α A2 But this doesn’t work ?? PhotoElectric Effect (III) q An alternate view is that light is acting like a particle q The light particle must have sufficient energy to “free” the electron from the atom. q Increasing the Amplitude is just simply increasing the number of light particles, but its NOT increasing the energy of each one! è Increasing the Amplitude does diddly-squat! q However, if the energy of these “light particle” is related to their frequency, this would explain why higher frequency light can knock the electrons out of their atoms, but low frequency light cannot… Photo-Electric Effect (IV) q In this “quantum-mechanical” picture, the energy of the light particle (photon) must overcome the binding energy of the electron to the nucleus. q If the energy of the photon does exceed the binding energy, the electron is emitted with a KE = Ephoton – Ebinding. q The energy of the photon is given by E=hν, where the constant h = 6.6x10-34 [J s] is Planck’s constant. “Light particle” Before Collision After Collision Photons q Quantum theory describes light as a particle called a photon q According to quantum theory, a photon has an energy given by E = hν = hc/λ h = 6.6x10-34 [J*sec] Planck’s constant, after the scientist Max Planck. q The energy of the light is proportional to the frequency, and inversely proportional to the wavelength! The higher the frequency (lower wavelength) the higher the energy of the photon! q 10 photons have an energy equal to ten times a single photon. q The quantum theory describes experiments to astonishing precision, whereas the classical wave description cannot. The Electromagnetic Spectrum Shortest wavelengths (Most energetic photons) E = hν = hc/λ h = 6.6x10-34 [J*sec] (Planck’s constant) Longest wavelengths (Least energetic photons) Interpretation of Photoelectric Effect Vary wavelength, fixed amplitude electrons emitted ? Increase Energy Increase Energy E1 = hν1 No E2 = hν2 Yes, with low KE E3 = hν3 Yes, with high KE E3 > E2 > E1 Photoelectric Effect Applet The Compton Effect In 1924, A. H. Compton performed an experiment where X-rays impinged on matter, and he measured the scattered radiation. Incident X-ray wavelength λ1 M A T T E R Scattered X-ray wavelength λ2 Louis de Broglie λ2 > λ1 e Electron comes flying out Problem: According to the wave picture of light, the incident X-ray gives up energy to the electron, and emerges with a lower energy (ie., the amplitude is lower), but must have λ2=λ1. Quantum Picture to the Rescue q If we treat the X-ray as a particle with zero mass, and momentum p = E / c, everything works ! Incident X-ray p1 = h / λ1 Electron initially at rest Scattered X-ray p2 = h / λ2 λ2 > λ1 e e pe Compton found that if the photon was treated like a particle with mometum p=E/c, he could fully account for the energy & momentum (direction also) of the scattered electron and photon! Just as if 2 billiard balls colliding! Interpretation of Compton Effect “Light particle” λ1 λ2 Before Collision After Collision The Compton Effect describes collisions of light with electrons perfectly if we treat light as a particle with: p = h/λ and E = hν = hc/λ = (h/λ)c = pc DeBroglie’s Relation p=h/λ è The smaller the wavelength the larger the photon’s momentum! è The energy of a photon is simply related to the momentum by: E = pc (or, p=E/c ) è The wavelength is related to the momentum by: λ = h/p è The photon has momentum, and its momentum is given by simply p = h / λ . Momentum of Photons If I have a photon with energy E=1 [GeV], what is its momentum? p = E / c = (1 [GeV])/c = 1 [GeV/c] … That’s it! If I have a photon with momentum 5 GeV/c, what is its energy? E = pc = (5 GeV/c) * c = 5 [GeV] … whallah ! So, the only difference between a photons’ energy and momentum is: Energy è [GeV] momentum è [GeV/c] Don’t forget though that the “c” in [GeV/c] really means 3x108 [m/s]. Scattering Problem Incident X-ray wavelength Electron initially at rest λf λi=1.5 [nm] e e KE=0.2 [keV] Before After q Compute the energy of the 1.5 [nm] X-ray photon. E = hc/λ = (6.6x10-34 [J s])(3x108 [m/s]) / (1.5x10-9 [m]) = 1.3x10-16 [J] Scattering Example (cont) q Express this energy in [keV]. 1.3x10-16 [J] * (1 [eV] / 1.6 x10-19 [J]) = 825 [eV] = 0.825 [keV] q What is the magnitude of the momentum of this photon? p = E / c = 0.825 [keV]/ c = 0.825 [keV/c] q After the collision the electron’s energy was found to be 0.2 [keV]. What is the energy of the scattered photon? A) 0.2 [keV] B) 0.625 [keV] C) 1.025 [keV] D) 0.825 [keV] Since energy must be conserved, the photon must have E=0.825-0.2 = 0.625 [keV] q What would be the wavelength of the scattered photon? HW exercise ! Summary of Photons q Photons can be thought of as “packets of light” which behave as a particle. q To describe interactions of light with matter, one generally has to appeal to the particle (quantum) description of light. q A single photon has an energy given by E = hc/λ, where h = Planck’s constant = 6.6x10-34 [J s] c = speed of light = 3x108 [m/s] λ = wavelength of the light (in [m]) and, q Photons also carry momentum. The momentum is related to the energy by: p = E / c = h/λ Matter Waves ? One might ask: “If light waves can behave like a particle, might particles act like waves”? The short answer is YES. The explanation lies in the realm of quantum mechanics, and is beyond the scope of this course. However, you already have been introduced to the answer. Particles also have a wavelength given by: λ = h/p = h / mv è That is, the wavelength of a particle depends on its momentum, just like a photon! è The main difference is that matter particles have mass, and photons don’t ! Matter Waves (cont) Compute the wavelength of a 1 [kg] block moving at 1000 [m/s]. λ = h/mv = 6.6x10-34 [J s]/(1 [kg])(1000 [m/s]) = 6.6x10-37 [m]. è This is immeasureably small. So, on a large scale, we cannot observe the wave behavior of matter Compute the wavelength of an electron (m=9.1x10-31 [kg]) moving at 1x107 [m/s]. λ = h/mv = 6.6x10-34 [J s]/(9.1x10-31 [kg])(1x107 [m/s]) = 7.3x10-11 [m]. This is near the wavelength of X-rays Electron Microscope èThe electron microscope is a device which uses the wave behavior of electrons to make images which are otherwise too small using visible light! This image was taken with a Scanning Electron Microscope (SEM). These devices can resolve features down to about 1 [nm]. This is about 100 times better than can be done with visible light microscopes! IMPORTANT POINT HERE: High energy particles can be used to reveal the structure of matter ! Remarks on Particle Probes q We have now asserted that high energy particles (electrons in the case of a SEM) can provide a way to reveal the structure of matter beyond what can be seen using an optical microscope. q The higher the momentum of the particle, the smaller the deBroglie wavelength. q As the wavelength decreases, finer and finer details about the structure of matter are revealed ! q We will return to this very important point. è To explore matter at its smallest size, we need very high momentum particles! è Today, this is accomplished at facilities often referred to as “atom-smashers”. We prefer to call them “accelerators” è More on this later ! What is Matter If you took a piece of paper, and ripped it in half. Take one of the halves, and rip it in half. Repeat this again & again & again… At what point would you find that you couldn’t subdivide the material anymore? What would you have in your hand at this point? A very good reference for the things we are going to cover is at: http://particleadventure.org/particleadventure/frameless/sitemap.html What is matter ? Ü We are ! And lots of other things around us… Almost everything around you is matter… But, what we’re really interested in is: What is matter at its most fundamental level ? What are we made of ? q We’re made of cells which contain DNA. - Different cells serve different functions in your body. q The cells contain a nucleus, which contains your DNA ! q And the DNA is a wonderful, complex chain of molecules which contains your genetic code! q But, what are molecules made of ? 0.0002” The Elements †Molecules are complex structures of the elements But what’s inside “an element” For each element, we can associate an atom. Prior to ~1905, nobody really knew: “ What does the inside of an atom look like ? ” Early “Plum-Pudding” Model Positive Charge (uniformly distributed) Corpuscles (Electrons) The positive charge is spread out like a “plum-pudding” A digression on radiation Radiation: The process of emitting energy in the form of waves or particles. Where does radiation come from? Radiation is generally produced when particles interact or decay. A large contribution of the radiation on earth is from the sun (solar) or from radioactive isotopes of the elements (terrestrial). Radiation is going through you at this very moment! http://www.atral.com/U238.html Isotopes What’s an isotope? Two or more varieties of an element having the same number of protons but different number of neutrons. Certain isotopes are “unstable” and decay to lighter isotopes or elements. Deuterium and tritium are isotopes of hydrogen. In addition to the 1 proton, they have 1 and 2 additional neutrons in the nucleus respectively*. Another prime example is Uranium-238, or just 238U. Radioactivity By ~1900, it was known that certain isotopes emit penetrating rays. Three types of radiation were known: 1) Alpha particles (α) 2) Beta particles (β) 3) Gamma-rays (γ) Where do these ‘particles’ come from ? qThese particles generally come from the nuclei of atomic isotopes which are not stable. q The decay chain of Uranium produces all three of these forms of radiation. q Let’s look at them in more detail… Note: This is the atomic weight, which is the number of protons plus neutrons Alpha Particles (α) Radium Radon R226 Rn222 88 protons 138 neutrons 86 protons 136 neutrons + n p p n α (4He) 2 protons 2 neutrons The alpha-particle (α) is a Helium nucleus (charge = +2) It’s the same as the element Helium, but without the electrons ! Beta Particles (β) Carbon C14 Nitrogen N14 6 protons 8 neutrons 7 protons 7 neutrons n à + e- + ν electron (beta-particle) p + e- + ν More on this bugger later… The electron emerges with relatively high energy in this “disintegration” (decay) process. We see that one of the neutrons from the C14 nucleus “converted” into a proton, and an electron was ejected. The remaining nucleus contains 7p and 7n, which is a nitrogen nucleus. In symbolic notation, the following process occurred: Gamma particles (γ) In much the same way that electrons in atoms can be in an excited state, so can a nucleus. Neon Ne20 10 protons 10 neutrons (in excited state) Neon Ne20 + 10 protons 10 neutrons (lowest energy state) gamma A gamma is a high energy light particle (short for gamma ray). It is NOT visible to your naked eye because it is not in the visible part of the EM spectrum. Gamma Rays Neon Ne20 Neon Ne20 + The gamma from nuclear decay is in the X-ray/ Gamma ray part of the EM spectrum (very energetic!) How do these particles differ ? Particle Mass Charge Gamma (γ) 0 0 Beta (β) (Electron) Alpha (α) Electron mass is ~1/2000th of a proton’s mass ~4 times a proton’s mass (since mp≈ mn). Back to “Structure of Matter” -1 +2 mp = proton mass mn = neutron mass Scattering Experiments If the plum-pudding model was right, then matter is “soft”. There’s no “central, hard core”… Alpha particle source Ernest Rutherford 1871-1937 Awarded the Nobel Prize in 1908 Calculations, based on the known laws of electricity and magnetism showed that the heavy alpha particles should be only slightly deflected by this “plum-pudding” atom… Au Contraire Contrary to expectations, Rutherford found that a significantly large fraction (~1/8000) of the alpha particles “bounced back” in the same direction in which they came…The theoretical expectation was that fewer than 1/10,000,000,000 should do this ??? Gold foil α Huh ??? α In Rutherford’s words… “It was quite the most incredible event that ever happened to me in my life. It was as if you fired a 15-inch naval shell at a piece of tissue paper and the shell came right back and hit you.” The (only) interpretation The atom must have a solid core capable of imparting large electric forces onto an incoming (charged) particle. α α α α α The Modern Atom Atom: the smallest particle of an element that can exist either alone or in combination Electrons Nucleus 2x10-13 cm 0.0000000002 cm (2 x 10-10 cm) Atoms and Space Approximately what fraction of the volume of an atom does the nucleus consume? Assume that an atom can be approximated by a sphere with a radius given by the electrons orbit radius? Use the following data. • The radius of the nucleus is ~ 2x10-13 cm. • The electrons orbits at a radius of ~ 2x10-10 cm • Ignore the electrons size, as it is unimportant. • The volume of a sphere is (4/3)πR3. Answer… a) First find the volume of the entire atom Volume = (4/3)*π∗(2x10-10)3 = 3.4 x 10-29 cm3 b) Now find the volume which contains the nucleus. Volume = (4/3)*π∗(2x10-13)3 = 3.4 x 10-38 cm3 c) Now compute the fraction: Fraction = (3.4 x 10-38 / 3.4 x 10-29 ) = 0.000000001 In other words, 99.99999999% of an atom is empty space !!! Matter & Forces Matter Hadrons Baryons Mesons Quarks Anti Anti-Quarks Quarks Leptons Charged Neutrinos Forces Gravity Weak Strong EM A Sense of Scale ~5x10-6 [m] Quarks and leptons are the most elementary particles we know about at this time. They are no larger than 10-18 [cm] ~2x10-9 [m] ~2x10-8 [m] ~5x10-15 [m] ~1.5x10-15 [m] <1x10-18 [m] q e The Standard Model q Quarks and leptons are the most fundamental particles of nature that we know about. q Up & down quarks and electrons are the constituents of ordinary matter. q The other quarks and leptons can be produced in cosmic ray showers or in high energy particle accelerators. q Each particle has a corresponding antiparticle. The cast of quarks & leptons Family Quarks Antiquarks Q = +2/3 Q = -1/3 Q = -2/3 Q = +1/3 1 u d u d 2 c s c s 3 t b t b Family 1 Leptons Q = -1 Q=0 eνe Antileptons Q = +1 Q=0 e+ νe 2 µ− νµ µ+ νµ 3 τ− ντ τ+ ντ Quarks versus Leptons What are the primary differences between quarks and leptons? Ultimately, what differentiates the quarks & leptons from one another are the forces which each may exhibit. We therefore now embark on the concept of forces. The Four Fundamental Forces Weaker 1. Gravity 2. Weak Force Stronger 3. Electromagnetic force 4. Strong Force Doesn’t that look like George W. ? All other forces you know about can be attributed to one of these! Gravity Gravity is the weakest of the 4 forces. The gravitational force between two objects of masses m1 and m2, separated by a distance d is: F = Gm1m2/d2 G = gravitational constant = 6.7x10-11[N*m2/kg2] d = distance from center-to-center The units of each are: [Force] = [Newton] = [N] [mass] = [kg] [distance] = [meters] Gravity is only an attractive force The Electric Force In the old days, we believed that “force” was transmitted more or less instantaneously by a “field of force”. Lines of force p p p p p The proton to the right is repelled by the “electric field” created by the one on the left (electrical repulsion). The New Concept of Force In the 1960’s, a new theory of interactions was developed. At the heart of it is the concept that: Richard Feynman, 1918-1988 1965 Nobel Prize in Physics Forces are the result of the exchange of “force carriers” between the two particles involved in the interaction. The force carrier of the electromagnetic force is the photon (γ) The Photon (γ) Property Mass Charge Value 0 0 q The photon is the “mediator” of the electromagnetic interaction q The photon can only interact with objects which have electric charge !!!!! !Note that all particles involved (other than the photon) carry electrical charge! Electron-Positron Scattering e+ + e- à e+ + e- e+ e+ e+ e+ e- e- ee- Electron-Positron Scattering e+ + e- à e+ + e- e+ e+ e+ e- ee-e- Electron-Positron Annihilation e+ + e- à e+ e+ e+ e+ee- γ γ e+ + e- ee- Electron-Positron Annihilation e+ + e- à e+ e+ e+ e+ee- γ γ e+ + e- ee- Quark Pair Production à e+ + e- q + q e+ e+ e+ e+ee- γ γ ee* Note: Two completely different particles in the “final state”. Since quarks have electric charge, this can in fact happen! Quark Pair Production à e+ + e- q + q e+ e+ e+ e+ee- γ ee* Note: Two completely different particles in the “final state” In the preceding example, assume that the incoming electron and positron each have energy of 5 GeV. Example 1. What is the energy of the photon after the electron & positron annihilate? A) 5 GeV B) 10 GeV C) 0 GeV D) None of these 2. Assuming that the final state electron & positron have equal energy, what is the energy of the emergent electron ? A) 5 GeV B) 10 GeV C) 0 GeV D) None of these 3. Once the photon is produced, it may split into any particle-antiparticle pair which is permissible by energy conservation. For each of these, tell whether the photon can produce the final state particles: a) u and u (Mu~0.005 GeV) Y or N b) d and d (Md ~ 0.010 GeV) Y or N c) s and s (MS ~ 0.20 GeV) Y or N d) c and c (MC ~ 1.5 GeV) Y or N e) b and b (Mb ~ 4.8 GeV) Y or N f) t and t (Mt ~ 175 GeV) Y or N Photon Conversion γ γ γ γ à γ γ e+ + e- Photon Conversion γ γ γ γ à γ γ e+ + e- Quark Antiquark Annihilation q + q à e+ + e- q q q qeq γ γ q q * Note: Reverse process to quark pair production! Quark Antiquark Annihilation à q + q e+ + e - q q q qeq γ q q * Note: Reverse process to quark pair production! Feynman Diagrams q A great simplification which allows us to represent these physical processes are facilitated by Feynman Diagrams. qIt turns out, they can also be used to calculate the probability for the process to occur (Beyond the scope of this module though). q We will use them more in a qualitative sense to visualize various processes. Feynman Diagrams e+ e- Electron-Positron Annihilation γ e- e+ e+ Electron-Positron Scattering e+ γ e- etime Photon Conversion and Emission ePhoton Conversion γ e+ γ Photon Emission e- e- More Feynman Diagrams Quark Pair Production §“q” can be any quark, as long as there is enough energy to create 2 of ‘em! Quark Antiquark Annihilation to Electron & Positron e+ e- q γ q q q e+ γ e- The paragraph is a series of sentences developing one topic. The Topic Sentence • The topic of a paragraph is stated in one sentence. This is called the topic sentence. The rest of the paragraph consists of sentences that develop or explain the main idea. • Through the centuries rats have managed to survive all our efforts to destroy them. We have poisoned them and trapped them. We have fumigated, flooded, and burned them. We have tried germ warfare. Some rats even survived atomic bomb tests conducted on Entwetok atoll in the Pacific after World War II. In spite of all our efforts, these enemies of ours continue to prove that they are the most indestructible of pests. Developing a Paragraph Unity in the Paragraph Every sentence in a paragraph should support the main idea expressed in the topic sentence. The concluding or clincher sentence • Restate the topic sentence in different words. • A clincher sentence or concluding sentence clinches the point made in the paragraph. • It summarizes the paragraph. Coherence in a Paragraph • Stick to the point: The ideas have a clear and logical relation to each other. • Put details or examples or incidents in logical order. chronological in relation to each other in order of importance 4 3 2 1 Connecting Sentences Within the Paragraph Transition words chronological order objects in relation to in order of importance one another first next to however meanwhile in front of furthermore later beside as a result afterwards between in fact finally behind yet Types of Paragraphs • The narrative paragraph • tells a story • The persuasive paragraph. • tries to convince the audience • The descriptive paragraph • describes something • The expository or explanatory paragraph • gives information or explains something Welcome to Particle Physics A blurb from the “Quarks Unbound” from the American Physical Society • “We’re barely aware that they are there, but the elementary particles of matter explain much of what we take for granted every day. Because of gluons binding the atomic nucleus, matter is stable and doesn’t crumble. Because of gravitons, our feet stay firmly planted on the ground. We see because our eyes react to photons of light. “ • “Particle Physics explains the ordinary, and delights us with tales of the extraordinary. Antimatter annihilates matter. “Virtual” particles blink in and out of existence in the vacuum of space. Neutrinos zip through the Earth untouched.” • “Particle Physics doesn’t stop at the unusual either. It contemplates the cosmic too, exploring the origins of the universe and the symmetries that frame its design.” Aims of Particle Physics 1. To understand nature at it’s most fundamental level. 2. What are the smallest pieces of matter, and how do they make up the large scale structures that we see today ? 3. How and why do these ‘fundamental particles’ interact the way that they do? 4. Understand the fundamental forces in nature. In this course, our aim is to introduce you to nature at its most fundamental level q Some of the concepts you will encounter may not agree with your intuition, others will… q We strongly encourage you to ask questions in class. It will help you, your classmates, and us! Before we can get to this, we will first spend some time on some basics, and then we’ll get to the meat later on…. Sizes and Powers of 10 q In describing nature, objects vary dramatically in size. q The solar system is about 10,000,000,000,000,000,000,000 times larger than an atom, for example è Scientific notation ! q You should become comfortable with seeing scientific notation, in the context of relative sizes of objects. q Useful Web Sites which allow you to step through the powers of 10 are at: q http://cern.web.cern.ch/CERN/Microcosm/P10/english/P0.html q http://www.wordwizz.com/pwrsof10.htm q http://micro.magnet.fsu.edu/primer/java/scienceopticsu/powersof10/ Powers of 10 10 = 101 Positive Powers 100 = 10 x10 = 101 x101 = 102 1000 = 10 x10 x10 = 10 x10 x10 = 10 1 1 1 3 1 1 0.1 = = 1 = 10−1 10 10 Negative Powers 0 Power 1 1 1 1 0.01 = = x = 2 = 10−2 100 10 10 10 1 1 1 1 1 0.001 = = x x = 3 = 10−3 1000 10 10 10 10 100 = 1 Scientific Notation 12500 = 1.25 x 10000 = 1.25 x (10 x 10 x 10 x 10) = 1.25 x 104 1.25x10? 1.2500 12500.0 Move decimal 4 places to right 0.00367 = 3.67 x 0.001 = 3.67 x (.1 x .1 x .1) = 3.67 x 10-3 3.67x10? 0.00367 3.67 Move decimal 3 places to left The earth has a circumference of about 25,000 miles. How is this expressed in scientific notation? A) 2.5x103 B) 25x104 C) 2.5x104 D) None of these The sun has a radius of 695 million meters. How is this expressed in scientific notation? A) 695x105 B) 6.95x108 C) 6.95x109 D) 6.95x106 Multiplying powers of 10 The circumference of the earth is about 4x107 [m]. If I were to travel around the earth 3x102 times, how many [m] will I have gone? A) 7.0x109 B) 1.2x1010 C) 1.0x1015 D) 7.0x1015 (4x107) x (3x102) = (4x3) x (107x102) = 12x10(7+2) = 12x109 = (1.2x10) x109 = 1.2x1010 A bullet takes 10-3 seconds to go 1 [m]. How many seconds will it take for it to go 30 [m]? A) 3.0x10-1 B) 3.0x10-2 C) 4.0x10-2 D) 4.0x10-1 (1x10-3) x (3x101) = (1x3) x (10-3x101) = 3x10(-3+1) = 3x10-2 Dividing Powers of 10 A gas truck contains 4.6x103 gallons of fuel which is to be distributed equally among 2.0x104 cars. How many gallons of fuel does each car get? A) 2.3x101 B) 2.3x10-1 C) 23 D) 2.3 3 3 4.6 x10 4.6 10 (3− 4) −1 = * 4 = 2.3 x10 = 2.3 x10 4 2.0 x10 2.0 10 The area of the U.S is about 3.6x106 [miles], and the population is about 300x106. On average, what is the population density in persons per square mile? A) 1.2x102 B) 1.2x10-1 C)1.2x10-3 D)1.2x10-2 6 6 3.6 x10 3.6 10 (6 −8) −2 = * 8 = 1.2 x10 = 1.2 x10 8 3.0 x10 3.0 10 Common Prefixes Commonly used prefixes indicating powers of 10 103 = “kilo” 106 = “mega” 109 = “giga” 1012 = “tera” 10-3 = “milli” 10-6 = “micro” 10-9 = “nano” 10-12 = “pico” 10-15 = “femto” How many times larger is a kilometer than a micrometer ? A) 1,000 B) 1,000,000 C) 1,000,000,000 D) 1x10-9 è1 km = 103 m and there are 106 micrometers in a meter, so there are 109 (or 1 billion) micrometers in 1 km How many 100 W bulbs can be kept lit with 100 Tera-Watts? A) 1.0x107 B) 1.0x109 C) 1.0x1012 D)1.0x1013 Common Conversions Length: Mass: Speed: 2.54 [cm] = 1 [inch] 1 [kg] = 2.2 [lbs] 1 [m/sec] = 2.25 [mi/hr] How many meters are there in a centimeter? A) 100 B) 0.01 C) 1000 D) 0.001 How many inches in 1 kg ? A) 2.54 B) 25.4 C) less than 25 D) None of these Units q Joe asks Rob… “About how much does your car weigh” ? Joe answers … “About 1.5” q Is Joe’s answer correct or incorrect? Physical quantities have units !!!!!!!! qAll physical quantities have units, and they must be used. q One exception is if you are talking only about a pure number. For example: How many seats are in this classroom? q I will often use brackets to indicate units: 1 kilogram == 1 [kg] Variables/Symbols q It is often more convenient to represent a number using a letter. For example, the speed of light is 3x108 [m/sec]. To avoid having to write this every time, we simply use the letter c which represents this value. That is c = 3x108 [m/sec]. q We might use the expression, “the particle is moving at 0.1c”. This should be interpreted as “The particle is moving at 1/10th of the speed of light.” q We will often use letters to represent constants or variables, so you must become comfortable with this. Proportionality What do we mean when we say: “Quantity A is proportional to quantity B” This means the following: 1) If we double B, then A also doubles. 2) If we triple B, then A also triples. 3) If we halve B, then A also halves. This is often written as: A α B The circumference of a circle, C, is proportional to the radius, R. If the radius is increased by a factor of 10, what happens to the circumference? It increases by a factor of 10 Proportionality Exercises q Consider this 1 cm square l q What is its area? Area = base * height = l*l = l2 = (1 cm )2 = 1 cm2 q What’s the area of this square? 2l l l Area = base * height = 2l*2l = 4l2 = 4(1 cm )2 = 4 cm2 If we double the length of the side, we quadruple the area? Proportionality Exercises (cont) The area of a circle is proportional to the radius squared. What happens to the area of a circle if the radius is doubled? Radius = 2 cm Radius = 4 cm A=πr2 A=π(22) = 4π A=π(42) = 16π Since A α r2, (A=πr2) doubling the radius quadruples the area ! Inverse Proportionality What do we mean when we say a quantity V is inversely proportional to another quantity, say d. V α (1/d) It means: If we double d, then V is reduced by a factor of 2 If we quadruple d, then V is reduced by a factor of 4. Why? We know that Vd α (1/d) If we double d, then d à (2*d), so V2d α [1/(2d)] = (1/2) (1/d) = (1/2) Vd. In the same way, show that V4d = (1/4) Vd Exercises The force of gravity is known to be inversely proportional to the square of the separation between two objects. What happens to the force between two objects when the distance is tripled? A) B) C) D) Increases by a factor of 6 Decreases by a a factor of 8 Decreases by a factor of 9 Decreases by a factor of 6 The electric force between two charges is also known to be inversely proportional to the square of the separation. What happens to the force if the distance is reduced by a factor of 10. A) B) C) D) Increases by a factor of 10 Increases by a a factor of 100 Decreases by a factor of 10 Decreases by a factor of 100 Algebra If a car is going 20 [mi/hr] for 4 [hrs], how far does the car go? A) 80 [mi] B) 5 [mi] C) 20 [mi] D) none of these What did you do to arrive at this result? q You multiplied the speed (20 [mi/hr]) by the time (4 [hrs]). q So, to get the distance, you did this: distance = velocity * time d = v*t Algebra (cont) If a biker goes 20 [mi] in 2 [hrs], what is the bikers average speed ? A) 20 [mi/hr] B) 5 [mi/hr] C) 10 [mi/hr] D) 40 [mi/hr] What did you do to arrive at this result? q You divided the distance (20 [mi]) by the time (2 [hrs]). q That is, you reasoned: average velocity = distance / time v=d/t Is this equation and the previous one expressing different relationships among the variables v, d and t? Algebra (cont) NO! d=v*t and v=d/t Are expressing the same relationship. The variables are just shuffled around a bit! Ø To cast the first form into the second: Multiply both sides by (1/t): The factor of t * (1/t) = 1, so And, (1/t)*d = d/t, Or, just switching sides… d=v*t (1/t)* d = v * t *(1/t) (1/t)* d = v d/t=v v=d/t An important example Einstein’s famous Energy-mass relation: E = m c2 Can be rearranged to read: m = E / c2 Note that the units of mass can also be expressed in units of Energy / (speed)2 (We’ll come back to this point later…) Summary For this module, you should be comfortable with: 1. Using and manipulating powers of 10 (division, multiplication). 2. Understanding what “proportional to” and “inversely proportional to” mean. 3. Simple conversion of units, if you are given the conversion factors. (e.g. [in.] to [cm], [cm] to [m]., etc) 4. Basic algebra and manipulating equations such as, E=mc2, c=fλ , E=hf , etc. 5. Understanding prefixes, such as Giga, Tera, Mega, etc. English Grammar Parts of Speech Eight Parts of Speech Nouns Interjections Adjectives Conjunctions Word that names • A Person bA Place b A Thing b An Idea Kinds of Nouns Common Nouns Proper Nouns John Mary Singular Nouns Plural Nouns boys girls Plural Possessive boys’ girls’ boy girl boy girl Singular Possessive boy’s girl’s A word that expresses action or otherwise helps to make a statement “be” verbs & taste feel sound look appear become seem grow remain stay Every sentence must have a Kinds of Verbs • Action verbs express mental or physical action. He rode the horse to victory. • Linking verbs make a statement by connecting the subject with a word that describes or explains it. He has been sick. The pronoun is a word used in place of one or more nouns. It may stand for a person, place, thing, or idea. Indefinite Pronouns anybody each either none someone, one, etc. Modifies or describes a noun or pronoun. Did you lose your address book? Is that a wool sweater? Just give me five minutes. Answers these questions: Modifies or describes a verb, an adjective, or another adverb. Answers the questions: He ran quickly. She left yesterday. We went there. It was too hot! To what degree or how much Interrogative Adverbs introduce questions How did you break your leg? How often do you run? Where did you put the mouse trap? A preposition introduces a noun or pronoun or a phrase or clause functioning in the sentence as a noun. The word or word group that the preposition introduces is its object. They received a postcard from Bobby telling about his trip to Canada. The preposition never stands alone! object of preposition preposition object You can press those leaves under glass. can have more than one object Her telegram to Nina and Ralph brought good news. object can have modifiers It happened during the last examination. Some Common Prepositions aboard about above across after against along among around at before behind below beneath beside between beyond by down during except for from in into like of off on over past since through throughout to toward under underneath until up upon with within without The conjunction a word that joins words or groups of words. A conjunction is or but The interjection is an exclamatory word that expresses emotion Goodness! What a cute baby! Wow! Look at that sunset! That’s all for now. . . More Later Introduction to Physical Quantities Scalars Scalar quantities are those which are described solely by their magnitude Some examples are: Mass Time Volume Temperature Voltage e.g. e.g. e.g. e.g e.g. 14 [kg], 36 [lbs], … 10 seconds, 40 minutes, … 1000 cm3, 4 litres, 12 gallons 14 oF , 25 oC, … 9 Volts, etc Vectors Vector quantities are those which need to be described by BOTH magnitude and direction Some of the most common examples which we will encounter are: Velocity e.g. 100 [mi/hr] NORTH Acceleration e.g. 10 [m/sec2] at 35o with respect to EAST Force e.g. 980 [Newtons] straight down (270o) Momentum e.g. 200 [kg m/sec] at 90o. Distance q The separation between two locations. q Distance can be measured in many types of units. We will mostly use: MKS Units millimeters [m] centimeters [cm] meters [m] kilometers [km], etc FYI : 1 [km] = 0.6 [mi] qYou should be comfortable with converting from [cm] to [m], [mm] to [km], and so on. q We may use the symbolic notation ∆d to mean a change in the position. The symbol ∆ should be read as “the change in” Time In physics, we are most often less interested in absolute time than changes in time, or a time interval. seconds [sec] minutes [min] hours [hr] Time can be expressed in several units as well: days years etc… Example 1: How much time does it take for the earth to make one revolution? Example 2: How long did it take for you to drive to the store today? We usually refer to a time interval as : ∆t Velocity Velocity is a measure of the rate of change of the distance with respect to time. v = ∆d / ∆t q It will usually be measured in [m/sec]. q What does 5 [m/sec] mean? q It means if an object passes by us at 5 [m/sec], it will advance its position by 5 [m] every second. So after 2 [sec], it will have advanced 10 [m], and 20 [m] in 4 [sec] and so on. If a train moves at 50 [meters/sec], how far will it go in 50 seconds ? a) 100 miles b) 2.5 [km] c) 250 [m] d) 2500 miles Acceleration (I) qAcceleration is the rate of change of velocity with respect to time a = ∆v / ∆t [a] = [m/sec] / [sec] = [m/sec2] q What does a = 5 [m/sec2] mean? If an object starts at rest, its velocity increases by 5 [m/sec] every second. Time (sec) 0 1 2 3 4 Acceleration 5 m/sec2 5 m/sec2 5 m/sec2 5 m/sec2 5 m/sec2 Velocity 0 m/sec 5 m/sec 10 m/sec 15 m/sec 20 m/sec Acceleration (II) Acceleration can be negative also! We call this deceleration. q If the acceleration is in the same direction as the velocity, the object has positive acceleration (it speeds up). q If the acceleration is in the opposite direction as the velocity, the object has negative acceleration or deceleration (it slows down). Deceleration: Animated GIF of car decelerating What is a Force ? Force is simply: A PUSH or A PULL Forces have both magnitude and direction Force and Acceleration q Experimentally, we find that if we apply a force to an object, it accelerates. q We also find that the acceleration (a) is directly proportional to the applied force (F) and inversely proportional to the mass (m) . That is: Isaac Newton a=F/m This means: Ø Increasing the force increases the acceleration; decreasing the force results in a lower acceleration. This is Newton’s Law, and it is often written: F = ma Force (I) q A force is generally a result of an interaction between two (or more) objects (Try and think of a scenario where a force is applied with only one object involved)? q Can you think of some examples of forces? ü Gravitational ü Electric ü Magnetic ü Friction ü Wind drag ü Van der Waals forces ü Hydrogen bonds ü Forces in a compressed or stretched spring +… Forces (II) q Since two or more objects must be involved, a force intimately tied to the notion of an interaction. q Interactions are now believed to occur through the exchange of “force carriers”. This is a very important point, and we’ll come back to it later… q So far, we know only of four types of fundamental forces in nature: q Gravity, Electromagnetic, Weak, and Strong q We will come back to each of these q All other forces in nature are understood to be the residual effects of these fundamental forces Momentum (I) What is momentum? Momentum is simply the product of the mass and the velocity. Denoting momentum as p, it is simply: m v p = m*v q The units of momentum are [kg][m/sec] == [kg m/sec] q Momentum is a very important subject in physics because it is what we call a conserved quantity. What does this mean? q We will come back to the idea of conserved quantities in physics. They play a very important role in understanding the world around us! Momentum (Example I) If a 500 [kg] car is traveling west at 20 [m/sec], what is its momentum? A) -1x104 [kg m/sec] B) -1x103 [kg m/sec] C) 25 [kg m/sec] D) 1x105 [kg m/sec] -20 [m/sec] 500 [kg] p = mv = (500 [kg])(-20 [m/sec]) = -10,000 [kg m/sec] = -1x104 [kg m/sec] Momentum (Example II) If a 5000 [kg] truck is travelling east at 10 [m/sec], what is its momentum? A) -5x104 [kg m/sec] B) 5x104 [kg m/sec] C) 500 [kg m/sec] D) 1x104 [kg m/sec] 5000 [kg] p = m*v = (5000 [kg])(10 [m/sec]) = 50,000 [kg m/sec] = 5x104 [kg m/sec] 10 [m/sec] Momentum (Example III) If the car and the truck collide, what is the total momentum of the car and truck just before impact? A) 6x104 [kg m/sec] B) -4x104 [kg m/sec] C) 4x104 [kg m/sec] D) 0 [kg m/sec] 10 [m/sec] 5000 [kg] -20 [m/sec] 500 [kg] Since their momenta are aligned in the same direction, we can just add them: PTOTAL = -1x104 [kg m/sec] + 5x104 [kg m/sec] = 4x104 [kg m/sec] Energy Energy: The capacity for doing work (or to produce heat) What are some forms/types of energy? 1. Energy of motion (kinetic energy) É 2. Heat 3. Electricity É 4. Electromagnetic waves - like visible light, x-rays, UV rays, microwaves, etc É 5. Mass É Energy What do you mean mass is a form of energy? We’ll get to this later…. i The thing about energy is that it cannot be created or destroyed, it can only be transformed from one form into another i Yes, like momentum it is a “conserved” quantity. We will learn that conserved quantities are a powerful tool in “predicting the future”! Summary I q In nature, there are two types of quantities, scalars and vectors q Scalars have only magnitude, whereas vectors have both magnitude and direction. q The vectors we learned about are distance, velocity, acceleration, force, and momentum q The scalars we learned about are time, and Energy. Summary II q Forces are the result of interactions between two or more objects. q If the net force on an object is not zero, it will accelerate. That is it will either speed up, slow down, or change direction. q Energy and momentum are conserved quantities. This has far-reaching consequences for predicting whether certain “events” or “processes” can occur. q There are many forms of energy. The topic of energy will be discussed in greater detail in next lecture. The Modern Quantum Atom The nucleus and the discovery of the neutron What are electron-volts ? The Quantum atom Rutherford’s Picture of the Atom Electrons circle the nucleus due to the Coulomb force Corpuscles (Electrons) ~10-14 m ~10-11 m Positively Charged Nucleus This model was inspired by the results of scattering alpha-particles off of heavy nuclei (like gold, silver, etc). James Chadwick and the Neutron Circa 1925-1935 Picked up where Rutherford left off with more scattering experiments… (higher energy though!) q Performed a series of scattering experiments with α-particles (recall a particles are He nucleus), 4 2 He + 9 Be 12 C+ 1 0 n q Chadwick postulated that the emergent radiation was from a new, neutral particle, the neutron. q Applying energy and momentum conservation he found that the mass of this new object was ~1.15 times that of the proton mass. Awarded the Nobel Prize in 1935 1891-1974 ***Electron-Volts (eV)*** q When talking about subatomic particles, and individual photons, energies are very small (~10-12 or smaller). q It’s cumbersome to always deal with these powers of 10. q We introduce a new unit of energy, called the electron-volt (eV). q An [eV] is equivalent to the amount of energy a single electron gains when it is accelerated across a voltage of 1 [V]. Electric TV tube accelerates electrons GPE using 20,000 [V] = 20 [kV]. 1 kg Potential 10[J] 0 [V] + 1m 0 [kV] 0 [J] - -20 [kV] q Your -20 [kV] More on [eV] How much energy does an electron gain when it is accelerated across a voltage of 20,000 [V] ? E = 20,000 [eV] [V] is a unit of “Potential” [eV] is a unit of Energy (can be converted to [J]) How can you convert [eV] to [J] ? Not too hard… the conversion is: 1 [eV] = 1.6x10-19 [J] So, let’s do an example ! Convert 20 [keV] to [J]. Since the “k” == kilo = 1000 = 103, 20 [keV] = 20,000 [eV] = 2x104 [eV] -19 1.6x10 [J] 4 −15 2x10 [eV] = 3.2 x10 [J] 1 [eV] =1 It’s a lot easier to say “20 [keV]” than 3.2x10-15 [J] ! Even more on [eV] So, [eV] IS A UNIT OF ENERGY; It’s not a “type” of energy (such as light, mass, heat, etc). When talking about energies of single photons, or of subatomic particles, we often use this unit of energy, or some variant of it. So, 1 [eV] = 1.6x10-19 [J] (can be used to go back & forth between these two energy units) 1 [keV] = 1000 [eV] = 103 [eV] 1 [MeV] = 1,000,000 [eV] = 106 [eV] 1 [GeV] = 1,000,000,000 [eV] = 109 [eV] “k = kilo (103)”” “M = mega (106)” “G = giga (109)” Example 1 A Cobalt-60 nucleus is unstable, and undergoes a decay where a 1173 [keV] photon is emitted. From what region of the electromagnetic spectrum does this come? The energy is 1173 [keV], which is 1173 [keV] = 1173x103 [eV] = 1.173x106 [eV]. * First convert this energy to [J], E = 1.173x106 [eV] * (1.6x10-19 [J] / 1 [eV]) = 1.88x10-13 [J] * Now, to get the wavelength, we use: E = hc/λ, that is λ = hc/E. So, λ = 6.63x10-34[J s]*3x108[m/s]/1.88x10-13 [J] = 1.1 x 10-12 [m] * Now, convert [m] to [nm], 1.1 x 10-12 [m] * (109 [nm] / 1 [m]) = 1.1x10-3 [nm] è It’s a GAMMA Ray Example 2 An electron has a mass of 9.1x10-31 [kg]. What is it’s rest mass energy in [J] and in [eV]. E = mc2 = 9.1x10-31*(3x108)2 = 8.2x10-14 [J] Now convert to [eV] 1 [eV] 5 = 8.2x10 [J] 5.1x10 [eV]=0.51 [MeV] -19 1.6x10 [J] -14 What is an electron’s rest mass? According to Einstein, m = E/c2, that is: [mass] = [Energy] / c2 m = E / c2 = 0.51 [MeV/c2] Example 3 A proton has a mass of 1.67x10-27 [kg]. What is it’s rest mass energy in [J] and in [eV]. E = mc2 = 1.67x10-27 *(3x108)2 = 1.5x10-10 [J] Now convert to [eV] 1 [eV] 8 = 1.5x10 [J] 9.4x10 [eV]=940 [MeV] -19 1.6x10 [J] -10 What is a proton’s rest mass? According to Einstein, m = E/c2, that is: [mass] = [Energy] / c2 m = E / c2 = 940 [MeV/c2] Proton vs Electron Mass How much more massive is a proton than an electron ? Ratio = proton mass / electron mass = 940 (MeV/c2) / 0.51 (MeV/c2) = 1843 times more massive You’d get exactly the same answer if you used: electron mass = 9.1x10-31 [kg] Proton mass = 1.67x10-27 [kg] Using [MeV/c2] as units of energy is easier… Neils Bohr and the Quantum Atom Circa 1910-1925 q Pointed out serious problems with Rutherford’s atom Ø Electrons should radiate as they orbit the nucleus, and in doing so, lose energy, until they spiral into the nucleus. ØAtoms only emit quantized amounts of energy (i.e., as observed in Hydrogen spectra) q He postulated Ø Electric force keeps electrons in orbit Ø Only certain orbits are stable, and they do not radiate energy Radiation is emitted when an e- jumps from an outer orbit to an inner orbit and the energy difference is given off as a radiation. 1885-1962 Awarded the Nobel Prize in 1922 Bohr’s Picture of the Atom Before Electrons circle the nucleus due to the Electric force After Radiated photon n= 5 4 3 2 Electron in lowest “allowed” energy level (n=1) 5 4 3 2 1 Electron in excited state (n=5) Allowed Orbits 1 Electron falls to the lowest energy level Note: There are many more energy levels beyond n=5, they are omitted for simplicity Atomic Radiation It is now “known” that when an electron is in an “excited state”, it spontaneously decays to a lower-energy stable state. The difference in energy, ∆E, is given by: E5 > E4 > E3 > E2 > E1 ∆E = E5 – E1 = hν = Εphoton One example could be: Energy E5 Electron in excited state (higher PE) Energy Electron in lowest state (lower PE) n=5 E5 n=5 E4 n=4 E4 n=4 E3 n=3 E3 n=3 E2 n=2 E2 n=2 E1 n=1 E1 n=1 Before After h = Planck’s constant = 6.6x10-34 [J s] ν = frequency of light [hz] The energy of the light is DIRECTLY PROPORTIONAL to the frequency, ν. Recall that the frequency, ν, is related to the wavelength by: c=νλ (ν = c / λ) So, higher frequency è higher energy è lower wavelength This is why UV radiation browns your skin but visible light does not ! Hydrogen atom energy “levels” Quantum physics provides the tools to compute the values of E1, E2, E3, etc…The results are: 2 En = -13.6 / n 5 4 3 2 1 Energy Level Energy En (eV) 1 -13.6 2 -3.4 3 -1.51 4 -0.85 5 -0.54 These results DO DEPEND ON THE TYPE OF ATOM OR MOLECULE So, the difference in energy between the 3rd and 1st quantum state is: Ediff = E3 – E1 = -1.51 – (-13.6) = 12.09 (eV) When this 3à 1 atomic transition occurs, this energy is released in the form of electromagnetic energy. Example 4 In the preceding example, what is the frequency, wavelength of the emitted photon, and in what part of the EM spectrum is it in? E = 12.1 [eV]. First convert this to [J]. 1.6x10-19 [J] −18 12.1 [eV] = 1.94 x10 [J] 1 [eV] Since E = hν è ν = E/h, so: ν = E/h = 1.94x10-18 [J] / 6.6x10-34 [J s] = 2.9x1015 [1/s] = 2.9x1015 [hz] λ = c/ν = (3x108 [m/s]) / (2.9x1015 [1/s]) = 1.02x10-7 [m] = 102 [nm] This corresponds to low energy X-rays ! Some Other Quantum Transitions Initial State Final State Energy diff. Energy diff. Wavelength [eV] [J] [nm] 10.2 1.6x10-18 121 2 1 3 1 12.1 1.9x10-18 102 4 1 12.8 2.0x10-18 97 3 2 1.89 3.0x10-19 654 4 2 2.55 4.1x10-19 485 5 2 2.86 4.6x10-19 432 4 3 0.66 1.05x10-19 1875 This completed the picture, or did it… q Electrons were discovered ~1900 by J. J. Thomson q Protons being confined in a nucleus was put forth ~1905 q Neutrons discovered 1932 by James Chadwick q Quantum theory of radiation had become “widely accepted”, although even Einstein had his doubts q Radiation is produced when atomic electrons fall from a state of high energy à low energy. Yields photons in the visible/ X-ray region. q A nucleus can also be excited, and when it “de-excites” it also gives QUARKS What IS Matter ? • Matter is all the “stuff” around you! • Here’s the picture we’re going to uncover (not all today though) Matter Hadrons Baryons Mesons Quarks Anti Anti-Quarks Quarks Leptons Charged Neutrinos Forces Gravity Weak Strong EM We’re going to work our way from the largest size objects which we know about to the smallest size objects which we know about Where does all this come from? The universe is a very big place! It is filled with galaxies much like our own, the Milky Way There are likely ~100 billion of them which we can “see”. Each of these galaxies contain around 100 billion stars. Fig: Small section of the universe, from the Hubble Space Telescope (HST) Our Milky Way galaxy is simply one of them. Our Sun is just one of the 10,000,000,000,000,000,000,000 stars in the universe! Our Galaxy: The Milky Way How big is the Milky Way (M.W.)? Its radius is about 100,000 light years ! How far is a light year (l.y.)? It’s the distance light travels in 1 year! So, 1 l.y. = 5,870,000,000,000 miles (5.9x1012 mi.) ! So, the M.W. Galaxy radius is about 600,000,000,000,000,000 (6x1017) miles in radius! Us (Our Solar System) The Center of our Solar System: The Sun At the center of our solar system is our star, the Sun It’s diameter is ~100 times that of the earth, which implies you could fit ~1,000,000 earths inside the sun! It’s is ~330,000 times as massive as the Earth The Sun (cont) It is a thermonuclear reactor. Inside the sun, hydrogen is being converted into helium. In this process, energy is released in the form of heat, electromagnetic waves (UV, visible light), neutrinos, etc. It’s surface temperature is ~10,000 OC; other parts of the sun can be as hot as 15,000,000 OC. So, it’s HOT ! Our Solar System: The Planets 3.6 billion miles Earth is at about 94 million miles from the Sun The Planets q The figure shows relative sizes of the planets q Distances between planets not drawn to scale q Astronomically, we’re pretty tiny! 3.6 billion miles Pluto Earth Saturn (Diam ~ 25000 mi.) Sun Jupiter Uranus Neptune The Earth Mass : 6 x 1024 [kg] Radius: 6.4 million meters Africa Ahhh, and finally we’re back home q So, to set the scale: q From here to California 2,500 miles q From here to the next closest star 25,000,000,000,000 miles (25 trillion miles) q Like traveling back and forth to California 10 billion times Not very practical to get even to the next closest star! Exercise The next closest star is about 25 trillion miles away. How long would it take an spacecraft moving at 20,000 miles/hr to get to this star? Well, every hour the spacecraft goes 20,000 miles (2x104 miles) So, the time it would take would be: (25 x 1012 [miles]) / 2x104 [miles/hr] = 1.25 billion hours = 52 million days = 143,000 years = 1,430 centuries! And then there’s US ! Ü We’re very small compared to the vast universe! ÜHowever, there are things which are a lot smaller than us. What are we made of ? q We’re made of cells which contain DNA. - Different cells serve different functions in your body. q Cells contain a nucleus, which holds your DNA ! q And the DNA is simply a complex chain of molecules which contains your genetic code! q And what are molecules made of ? 0.0002” The Elements †Molecules are complex structures of the elements The Atom Electrons Nucleus 5x10-15 m 0.0000000002 m (2 x 10-10 m) Atoms and Space Approximately what fraction of the volume of an atom does the nucleus consume? Assume that the nucleus and the atom can be approximated via spheres with the radii given below? Use the following data. • The radius of the nucleus is ~ 5x10-15 [m]. • The electrons orbits at a radius of ~ 2x10-10 [m] • Ignore the electrons size, as it is unimportant. • The volume of a sphere is (4/3)πR3. Answer… a) First find the volume of the entire atom Volume = (4/3)*π∗(2x10-10)3 = 3.4 x 10-29 [m3] b) Now find the volume which contains the nucleus. Volume = (4/3)*π∗(5x10-15)3 = 5.2 x 10-43 [m3] c) Now compute the fraction: Fraction = (5.2 x 10-43 / 3.4 x 10-29 ) = 0.000000000000015 In other words, more than 99.99999999% of an atom is empty space !!! What’s in the Nucleus? Protons Protons are positively charged and that amount of charge is exactly equal (and opposite) to the charge of the electron Neutrons Neutrons are similar to protons (ie., similar mass), but have a net charge of zero. Recall: 1 [fm] = 10-15 [m] Are protons and neutrons fundamental? (By fundamental, I mean are they indivisible? The answer is NO ! Protons and neutrons are made of smaller objects called quarks! 1x 10-18 m (at most) ØProtons 2 “up” quarks 1 “down” quark (1.6 x 10-15 m) ØNeutrons 1 “up” quark 2 “down” quarks Three Families of Quarks Generations Increasing mass Woohhh, fractionally charged particles? Charge = -1/3 Charge = +2/3 I II III d s b (down) (strange) (bottom) u c t (up) (charm) (top) Also, each quark has a corresponding antiquark. The antiquarks have opposite charge to the quarks The 6 Quarks, when & where… Quark Date Where Mass [GeV/c2] Comment up, down - - ~0.005, ~0.010 Constituents of hadrons, most prominently, proton and neutrons. strange 1947 - ~0.2 discovered in cosmic rays ~1.5 Discovered simultaneously in both pp and e+e- collisions. ~4.5 Discovered in collisions of protons on nuclei ~175 Discovered in pp collisions charm 1974 bottom 1977 top 1995 SLAC/ BNL Fermilab Fermilab How do we know any of this? qRecall that high energy particles provide a way to probe, or “see” matter at the very smallest sizes. (Recall Electron microscope example). q Today, high energy accelerators produce energetic beams which allow us to probe matter at its most fundamental level. q As we go to higher energy particle collisions: 1) Wavelength probe is smaller è see finer detail 2) Can produce more massive objects, via E=mc2 Major High Energy Physics Labs Fermilab DESY SLAC CERN CESR BNL KEK Fermilab Accelerator (30 miles from Chicago) Experimental areas Tevatron Top Quark discovered here at FNAL in 1995. 1.25 miles Main Injector “Typical” Particle Detector Typical physicist colleagues! Don’t ask me what they’re doing ! Summary q Protons and neutrons are made of up & down quarks. q The strange quark was uncovered in cosmic rays via their “strange” behavior. q Today, accelerators produce high energy beams of particles which illuminate the structure of matter. * Smaller deBroglie wavelength è finer microscope * Can produce massive particles which haven’t been around since the Big Bang! (E=mc2) q The charm, bottom and top quarks were all discovered by producing them artificially at high energy accelerators. Radioactivity Radiation Radiation: The process of emitting energy in the form of waves or particles. Where does radiation come from? Radiation is generally produced when particles interact or decay. A large contribution of the radiation on earth is from the sun (solar) or from radioactive isotopes of the elements (terrestrial). Radiation is going through you at this very moment! Isotopes What’s an isotope? Two or more varieties of an element having the same number of protons but different number of neutrons. Certain isotopes are “unstable” and decay to lighter isotopes or elements. Deuterium and tritium are isotopes of hydrogen. In addition to the 1 proton, they have 1 and 2 additional neutrons in the nucleus respectively*. Another prime example is Uranium 238, or just 238U. Radioactivity By the end of the 1800s, it was known that certain isotopes emit penetrating rays. Three types of radiation were known: 1) Alpha particles (α) 2) Beta particles (β) 3) Gamma-rays (γ) Where do these particles come from ? qThese particles generally come from the nuclei of atomic isotopes which are not stable. q The decay chain of Uranium produces all three of these forms of radiation. q Let’s look at them in more detail… Note: This is the atomic weight, which is the number of protons plus neutrons Alpha Particles (α) Radium Radon R226 Rn222 88 protons 138 neutrons + 86 protons 136 neutrons n p p n α (4He) 2 protons 2 neutrons The alpha-particle (α) is a Helium nucleus. It’s the same as the element Helium, with the electrons stripped off ! Beta Particles (β) Carbon C14 Nitrogen N14 6 protons 8 neutrons 7 protons 7 neutrons + eelectron (beta-particle) We see that one of the neutrons from the C14 nucleus “converted” into a proton, and an electron was ejected. The remaining nucleus contains 7p and 7n, which is a nitrogen nucleus. In symbolic notation, the following process occurred: nàp+e (+ν) Yes, the same neutrino we saw previously Gamma particles (γ) In much the same way that electrons in atoms can be in an excited state, so can a nucleus. Neon Ne20 10 protons 10 neutrons (in excited state) Neon Ne20 + 10 protons 10 neutrons (lowest energy state) gamma A gamma is a high energy light particle. It is NOT visible by your naked eye because it is not in the visible part of the EM spectrum. Gamma Rays Neon Ne20 Neon Ne20 + The gamma from nuclear decay is in the X-ray/ Gamma ray part of the EM spectrum (very energetic!) How do these particles differ ? Particle Mass* (MeV/c2) Charge Gamma (γ) 0 0 Beta (β) ~0.5 -1 Alpha (α) ~3752 +2 * m = E / c2 Rate of Decay qBeyond knowing the types of particles which are emitted when an isotope decays, we also are interested in how frequently one of the atoms emits this radiation. q A very important point here is that we cannot predict when a particular entity will decay. q We do know though, that if we had a large sample of a radioactive substance, some number will decay after a given amount of time. q Some radioactive substances have a very high “rate of decay”, while others have a very low decay rate. q To differentiate different radioactive substances, we look to quantify this idea of “decay rate” Half-Life The “half-life” (h) is the time it takes for half the atoms of a radioactive substance to decay. For example, suppose we had 20,000 atoms of a radioactive substance. If the half-life is 1 hour, how many atoms of that substance would be left after: #atoms remaining % of atoms remaining 1 hour (one lifetime) ? 10,000 (50%) 2 hours (two lifetimes) ? 5,000 (25%) 3 hours (three lifetimes) ? 2,500 (12.5%) Time Lifetime (τ) The “lifetime” of a particle is an alternate definition of the rate of decay, one which we prefer. It is just another way of expressing how fast the substance decays.. It is simply: 1.44 x h, and one often associates the letter “τ” to it. The lifetime of a “free” neutron is 14.7 minutes {τ (neutron)=14.7 min.} Let’s use this a bit to become comfortable with it… Lifetime (I) Ø The lifetime of a free neutron is 14.7 minutes. Ø If I had 1000 free neutrons in a box, after 14.7 minutes some number of them will have decayed. Ø The number remaining after some time is given by the radioactive decay law N = N 0e −t /τ N0 = starting number of particles τ = particle’s lifetime This is the “exponential”. It’s value is 2.718, and is a very useful number. Can you find it on your calculator? Lifetime (II) N = N0e Note by slight rearrangement of this formula: Fraction of particles which did not decay: −t /τ N / N0 = e-t/τ 1.20 0τ 1τ 2τ 3τ 4τ 5τ 0 14.7 29.4 44.1 58.8 73.5 Fraction of remaining neutrons 1.0 0.368 0.135 0.050 0.018 0.007 1.00 Fraction Survived # Time lifetimes (min) 0.80 0.60 0.40 0.20 0.00 0 2 4 6 8 10 Lifetimes After 4-5 lifetimes, almost all of the unstable particles have decayed away! Lifetime (III) q Not all particles have the same lifetime. q Uranium-238 has a lifetime of about 6 billion (6x109) years ! q Some subatomic particles have lifetimes that are less than 1x10-12 sec ! q Given a batch of unstable particles, we cannot say which one will decay. q The process of decay is statistical. That is, we can only talk about either, 1) the lifetime of a radioactive substance*, or 2) the “probability” that a given particle will decay. Lifetime (IV) q Given a batch of 1 species of particles, some will decay within 1 lifetime (1τ), some within 2τ, some within 3τ, and so on… q We CANNOT say “Particle 44 will decay at t =22 min”. You just can’t ! q All we can say is that: q After 1 lifetime, there will be (37%) remaining q After 2 lifetimes, there will be (14%) remaining q After 3 lifetimes, there will be (5%) remaining q After 4 lifetimes, there will be (2%) remaining, etc Lifetime (V) q If the particle’s lifetime is very short, the particles decay away very quickly. q When we get to subatomic particles, the lifetimes are typically only a small fraction of a second! q If the lifetime is long (like 238U) it will hang around for a very long time! Lifetime (IV) What if we only have 1 particle before us? What can we say about it? Survival Probability = N / N0 = e-t/τ Decay Probability = 1.0 – (Survival Probability) # lifetimes Survival Probability (percent) 1 2 3 4 5 37% 14% 5% 2% 0.7% Decay Probability = 1.0 – Survival Probability (Percent) 63% 86% 95% 98% 99.3% Summary q Certain particles are radioactive and undergo decay. q Radiation in nuclear decay consists of α, β, and γ particles q The rate of decay is give by the radioactive decay law: Survival Probability = (N/N0)e-t/τ q After 5 lifetimes more than 99% of the initial particles have decayed away. q Some elements have lifetimes ~billions of years. q Subatomic particles usually have lifetimes which are fractions of a second… We’ll come back to this! The Need for a “Strong Force” Why do protons stay together in the nucleus, despite the fact that they have the same electric charge? è They should repel since they are like charge Why do protons and neutrons in the nucleus bind together? è Since the neutron is electrically neutral, there should be no EM binding between protons and neutrons. Search for a Theory of Strong Interactions q By the 1960’s, Feynman et al, had fully developed a “quantum” theory which accounted for all EM phenomenon. This theory is called Quantum Electrodynamics (or QED for short). q Because of this remarkable success, scientists developed an analogous theory to describe the strong interaction. It is called Quantum Chromodynamics (or QCD for short). q Scientists conjectured that, like the EM force, there is also a quantum of the strong force, and called it the gluon. The Strong Force q For the EM interactions, we learned that: The photon mediates the interaction between objects which carry electrical charge q For the Strong Interactions, we conjecture that: A force carrier, called the gluon mediates the interaction between objects which carry color charge (that is, the quarks, and …gluons !). q The most striking difference between the gluon and the photon is: The gluon carries color charge, but the photon does not carry electric charge. è Gluons can interact with other gluons !!!! Comparison Strong and EM force Property EM Strong Force Carrier Photon (γ) Gluon (g) Mass 0 0 Charge ? None Yes, color charge Charge types +, - red, green, blue Couples to: All objects with electrical charge Range Infinite (1/d2) All objects with color charge ˆ10-14 [m] (inside hadrons) Color Charge of Quarks q Recall, we stated, without much explanation, that quarks come in 3 colors. q “color charge” çè “electrical charge” çè strong-force EM force. as q Experiments show that there are 3 colors; not 2, not 4, but 3. q Again, this does not mean that if you could see quarks, you would see them as being colored. This “color” that we refer to is an “intrinsic property” and color is just a nice way to visualize it. Color of Hadrons (II) BARYONS q1 q2 RED + BLUE + GREEN = “WHITE” or “COLORLESS” q3 MESONS q q q q q q GREEN + ANTIGREEN = “COLORLESS” RED + ANTIRED = “COLORLESS” BLUE + ANTIBLUE = “COLORLESS” Color of Gluons rb rg bg br Each of the 8 color combinations have a “color” and an “anti-color” When quarks interact, they “exchange” color charge. gb gr rr + gg − 2bb rr − gg rg Don’t worry about what this means Quark 1 rg rg Quark 2 Color & the Strong Force Flow of Color Charge rg rg rg Emission of Gluon Initially RED (quark) After gluon emission è RED-ANTIGREEN (gluon) + GREEN (quark) Re-absorption of Gluon Before gluon absorption RED-ANTIGREEN + GREEN è (gluon) (quark) After gluon absorption RED (quark) Color Exchange Quarks interact by the exchange of a gluon. Since gluons carry color charge, it is fair to say that the interaction between quarks results in the exchange of color charge (or just color) ! Gluons – Important Points q Gluons are the “force carrier” of the strong force. q They only interact with object which have color, or color charge. q Therefore, gluons cannot interact with leptons because leptons do not have color charge ! q e+ g e- q This cannot happen, because the gluon does not interact with objects unless they have color charge! Feynman Diagrams for the Strong Interaction qAs before, we can draw Feynman diagrams to represent the strong interactions between quarks. q The method is more or less analogous to the case of EM interactions. q When drawing Feynman diagrams, we don’t show the flow of color charge (oh goody). It’s understood to be occurring. q Let’s look at a few Feynman diagrams… Feynman Diagrams (Quark Scattering) q q Quark-antiquark Annihilation q Quark-quark Scattering Could also be Quark-antiquark Scattering or Antiquark-antiquark Scattering g q q q g q q time Where do we get quark and antiquarks from? Quarks u d PROTON u And, antiquarks?… u d ANTIPROTON u Flashback to EM Interactions Recall that photons do not interact with each other. Why? Because photons only interact with objects which have electric charge, and photons do not have electric charge ! γ γ γ γ γ This can’t happen because the photon only interacts with electrically charged objects ! BUT GLUONS DO !!! Gluons carry the “charge” of the strong force, which is “color charge”, or just “color” ! Ok, so here’s where it gets hairy! Since gluons carry “color charge”, they can interact with each other ! (Photons can’t do that) Gluon-gluon Scattering Gluon-gluon Fusion g g g g g g g g g g And quark-gluon interactions as well! Since both quarks and gluons have color, they can interact with each other !!! Quark-Antiquark Annihilation Quark-gluon Scattering q q q g g g g g q g Where do the gluons come from ? qThe gluons are all over inside hadrons!! Proton q In fact there are a lot more than shown here !!! u d q Notice sizes here: In fact quarks are < 1/1000th of the size of the proton, so they are still too big in this picture ! ~10-15 [m] q Even protons and neutrons are mostly empty space !!! u Confinement Since the strong force increases as quarks move apart, they can only get so far… The quarks are confined together inside hadrons. Hadron jail ! Hadronization As quarks move apart, the potential energy associated with the “spring” increases, until its large enough, to convert into mass energy (qq pairs) Hadrons! u u u u u u u d s s u u d d In this way, you can see that quarks are always confined inside hadrons (that’s CONFINEMENT) ! ΚΚ+ π- d d d d π0 What holds the nucleus together? The strong force ! q Inside the nucleus, the attractive strong force is stronger than the repulsive electromagnetic force. q Protons and neutrons both “experience” the strong force. q The actual binding that occurs between proton-proton and proton-neutron is the residual of the strong interaction. Food for thought Recall: Mass of Proton ~ 938 [MeV/c2] Proton constituents: 2 up quarks: 2 * (5 [MeV/c2]) = 10 [MeV/c2] 1 down quark: 1 * 10 [MeV/c2] = 10 [MeV/c2] Total quark mass in proton: ~ 20 [MeV/c2] Where’s all the rest of the mass ????? It’s incorporated in the binding energy associated with the gluons ! è ~98% of our mass comes from glue-ons !!!! Summary (I) q The property which gives rise to the strong force is “color charge” q There are 3 types of colors, RED, GREEN and BLUE. q Quarks have color charge, and interact via the mediator of the strong force, the gluon. q The gluon is massless like the photon, but differs dramatically in that: q It has color charge q It’s force acts over a very short range (inside the nucleus) Summary (II) q Because gluons carry color charge, they can interact among themselves. q Quarks and gluons are confined inside hadrons because of the nature of the strong force. q Only ~50% of a proton’s energy is carried by the quarks. The remaining 50% is carried by gluons. q We learn about the strong force by hadron-hadron scattering experiments. Right after the Big Bang, particles called quarks unite in groups of three to form the first nucleons: neutrons and protons. Action Verbs A Project LA Activity jump What is an action verb? • A verb is one of the most important parts of the sentence. It tells the subjects actions, events, or state of being. It is always found in the predicate of a sentence. A verb that shows action is called an action verb. The words are action verbs: ran coughed swallowed ride sang awake Can you find the action verb in each sentence? 1. The girls danced in the recital. 2. Our mailman drove a funny car last week. 3. His teacher wrote the answers on the board. 4. Alice worked on her homework Move On last night. No, try again. Yes, that word is an action verb! Try another sentence Move On Present verbs • An action verb that describes an action that is happening now is called a present tense verb. verb The bird flies through the sky. Flies is a present tense verb because it is happening right now. Present tense verbs • Many present tense verbs end with s, but some end with es es, or ies. ies cries ies sleepss splashes es Past Verbs • Verbs which tell about actions which happened some time ago are past tense verbs. The dog wanted a bone. Wanted is a past tense verb because the action has already happened. Past tense verbs • Many past tense verbs end with ed, but some end with d, or ied ied. tried clapped played Future Verbs • Verbs which tell about actions which are going to happen are future verbs. We will tense awaken at six a.m. Will awaken is a future tense verb because the action has not yet happened. Future tense verbs • Future tense verbs use special words to talk about things that will happen: will, going to, shall, aim to, etc. going to start will enjoy shall email Helping Verbs • A helping verb works with a main verb to help you understand what action is taking place. Elmer was using the computer. 23 Helping Verbs do may be might being does must been did am are is was were (main) (main) should have could had would has (main) will can shall Helping Verbs Other things to keep in mind: •Not every sentence will have a helping verb with the main verb. •When you see an "ing" verb such as "running", be on the lookout for a helping verb also. Helping Verbs •Sometimes there is another word which separates the helping verb from the main verb. One common example is "not", as in: The boy couldn't find his socks. The helping verb is could and the main verb is find. Helping Verbs •A sentence may contain up to three helping verbs to the main verb. An example would be: The dog must have been chasing the cat. The helping verbs are: must, have, and been; the main verb is chasing. Online Verb Games HitTake the Back ArrowQuiz on your browser to return. Dave’s Helping Verb Quiz Print and complete the Action Verb Worksheet Find the Verb Game Jeopardy Challenge Board Present and Past Tense Matching Game Verb Machine More Verb Activities • • • • Irregular Verb Worksheet Verb Concentration Game ANTS PICNIC (Irregular Verb Game) Verb Worksheet MAIN Putting it all together What IS Matter ? • Matter is all the “stuff” around you ! • Here’s the picture we’ve uncovered Matter Hadrons Baryons Mesons Quarks Anti Anti-Quarks Quarks Leptons Charged Neutrinos Forces Gravity Weak Strong EM The Quarks Family Quark Charge Mass [MeV/c2] Quark Charge Mass [MeV/c2] 1 d -1/3 ~10 u +2/3 ~5 2 s -1/3 ~200 c +2/3 ~1500 3 b -1/3 ~4500 t +2/3 ~175,000 Ø Each quark has a corresponding antiquark. Ø Antiquarks have opposite charge to their quark. Ø Huge variation in the masses, from 5 [MeV/c2] to 175,000 [MeV/c2]. The Leptons Family Charged Charge Mass [MeV/c2] Neutral Charge Mass [MeV/c2] eµ− τ− ~0.51 ~105 ~1780 νe νµ ντ 0 0 0 ~0 ~0 ~0 1 2 3 -1 -1 -1 Ø Each lepton has a corresponding anti-lepton. Ø Antileptons have opposite charge to their lepton. Ø Huge variation in the masses, from 0.5 [MeV/c2] to 1,780 [MeV/c2]. Forces q Forces are the due to the exchange of force carriers. q For each fundamental force, there is a force carrier (or set of them). q The force carriers only “talk-to” or “couple to” particles which carry the proper charge. Electromagnetic: the photon (γ) Electric Charge (+, -) Strong: the gluon (g) Color Charge (r,g,b) Weak: the W+, W- & Z0 Weak Charge Particles & Forces quarks Charged leptons (e,µ,τ) Neutral leptons (ν) Color Charge ? Y N N EM Charge ? Y Y N Weak Charge ? Y Y Y q Quarks can participate in Strong, EM & Weak Interactions ! q All quarks & all leptons carry weak charge In other words… q Since quarks have color charge, EM charge & weak charge, they can engage in all 3 types of interactions ! q Charged leptons (e,µ,τ) carry EM and weak charge, but no strong charge. Therefore, they can participate in the EM & weak interaction, but they cannot participate in the strong interaction. q Neutrinos only carry weak charge, and therefore they only participate in the weak interaction è they can pass through the earth like it wasn’t even there ! Why should we believe that forces are the result of force carriers? q The Standard Model (SM) which I have describe to you is just that, it’s a model, or better yet, a theory. q All forces are described by exchange of force carriers, period ! q It’s is an extremely successful theory. q It explains all subatomic phenomenon to extraordinary precision! One example is in a quantity referred to as the electron’s “g-factor” “g” from experiment: “g” from theory (SM): 2.0023193043768 2.0023193043070 They agree to better than 1 part in 10 billion ! Coincidence ? Particle or Wave? Two benchmark experiments established the foundation for the particle nature of light 1. Photoelectric Effect 2. Compton Effect Both experiments indicated that light was acting like a particle with energy and momentum given by: E = hν = hc / λ p = E / c = (hc / λ) / c =h/λ Uses c = λν q This light particle has energy and momentum, but no mass !!! q It’s energy & momentum are inversely proportional to the wavelength Photoelectric Effect “Classical” Method What if we try this ? Increase energy by increasing amplitude Vary wavelength, fixed amplitude electrons emitted ? No No No No electrons emitted ? No Yes, with low KE Yes, with high KE No electrons were emitted until the frequency of the light exceeded a critical frequency, at which point electrons were emitted from the surface! (Recall: small λ è large ν) The Electromagnetic Spectrum Shortest wavelengths (Most energetic photons) E = hν = hc/λ h = 6.6x10-34 [J*sec] (Planck’s constant) Longest wavelengths (Least energetic photons) The EM force and the Photon q The photon is the carrier of the EM force. q It can only “talk-to” particles which have electric charge. q A photon does NOT have electric charge, and therefore it cannot interact with other photons q While the photon is massless, it does carry both momentum & energy given by: p=h/λ E = pc = hc / λ = hν q When charged particles exchange photons, they are exchanging this momentum. One particle emits the photon & the other absorbs it ! q Can also have particle-antiparticle annihilation into a photon. Electromagnetic Force Quark Pair Production e+ e- q γ q Detectable hadrons, such as π+, π-, π0, p, n, etc Electron – Proton Collision ! e e u u hadrons Proton u d e- hadrons eγ u u d u This the Feynman diagram for an electron scattering off an up quark ! Actual e+e- Collision at Cornell’s Collider e + + e − → qq → hadrons E ~ 5 [GeV] for the e+ and eHadrons which are charged and are “bent” by a magnetic field Side view of Detector Event is not balanced… Probably a ν in this interaction ν? Another e+ e- Collision at CERN + − e + e → qq LOTS MORE HADRONS !!! → hadrons E ~ 103 [GeV] for the e+ and e- How much energy is needed to produce a t t pair via an e+e- Collision ? t e+ Me = 0.5 MeV/c2 Mt = 175 GeV/c2 e- t What minimum energy is needed by each incoming particle to produce the top and antitop quark? A) 175 MeV B) 350 GeV C) 175 GeV D) 350 MeV What maximum mass particle can be produced? particle q Ee = 115 GeV (each) q antiparticle What maximum mass particle can be created in this collision ? A) 115 MeV/c2 B) 230 GeV/c2 C) 115 GeV/c2 D) 230 MeV/c2 Strong Force and the Gluon q The gluon is the carrier of the strong force. q Unlike the EM force, it gets stronger as quarks separate ! q It can only “talk-to” particles which have color charge (quarks). q Since gluons do have color charge, they can interact with other gluons ! q The gluon is also massless. q When quarks exchange gluons, they are exchanging color charge. One quark emits the gluon & the other absorbs it ! q Quarks and antiquarks can annihilate into a gluon! Color (or Color charge) ØLike electric charge, quarks have an internal property which allows gluons to interact with them (i.e., couple to them). ØThis property is called color. Quarks can have one of three colors: red, green, or blue. Ø Antiquarks have anticolor: antired, antigreen or antiblue. Ø Gluons also carry color (r b, b g, g r, etc ), and therefore can interact among themselves !!! This is the most striking difference between gluons & photons! Ø FYI, it is the fact that gluons have color which leads to confinement Hadrons q Because of the strong force, quarks are bound into hadrons. q Hadrons are simply particles which interact via the strong force. q Our inability to directly observe the color of hadrons have lead us to believe that all hadrons are colorless q There are two types of hadrons: Baryons: bound state of any 3 quarks (except the top quark) ( 1 red + 1 green + 1 blue == colorless ) Mesons: bound state of a quark and antiquark (except t) one color + one anticolor ( r r, g g, or b b ) == colorless ) q Antibaryons contain 3 antiquarks Proton-Proton Collision hadrons u u u d u u hadrons d u u u u u u d u u u u d u d u u d u d u u d u hadrons d u u d d hadrons d The up & down quarks have exchanged a gluon, and hence underwent an interaction! Quark-Quark Interaction to hadrons d u u to hadrons u u g d u u d d to hadrons to hadrons Quark-Gluon Interaction d u u to hadrons to hadrons g g g d u u d d to hadrons to hadrons Hadronization As quarks move apart, the potential energy associated with the “spring” increases, until its large enough, to convert into mass energy (qq pairs) Hadrons! u u u u u u u d s s u u d d In this way, you can see that quarks are always confined inside hadrons (that’s CONFINEMENT) ! ΚΚ+ π- d d d d π0 p p à t t from Fermilab Jet = spray of particles when a quark undergoes hadronization 4 jets è 4 quarks emerging from the interaction. Putting it all together The Carriers of the Weak Force qThree force carriers for the weak force: W+, W- and Z0 q The W+ and W- are the ones I have emphasized, and their role in the decay of heavy quarks to lighter quarks. q The W+ and W- carry both electrical and weak charge. qThey “connect” the +2/3 charge quarks with the –1/3 charge quarks (a change in charge of 1 unit). q These range of the weak force is very short !! It’s about 10-18 [m], which is about 10,000 times smaller than the range of the strong force Particles & Forces quarks Charged leptons (e,µ,τ) Strong Y N N ElectroMagnetic Y Y N Y Y Y Weak Neutral leptons (ν) Quarks carry strong, weak & EM charge !!!!! Weak Force qThey W and Z particles can only“talk-to” particles which have weak charge (the leptons and the quarks !). q Heavy quark decay to lighter quarks via emission of a W+ or W-. q The weak force is also responsible for neutron decay. q Because the weak force is sooo weak, neutrinos can pass through matter (like the earth) as if it wasn’t there ! q Quarks and leptons can interact by exchanging a W or Z force carrier… Neutron Decay (cont) u d d Neutron n u u d + W- Proton p + e- + νe e- + νe + νe But in fact, what’s really going on is this: d u + e- What about the decay of a b-quark? − b à c + µ + νµ νµ 0 µ- -1 Wb c -1/3 +2/3 Notice: Here, the W- decays to a µ− and νµ,could have also been a e−νe, or τ−ντ b-quark decay at the hadron level Decay of a B- Meson Could end up as: B- à D0 π− u W- B- b u B- à D0 π−π0 d c 0 D u B- à D0 π− π+ π− etc qAdditional particles are created when the strong force produces more quark-antiquark pairs. They then combine to form hadrons! q Notice that the charge of the particles other than the D0 add up to the charge of the W- (Q = -1), as they must! Hadronization – Producing hadrons! Hadrons! u u π0 u u u u d π- d d d In this way, you can see that quarks are always confined inside hadrons (that’s CONFINEMENT) ! uu pair produced by converting energy stored in the “stretched spring” into mass energy… Conservation Laws q Conservation of Total Energy q Conservation of Total Momentum q Conservation of Electric Charge q Conservation of Baryon Number q Conservation of Lepton Number (Le, Lµ, and Lτ) Energy Conservation (I) A+B à C +D q Energy conservation means: Energy of particle “A” + Energy of particle “B” = Energy of particle “C” + Energy of particle “D” q Or, in simpler notation, EA + EB = EC + ED If you knew any 3 of the energies, you could compute the fourth! è So, in such a reaction, you only need to measure 3 particles, and energy conservation allows you to compute the fourth! Energy Conservation (II) Decay Process: A à B + D If particle A has non-zero mass (mA > 0), then: mB < mA mD < mA This is a consequence of energy conservation (see lecture 24) ! B D A EB=MBc2 B EA=MAc2 A ED=MDc2 D This can’t happen if MB>MA, or MD>MA This can happen Interaction – Conversion of KE to Mass π0 n π+ p π0 p p p p ππ0 n p Notice that the total mass of the particles after the interaction is larger than the incoming masses (2 proton masses) ! This is OK, as long as the incoming protons have enough kinetic energy to produce all these particles Then why can’t this happen in decays? Well, according to me, this neutron is at rest ! So, ha ! Therefore it cannot decay to something heavier!! That would violate energy conservation ! n Now, if the neutron is zipping along, and it has a lot of KE, why can’t it decay to something heavier by converting some of its KE into mass ??? Momentum Conservation (I) e+ e- (I) If this electron & positron have equal & opposite velocity, what can be said about their total momentum? A) It’s twice as large B) It’s zero C) It’s negative D) It’s positive Bam (II) What can be said about the total momentum of all the particles which are produced in this collision at top? A) It’s positive B) It’s negative C) It’s same as in (I) D) It’s 0.5 [MeV/c] Momentum Conservation (II) neutron at rest appears to decay to a proton + electron p n ν e mP me Since both the electron and proton are both moving off to the right, their total momentum cannot be zero. è In other words, this reaction, as shown cannot occur, since it would violate momentum conservation. This is precisely what lead to the conjecture that there must be an undetected particle, called the neutrino! Charge Conservation Consider the process: π+ + p à n + π0 Can it occur? What about this one ? π+ + n à p + π0 What about this one ? π+ + p à π0 + π0 Total charge on left has to equal total charge on right in order for charge to be conserved! The process could still be forbidden to occur if it violates some other conservation law ! Baryon Number Conservation Rules of the game: For each baryon, assign B = +1 For each antibaryon, assign B = -1 Compare total Baryon number on left side to right side… Y N π+ + p à π0 + π0 X p + p à p + π+ + n + π0 X n à π0 + π0 X n àp+p X p + p à n + n + π+ + π− X Why can’t the proton decay ? pà?+?+? Since baryon number must be conserved , there MUST BE a baryon among the “?” decay products. But, the proton is the lowest mass baryon (938 [MeV/c2]). So there is nowhere it can go ! It CANNOT decay into something heavier, as this would violate energy conservation ! p 938 [MeV/c2] à < n + e+ + νe 940 + 0.51 + ~0 [MeV/c2] [MeV/c2] [MeV/c2] Lepton Number Conservation A+B à C +D At it’s heart, it’s just: Total lepton number on LHS = Total lepton number on RHS All leptons get assigned: L = +1 All antileptons get assigned: L = -1 But, it’s more powerful than that ! It can be applied for “electron-type”, “muon-type” and “tau-type” objects separately! Example Photon Conversion: γ à e+ + µLepton Antilepton q If we don’t distinguish between “electron-type” and “muon-type” objects, we would conclude that this process can occur, since we have a lepton and anti-lepton on the RHS ! q If we require both Le and Lµ conserved separately, we see that this process violates both è cannot occur ! And, in fact this process is never observed… γ à e+ + µLe Lµ 0 0 -1 0 0 1 X X Example II n à p + e+ + νµ Energy (Check mass) 940 [MeV/c2] 938 [MeV/c2] 0.51 [MeV/c2] ~0 [MeV/c2] Charge 0 -1 +1 0 Baryon Number -1 -1 0 0 Le 0 0 -1 0 Lµ 0 0 0 +1 The Big Bang ! Everything that could have possibly existed, did exist ! ss νe e− ντ νµ cc + µ+ τ dd uu τ µ− − tt bb ντ νµ e + νe And ??? Matter today q Today, the universe is a relatively cold place (remember the 3o microwave background… that’s –270 oC) q Nearly all heavy quarks have decayed through the weak interaction into up & down quarks. tàbàcà sàu àd q The up & down quarks which are the lightest of the quarks are the lightest, and have combined to form protons & neutrons q The protons and neutrons have combined with electrons to form our atomic elements…and hence, US ! q The heavy quarks are produced in cosmic rays or at large accelerator laboratories, like Fermilab.. Space is mostly “empty space” Atoms are > 99.999% empty space Electron γ Nucleus Protons & Neutrons are > 99.999% empty space g u Proton u The quarks make up a negligible fraction of the protons volume !! d The Universe The universe and all the matter in it is almost all empty space ! (YIKES) So why does matter appear to be so rigid ? Forces, forces, forces !!!! It is primarily the strong and electromagnetic forces which give matter its solid structure. Strong force è defines nuclear size Electromagnetic force è defines atomic sizes So why is this stuff interesting/important? qAll matter, including us, takes on its shape and structure because of the way that quarks, leptons and force carriers behave. q Our bodies, and the whole universe is almost all empty space ! q By studying these particles and forces, we’re trying to get at the question which has plagued humans for millenia … How did the universe start? And how did we emerge from it all?