Bushong Ch 4

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Name some uses of microwaves:

*cell phone communication *highway speed monitoring *medical diathermy *hot dog preparation

The important properties of the sine wave model of electromagnetic energy:

*frequency (f) and *wavelength (represented by the Greek letter lambda)

List the 4 properties of electromagnetic energy:

*frequency *wavelength *velocity *amplitude

List the 4 properties of photons:

*frequency *wavelength *velocity *amplitude

sunlight contains these 2 types of invisible light:

*infrared *ultraviolet

3 degrees of interaction between light and an absorbing material:

*transparency (transmission) *translucency (attenuation) *opacity (absorption)

The 3 wave parameters needed to describe electromagnetic energy:

*velocity *frequency *wavelength

3 regions of the electromagnetic spectrum most important to radiologic science:

*visible light *x-radiation *radiofrequency

Name 2 mathematical formulas that describe how electromagnetic energy behaves

*wave equation *inverse square law

List 3 examples of electromagnetic energy:

*x-rays *visible light *radiofrequencies

the x-ray energy ranges

10 keV to 50 MeV

the associated wavelength for x-ray energy

10^-10 to 10^-14 m

the range of x-ray photon frequency

10^18 to 10^22 Hz

the speed of light as represented by the SI system of units

3 x 10^8 m/s

the velocity of all electromagnetic radiation

3 x 10^8 m/s

the numeric value for Planck's constant

4.15 x 10^-15

Planck's Quantum Equation

E = hf (where E is the photon energy, "h" is Planck's constant, and "f" is the photon frequency in hertz)

Einstein's Relativity Equation

E = mc^2 (E is the energy measured in joules, "m" is the mass measured in kilograms, and "c" is the velocity of light measured in meters per second)

In the late 19th century, he showed that visible light has both electric and magnetic properties

James Clerk Maxwell

states that energy can be neither created or destroyed

Law of Conservation of Energy

states that matter can be neither created or destroyed

Law of Conservation of Matter

a German physicist whose mathematical and physical theories synthesized our understanding of electromagnetic radiation into a uniform model

Max Planck

he received the Nobel Prize in 1918

Max Planck

the constant of proportionality is know as this:

Planck's constant

covers a considerable portion of the electromagnetic spectrum and has relatively low energy and relatively long wavelength

RF (radio frequency)

How is the energy of a photon and its frequency related?

The energy of a photon is directly proportional to its frequency.

How is the energy of a photon related to its frequency?

The energy of a photon is directly proportional to its frequency.

At what distance from the source can the inverse square law be applied?

The inverse square law can be applied to distances greater than seven times the longest dimension of the source.

principle that states that both wave and particle concepts must be retained, because wave-like properties are exhibited in some experiments and particle-like properties are exhibited in others

Wave-particle duality

One of the substantive statements of Planck's Quantum Theory

X-rays are created with the speed of light (c), and they exist with velocity (c) or they do not exist at all.

visible light behaves like

a wave

one-half the range from crest to valley over which the sine wave varies

amplitude

a quantum of electromagnetic energy that travels through space at the speed of light

an x-ray photon

contains considerably more energy than a visible light photon or an RF photon

an x-ray photon

The Electromagnetic Wave Equation:

c = frequency x wavelength

an uninterrupted (continuous) ordered sequence

continuum

this imaging modality is not a part of the electromagnetic spectrum

diagnostic ultrasound

a field or state of energy that is always present around us and exists over a wide range called an energy continuum

electromagnetic energy

the reduction in intensity that results from scattering and absorption

electromagnetic energy attenuation

this includes the entire range of electromagnetic energy

electromagnetic spectrum

x-rays are identified by:

energy

physicists use this term to describe the interactions among different energies, forces, or masses that can otherwise be described only mathematically

field

RF is identified by:

frequency

the number of wavelengths that pass a point of observation per second

frequency

these come from inside the nucleus of a radioactive atom

gamma rays

consists of photons with wavelengths longer than those of visible light but shorter than those of microwaves

infrared light

How is electromagnetic energy (radiation) intensity related to the square of the distance from the source?

inversely

at a given velocity, wavelength and frequency are:

inversely proportional

for electromagnetic energy, frequency and wavelength are:

inversely proportional

today, these make it possible to produce x-rays of considerably higher energies than gamma ray emissions

linear accelerators

these frequencies vary according to use but are always higher than broadcast RF and lower than infrared

microwave frequencies

very-short-wavelength RF

microwave radiation

an example of converting matter into energy

nuclear fission

the basis for generating electricity

nuclear fission

an example of converting energy into mass

pair production

x-rays behave as though they are

particles

the smallest quantity of any type of electromagnetic energy

photon

How is the energy of a photon related to its wavelength?

photon energy is inversely proportional to photon wavelength

a term that means "a small bundle of energy"

quantum

structures that transmit x-rays are called this:

radiolucent

structures that absorb x-rays are called this:

radiopaque

return or reentry of an x-ray

reflection

the deviation in the course of visible light when they pass from one transparent medium to another

refraction

variations of amplitude over time

sine waves

this term means "simple motion; a sine wave"

sinusoidal

the first ancient people to describe photons

the ancient Greeks

this governs the interaction of electrostatic charges, the magnetic field, and the interaction of magnetic poles

the electric field

unit of energy used to describe x-rays

the electron volt (eV)

this governs the interaction of different masses

the gravitational field

the unit of frequency that is used to describe radio waves

the hertz

describes the relationship between radiation intensity and distance from the radiation source

the inverse square law

Planck's constant is symbolized by

the letter "h"

this extremely small segment of the electromagnetic energy continuum is the only one that is naturally apparent to us

the visible light segment

the only difference between x-rays and gamma rays

their origin

the wavelength differences between a photon of x-radiation and a photon of visible light result in this difference between them

these differences result in differences in the way these photons interact with matter

What is the only way the photons of various portions of the electromagnetic spectrum differ?

they differ only in frequency and wavelength

located in the electromagnetic spectrum between visible light and ionizing radiation

ultraviolet light

The Wave Equation:

v = frequency x wavelength

occupies the smallest segment of the electromagnetic spectrum

visible light

the only portion of the electromagnetic spectrum we can sense directly

visible light

the distance from one crest to another, from one valley to another, or from any point on the sine wave to the next corresponding point

wavelength

visible light is identified by:

wavelength

When do photons interact with matter most easily?

when the matter is approximately the same size as the photon wavelength

these are emitted from the electron cloud of an atom that has been stimulated artificially

x-rays


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