PHYS-2020: General Physics II Course Lecture Notes Section IX Dr. Donald G. Luttermoser

... lines. Often, however, these dividing lines are fuzzy such that one scientist might call a long IR photon a microwave whereas another would refer to it as a microwave. a) Gamma rays: Highest energy, highest frequency, and shortest wavelengths: λ < 0.01 nm. These types of photons are given off by nuc ...

ppt

Math Module II Review

... This is an awesome light show caused by the atoms of the atmosphere getting their electrons “excited” by high energy particles from the sun. It happens near the poles due to the magnetic field of the Earth being thinner there. ...

Answers to Homework #6 on Chapter 5

Modern Physics FRQ Problem Set

... A free electron with negligible kinetic energy is captured by a stationary proton to form an excited state of the hydrogen atom. During this process a photon of energy Ea is emitted, followed shortly by another photon of energy 10.2 electron volts. No further photons are emitted. The ionization ener ...

Modern Atomic Theory Part One

Pre-class 11

... - Carl Wieman, Nobel Laureate in Physics 2001 ...

Atoms and quantum phenomena

... de Broglie wavelength of an electron • When you accelerate at about 100V then the wavelength is of the order of 10-10m. This is of the same magnitude as an X-ray. We know that X-rays can diffract because of their wave properties and so if this were all true and electrons could exhibit wave behaviou ...

Photoelectric Effect Wear Safety Goggles whenever a mercury light

... When the Java applet opens, you will see a lamp placed next to a photocell. You can adjust the intensity and color of the light by using slide controls in the applet. The light shines on an electrode called the “photocathode.” The electrons are ejected from the photocathode by the light. The other e ...

Chapter 5 – Organic Analysis

Unit 3 EMR 2015

The Electromagnetic spectrum and light

... Gamma Rays • Have the highest frequency and are the most penetrating of electromagnetic waves! • They are emitted from the nuclei of radioactive atoms. • Earth receives some from space. • Can be used to kill cancer cells. ...

PPT - IIT Kanpur

... 1. Optical interactions depend on the Electric field in the light wave. 2. Valence/outer `bound’ electrons that respond to this field. ...

Chapter 5 - Taylor County Schools

... • The wave model of light cannot explain all of light’s characteristics. • An example is the photoelectric effect , when electrons are emitted from a metal’s surface when light of a certain frequency shines on it (how solar calculators work). ...

6 - The Quantum Atomic Model SCH4U – Structure and Properties of

A310G Examination #2

Practice Test

Cathode ray deflection tube

... The electron gun shoots out a beam of electrons across an evacuated tube. It hits a fluorescent screen placed in its path and when it does the screen glows. If there is no voltage between the two plates the beam will go along the middle of the scale. Beams of electrons (cathode rays) move in straigh ...

Periodic Trends - cloudfront.net

... their atomic numbers; properties of the elements occurred at repeated intervals called periods.  This defines the property of periodicity Periodic Trends-properties that show patterns when examined across the periods or vertically down the groups  while there are many periodic trends, we will focu ...

Document

... 7. A ruby laser emits 694.3-nm light. Assume light of this wavelength is due to a transition of an electron in a box from its n = 2 state to its n = 1 state. Find the length of the box. 11. Use the particle-in-a-box model to calculate the first three energy levels of a neutron trapped in a nucleus o ...

1 - PLK Vicwood KT Chong Sixth Form College

Quantum Mechanics I SS 2017 - Institut für Theoretische Physik

... of electromagnetic waves. A black body at temperature T absorbs all wavelengths λ of energy and radiates (emits) at all wavelengths. λ = 2πc/ω with c light velocity and ω angular frequency. A good example of a black body is a furnace. Let’s assume we have a cavity with black walls. After a short per ...

Chapter28ReadingQuiz..

... 1. The photoelectric effect tells us that A. B. C. D. ...

Law of Charges - Haiku Learning

Chap. 13 -- Atomic P..

... collide with the hydrogen atoms and increase the energy of the electrons in the atoms. In this way, the hydrogen electrons may briefly acquire some of the higher energy levels shown in this diagram. Usually, after a brief moment, these electrons will abruptly lose at least some of their extra energy ...

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Photoelectric effect

The photoelectric effect is the observation that many metals emit electrons when light shines upon them. Electrons emitted in this manner can be called photoelectrons. The phenomenon is commonly studied in electronic physics, as well as in fields of chemistry, such as quantum chemistry or electrochemistry.According to classical electromagnetic theory, this effect can be attributed to the transfer of energy from the light to an electron in the metal. From this perspective, an alteration in either the amplitude or wavelength of light would induce changes in the rate of emission of electrons from the metal. Furthermore, according to this theory, a sufficiently dim light would be expected to show a lag time between the initial shining of its light and the subsequent emission of an electron. However, the experimental results did not correlate with either of the two predictions made by this theory.Instead, as it turns out, electrons are only dislodged by the photoelectric effect if light reaches or exceeds a threshold frequency, below which no electrons can be emitted from the metal regardless of the amplitude and temporal length of exposure of light. To make sense of the fact that light can eject electrons even if its intensity is low, Albert Einstein proposed that a beam of light is not a wave propagating through space, but rather a collection of discrete wave packets (photons), each with energy hf. This shed light on Max Planck's previous discovery of the Planck relation (E = hf) linking energy (E) and frequency (f) as arising from quantization of energy. The factor h is known as the Planck constant.In 1887, Heinrich Hertz discovered that electrodes illuminated with ultraviolet light create electric sparks more easily. In 1905 Albert Einstein published a paper that explained experimental data from the photoelectric effect as being the result of light energy being carried in discrete quantized packets. This discovery led to the quantum revolution. In 1914, Robert Millikan's experiment confirmed Einstein's law on photoelectric effect. Einstein was awarded the Nobel Prize in 1921 for ""his discovery of the law of the photoelectric effect"", and Millikan was awarded the Nobel Prize in 1923 for ""his work on the elementary charge of electricity and on the photoelectric effect"".The photoelectric effect requires photons with energies from a few electronvolts to over 1 MeV in elements with a high atomic number. Study of the photoelectric effect led to important steps in understanding the quantum nature of light and electrons and influenced the formation of the concept of wave–particle duality. Other phenomena where light affects the movement of electric charges include the photoconductive effect (also known as photoconductivity or photoresistivity), the photovoltaic effect, and the photoelectrochemical effect.

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Photoelectric effect