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Atomic Theories Atomic Theories First Thoughts • People began wondering about matter more than 2,500 years ago. • Some of the early philosophers thought that matter was composed of tiny particles. • They reasoned that you could take a piece of matter, cut it in half, cut the half piece in half again, and continue to cut again and again. • Eventually, you wouldn’t be able to cut any more. You would have only one particle left. • They named these particles atoms, a term that means “cannot be divided.” A Model of the Atom- a model is a simplified representation, a picture. • During the eighteenth century, scientists in laboratories began debating the existence of atoms once more. • Chemists were learning about matter and how it changes. • They found that certain substances couldn’t be broken down into simpler substances. • Scientists came to realize that all matter is made up of elements. • An element is matter made of atoms of only one kind. Classifications of Matter Matter Yes Yes Can it be separated by physical means? Is the composition uniform? Homogeneous mixture No Pure substance Mixture Yes Yes No No No Heterogeneous mixture Can it be decomposed by ordinary chemical means? Yes Yes Compound No No Element Chemical Laws • Law of Conservation of Mass or matter states that mass is neither created nor destroyed in ordinary chemical reactions. • Law of Definite Proportions- the fact that a specific chemical compound contains the same elements in exactly the same proportions by mass regardless of the size of the sample or the source of the sample. • Law of Multiple Proportions- if two or more different compounds are composed of the same two elements, then the ration of the masses of the second element combined with a certain mass of the first element is always a ration of small whole numbers. Examples • Law of Definite Proportions • Carbon Dioxide – Always 73% oxygen and 27% carbon by weight • Law of Multiple Proportions • Carbon Monoxide – 6 grams of carbon, 8 grams of oxygen • Carbon Dioxide – 6 grams of carbon, 16 grams of oxygen Dalton’s Concept (1766-1844) • John Dalton, an English schoolteacher proposed the following ideas about matter: 1. Matter is made up of atoms. *2. Atoms cannot be divided into smaller pieces. *3. All the atoms of an element are exactly alike. 4. Different elements are made of different kinds of atoms. • Dalton pictured an atom as a hard sphere that was the same throughout. Scientific Evidence • In 1870, the English scientist William Crookes did experiments with a glass tube that had almost all the air removed from it. • The glass tube had two pieces of metal called electrodes sealed inside. • The electrodes were connected to a battery by wires. A Strange Shadow • One electrode, called the anode, has a positive charge. • The other, called the cathode, has a negative charge. • When the battery was connected, the glass tube suddenly lit up with a greenish-colored glow. A Strange Shadow • A shadow of the object appeared at the opposite end of the tube—the anode. • The shadow showed Crookes that something was traveling in a straight line from the cathode to the anode, similar to the beam of a flashlight. Cathode Rays • Crookes hypothesized that the green glow in the tube was caused by rays, or streams of particles. • These rays were called cathode rays because they were produced at the cathode. • Crookes’s tube is known as a cathode-ray tube, or CRT. – • Old TV or computer monitor. J.J Thompson • In 1897, J.J. Thomson, an English physicist, tried to clear up the confusion. • He placed a magnet beside the tube from Crookes’s experiments. • The beam is bent in the direction of the magnet. • Light cannot be bent by a magnet, so the beam couldn’t be light. The Electron • Thomson concluded that cathode rays are charged particles of matter. • Based on the direction the beam bent in the magnetic field he reasoned that the beam was negative charges. • He observed that these particles were attracted to the positively charged anode, so he reasoned that the particles must be negatively charged. The Electron • These negatively charged particles are now called electrons. • Thomson also inferred that electrons are a part of every kind of atom because they are produced by every kind of cathode material. • If atoms contain one or more negatively charged particles, then all matter, which is made of atoms, should be negatively charged as well. • But matter is not negatively charge. • Atoms must also contain some positive charge? Thomson’s Atomic Model • Thomson pictured a sphere of positive charge. • The negatively charged electrons were spread evenly among the positive charge. • The atom is neutral. • Plum pudding model (chocolate chip cookie) Chocolate Chip Cookie Model Rutherford’s Experiments • Ernest Rutherford and his coworkers began an experiment to find out if Thomson’s model of the atom was correct. • They wanted to see what would happen when they fired fast-moving, positively charged bits of matter, called alpha particles, at a thin film of metal such as gold. Rutherford’s Gold Foil Experiment A Model with a Nucleus They might have drawn diagrams like those which uses Thomson’s model and shows what Rutherford expected. Most alpha particles could move through the foil with little or no interference. Some alpha particles bounced back at them. Shoot a tissue with a 22 and the bullet bounces back The Proton • This figure shows how Rutherford’s new model of the atom fits the experimental data. • Most alpha particles could move through the foil with little or no interference. But some bounce back. Rutherford’s Model • The actual results did not fit Thompson’s model, so Rutherford proposed a new one. • He hypothesized that almost all the mass of the atom and all of its positive charge are crammed into an incredibly small region of space at the center of the atom called the nucleus. Most of the atom is empty space. The Proton • In 1920 scientists identified the positive charges in the nucleus as protons. • A proton is a positively charged particle present in the nucleus of all atoms. The Neutron • An atom’s electrons have almost no mass. • According to Rutherford’s model, the only other particle in the atom was the proton. • That meant that the mass of an atom should have been approximately equal to the mass of its protons. The Neutron • However, it wasn’t. • The mass of most atoms is at least twice as great as the mass of its protons. • It was proposed that another particle must be in the nucleus to account for the extra mass. • The particle, which was later call the neutron (NEW trahn), would have the same mass as a proton and be electrically neutral. The Neutron • Proving the existence of neutrons was difficult though, because a neutron has no charge. • It took another 20 years before scientists were able to show by more modern experiments that atoms contain neutrons. • Chadwick The Neutron • The model of the atom was revised again to include the newly discovered neutrons in the nucleus. • The nuclear atom has a tiny nucleus tightly packed with positively charged protons and neutral neutrons. Negatively charged (electrons) particles surround this nucleus Further Developments • Then, electrons would travel in orbits around the nucleus. • A physicist named Niels Bohr even calculated exactly what energy levels those orbits would represent for the hydrogen atom. • However, scientists soon learned that electrons are in constant, unpredictable motion and can’t be described easily by an orbit. Electrons as Waves • Physicists began to wrestle with explaining the unpredictable nature of electrons. • The unconventional solution was to understand electrons not as particles, but as waves. • This unconventional solution also applied to light waves which can be thought of as particles. The Electron Cloud Model • The new model of the atom allows for the somewhat unpredictable wave nature of electrons by defining a region where electrons are most likely to be found. • Electrons travel in a region surrounding the nucleus, which is called the electron cloud. Size and Scale • Drawings of the nuclear atom don’t give an accurate representation of the extreme smallness of the nucleus compared to the rest of the atom. • For example, if the nucleus were the size of a table-tennis ball, the atom would have a diameter of more than 2.4 km. • A football field is 100 m so 10 football fields is 1 km so 2.4 km = 24 football fields Atomic Models • • • • • • Ancient Greek- “cannot be divided” John Dalton’s Theory- simple sphere Thompson’s Model- plum pudding Rutherford- Electron/Proton Model Bohr- Orbital Model/ Neutron Modern – electron Cloud Model – Protons, Neutrons, Electrons • Current Model – Protons and neutrons made up of quarks Dalton’s Concept (1766-1844) • John Dalton, an English schoolteacher proposed the following ideas about matter: 1. Matter is made up of atoms. *2. Atoms cannot be divided into smaller pieces. *3. All the atoms of an element are exactly alike. 4. Different elements are made of different kinds of atoms. • Dalton pictured an atom as a hard sphere that was the same throughout. Identifying Numbers Page 512 • The atoms of different elements contain different numbers of protons. • The atomic number of an element is the number of protons in the nucleus of an atom of that element. Designated as Z • Atoms of an element are identified by the number of protons because this number never changes without changing the identify of the element. Number of Neutrons • Most atoms of carbon have six neutrons, some have 7 and some have 8. • They are all carbon atoms because they all have six protons. • These three kinds of carbon atoms are called isotopes. Isotopes (I suh tohps) are atoms of the same element that have different numbers of neutrons. Mass Number • The mass number of an isotope is the number of neutrons plus protons. Also called the atomic mass. Designated A Atomic Number, Atomic Mass, and # of Neutrons • mass number = #protons + # neutrons • # protons = atomic number • Number of neutrons = mass number – atomic number • Number of neutrons = A – Z Find the number • How many neutrons in Iodine-131? • What is the atomic mass number of a copper isotope with 34 neutrons? • Worksheet