here

... radiation causes those charges to oscillate up and down. In the case of the long wavelength radiation the charge at right oscillates slowly. This is low frequency and low energy motion. The short wavelength causes the charge at right to oscillate more rapidly - high frequency and high energy. These ...

Free Electron Lasers Introduction Undulator Radiation Low

... The essential feature of the high-gain FEL is that a large number of electrons radiate coherently. In that case, the intensity of the radiation field grows quadratically with the number of particles: IN = N 2 I1. ...

RADIATION EMISSION FROM ACCELERATED ATOMS

... • In the photoelectric effect, light incident on a metal eject electrons from it. • Although its explanation constitutes one of the most success of the corpuscular theory of radiation, it is not necessary to quantize the electromagnetic field to explain it. ...

Seminar

... over the Polar Regions where field lines are open to interplanetary space. The levels of galactic cosmic ray particles also vary with the ionization state of the particle. Particles that have not passed through large amounts of interstellar matter are not fully stripped of their electrons. Therefore ...

Introduction to Nuclear Forces

... The meson theory of nuclear forces is constructed in analogy with quantum electrodynamics. It is well known that in quantum electrodynamics the electromagnetic field is considered jointly with the particles (photons) associated with it. The field as if consists of photons which are the quanta of thi ...

Compton scattering

... photon. This process is called inverse Compton to distinguish it from the direct Compton scattering, in which the electron is at rest, and it is the photon to give part of its energy to the electron. We have two regimes, that are called the Thomson and the Klein–Nishina regimes. The difference betwe ...

Short questions from past papers

... Work, Energy and Power 1. Define energy [2005 OL] Energy is defined as the ability to do work 2. Define work. [2007 OL] Work is the product of force × displacement 3. What is the difference between potential energy and kinetic energy? [2007 OL][2010 OL] Potential energy is energy a body has due to ...

GOAL 3: Construct an understanding of electricity and

... _____ 13. If you drop a sheet of paper and a pencil at the same time, the pencil will hit the ground first even though they experience the same acceleration. Why is this true? A) there is more air resistance on the paper than the pencil B) there is more air resistance on the pencil than the paper C) ...

Waves What happens ? What happens if we continue to move hand

... radiation. Keep heat from escaping earth into space. •Keeps it about 35o higher than without… Important for life conditions •Regulates temperature on Earth •Responsible for high temperature on Venus (460 C) – runaway greenhouse effect ...

mössbauer spectroscopy

... In the case of gamma radiation from nuclei, however, resonant absorption does not usually take place because of the relatively large momentum associated with gamma ray photons. When a stationary nucleus of excitation energy E emits radiation in a transition to its ground state, the nucleus recoils s ...

frequency - Wayne State University Physics and Astronomy

... radiation. Keep heat from escaping earth into space. ...

Test 8 Review

... different frequency waves that are out of phase with each other. The more a light beam spreads, the less energy is focused on a given point. Lasers are monochromatic, so the waves stay in phase and they don’t spread. This makes the laser beam narrower and higher energy. Electromagnetic Waves. Electr ...

Discovery

... Primary cosmic rays are charged particles, mostly hydrogen and helium nuclei, which have been accelerated to very high energies in astrophysical sources. These cosmic rays continuously bombard the earth and collide with air nuclei to create cascades of less energetic particles. As they travel throug ...

Electromagnetic Waves from TNT Explosions

... Experimental observations indicate that electromagnetic (EM) radiation is emitted after the detonation of high explosives (HE) charges. The movement of ionized atoms, particles and electrons seems to be the underlying cause. Expansion of the detonation products (DP) drives a strong (~1 kb) shock in ...

Answers - Pearson-Global

... 10 See page 31 for description of a suitable experiment. 11 At A: velocity is zero at start, so air resistance is zero and the unbalanced force is downwards (and is due to gravity or the weight of the parachutist). At B: as the velocity of the parachutist increases so does the size of the upward air ...

Atmospheric Radiation Basics

... ◦ The reflection and emission from the surface at the bottom of the atmosphere. ...

Document

... To prevent this, a quenching gas is added to the noble gas that fills the counter chamber. The G-M counter is made as a tube, up to 10-15cm long and about 3cm in diameter. A window is provided to allow penetration of radiation. The tube is filled with argon or helium with about 5-10% alcohol (Ethyl ...

Full Text:PDF

... From the complex form of Poynting's Theorem for a linear, homogeneous, and isotropic material, the absorbed power Pabs within the given volume V of the lossy material is a function of the electric (E) and magnetic (H) field intensities inside the screen and is given by Pabs ³ (VE 2 ZH '' E 2 ZP ...

Electromagnetic Radiation

... Using the relationship between energy, frequency, and wavelength (i.e., E = hν = hc/λ), you can see that a FM radio station that broadcasts at a frequency of 100 MHz emits radio waves that are 3 m long and have an energy of 4.13 x 10-7 eV. An AM radio station broadcasting at 1000 kHz (i.e., 1 MHz) e ...

Notes/All Physics IB/Introductory Items/vocabulary list ib2

... 22. Change in Gravitational Potential Energy (ΔEp) – product of an object’s mass times the gravitational field strength times the change in height 23. *Principle of Conservation of Energy – The total energy of an isolated system (no external forces) remains constant. (OR – Energy can be neither crea ...

Geometric effects on blackbody radiation

... BBR spectrum. However, Bohren and Huffman [6] have previously shown that the absorption area of a small body is greater than its geometrical area; therefore the fact that the emissivity equals the absorptivity actually leads to the opposite conclusion—that we actually do expect a greater emittance t ...

Year 11 Revision Plan (Triple Science)

... The basic structure of an atom is a small central nucleus composed of protons and neutrons surrounded by electrons. b) The relative masses and relative electric charges of protons, neutrons and electrons. c) In an atom the number of electrons is equal to the number of protons in the nucleus. The ato ...

Ch 33 Electromagnetic Waves I

... Most of UV light from the Sun is absorbed by ozone (臭氧) (O3) molecules in the Earth’s upper atmosphere, in a layer called the stratosphere (同溫層、平流層). This ozone shield ( 護罩 ) converts lethal ( 致命の ) highenergy UV radiation to IR radiation, which in turn warms the stratosphere. X-rays: 10-8m<λ<1 ...

25.7 The Photon Model of Electromagnetic Waves

... that each view is appropriate in certain circumstances. For example, we speak of radio waves but of x rays. The “ray” terminology tells us that x rays are generally better described as photons than as waves. Figure 25.34 shows the electromagnetic spectrum with photon energy (in eV) and wavelength (i ...

2006 - The Physics Teacher

... Describe what will happen if the aluminium foil is placed parallel to the magnetic field. Nothing will happen because they have to be at an angle to each other. Calculate the force on the aluminium foil if its length is 10 cm and a current of 1.5 A flows through it when it is placed in a magnetic fi ...

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Effects of nuclear explosions

The energy released from a nuclear weapon detonated in the troposphere can be divided into four basic categories: Blast—40–50% of total energy Thermal radiation—30–50% of total energy Ionizing radiation—5% of total energy (more in a neutron bomb) Residual radiation—5–10% of total energy with the mass of the explosionHowever, depending on the design of the weapon and the environment in which it is detonated the energy distributed to these categories can be increased or decreased. The blast effect is created by the coupling of immense amounts of energy, spanning the electromagnetic spectrum, with the surroundings. Locations such as submarine, surface, air burst, or exo-atmospheric determine how much energy is produced as blast and how much as radiation. In general, denser media around the bomb, like water, absorb more energy, and create more powerful shockwaves while at the same time limiting the area of its effect.When an air burst occurs lethal blast and thermal effects proportionally scale much more rapidly than lethal radiation effects, as higher and higher yield nuclear weapons are used.The physical-damage mechanisms of a nuclear weapon (blast and thermal radiation) are identical to those of conventional explosives. However, the energy produced by a nuclear explosive is millions of times more powerful per gram and the temperatures reached are briefly in the tens of millions of degrees.Energy from a nuclear explosive is initially released in several forms of penetrating radiation. When there is a surrounding material such as air, rock, or water, this radiation interacts with and rapidly heats it to an equilibrium temperature (i.e. so that the matter is at the same temperature as the atomic bomb's matter). This causes vaporization of surrounding material resulting in its rapid expansion. Kinetic energy created by this expansion contributes to the formation of a shockwave. When a nuclear detonation occurs in air near sea level, much of the released energy interacts with the atmosphere and creates a shockwave which expands spherically from the hypocenter. Intense thermal radiation at the hypocenter forms a nuclear fireball and if the burst is low enough, it is often associated mushroom cloud. In a burst at high altitudes, where the air density is low, more energy is released as ionizing gamma radiation and x-rays than an atmosphere-displacing shockwave.In 1942 there was some initial speculation among the scientists developing the first nuclear weapons that there might be a possibility of igniting the Earth's atmosphere with a large enough nuclear explosion. This would concern a nuclear reaction of two nitrogen atoms forming a carbon and an oxygen atom, with release of energy. This energy would heat up the remaining nitrogen enough to keep the reaction going until all nitrogen atoms were consumed. Hans Bethe was assigned the task of studying whether there was a possibility in the very early days, and concluded there was no possibility due to inverse Compton effect cooling of the fireball. Richard Hamming, a mathematician, was asked to make a similar calculation just before Trinity, with the same result. Nevertheless, the notion has persisted as a rumor for many years, and was the source of black humor at the Trinity test.

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Effects of nuclear explosions