Radio waves Radio waves are emitted and received by
antennas, which consist of conductors such as metal rod
resonators. In artificial generation of radio waves, an electronic device called a
transmitter generates an alternating
electric current which is applied to an antenna. The oscillating electrons in the antenna generate oscillating
electric and
magnetic fields that radiate away from the antenna as radio waves. In reception of radio waves, the oscillating electric and magnetic fields of a radio wave couple to the electrons in an antenna, pushing them back and forth, creating oscillating currents which are applied to a
radio receiver. Earth's atmosphere is mainly transparent to radio waves, except for layers of charged particles in the
ionosphere which can reflect certain frequencies. Radio waves are extremely widely used to transmit information across distances in
radio communication systems such as
radio broadcasting,
television,
two way radios,
mobile phones,
communication satellites, and
wireless networking. In a radio communication system, a radio frequency current is
modulated with an information-bearing
signal in a transmitter by varying either the amplitude, frequency or phase, and applied to an antenna. The radio waves carry the information across space to a receiver, where they are received by an antenna and the information extracted by
demodulation in the receiver. Radio waves are also used for navigation in systems like
Global Positioning System (GPS) and
navigational beacons, and locating distant objects in
radiolocation and
radar. They are also used for
remote control, and for industrial heating. The use of the
radio spectrum is strictly regulated by governments, coordinated by the
International Telecommunication Union (ITU) which
allocates frequencies to different users for different uses.
Microwaves radio transmissions within the
troposphere but opaque to space due to the
ionosphere.
Microwaves are radio waves of short
wavelength, from about 10 centimeters to one millimeter, in the
SHF and
EHF frequency bands. Microwave energy is produced with
klystron and
magnetron tubes, and with
solid state devices such as
Gunn and
IMPATT diodes. Although they are emitted and absorbed by short antennas, they are also absorbed by
polar molecules, coupling to vibrational and rotational modes, resulting in bulk heating. Unlike higher frequency waves such as
infrared and
visible light which are absorbed mainly at surfaces, microwaves can penetrate into materials and deposit their energy below the surface. This effect is used to heat food in
microwave ovens, and for industrial heating and medical
diathermy. Microwaves are the main wavelengths used in
radar, and are used for
satellite communication, and
wireless networking technologies such as
Wi-Fi. The copper cables (
transmission lines) which are used to carry lower-frequency radio waves to antennas have excessive power losses at microwave frequencies, and metal pipes called
waveguides are used to carry them. Although at the low end of the band the atmosphere is mainly transparent, at the upper end of the band absorption of microwaves by atmospheric gases limits practical propagation distances to a few kilometers.
Terahertz radiation Terahertz radiation, also known as sub-millimeter radiation, THF, T-rays, or T-light, is a region of the spectrum from about 100 GHz to 30 terahertz (THz) between microwaves and far infrared which can be regarded as belonging to either band. Until recently, the range was rarely studied and few sources existed for microwave energy in the so-called
terahertz gap, but applications such as imaging and communications are now appearing. Scientists are also looking to apply terahertz technology in the armed forces, where high-frequency waves might be directed at enemy troops to incapacitate their electronic equipment. Terahertz radiation is strongly absorbed by atmospheric gases, making this frequency range useless for long-distance communication.
Infrared radiation The
infrared part of the electromagnetic spectrum covers the range from roughly 300 GHz to 400 THz (1 mm – 750 nm). It can be divided into three parts: By definition, visible light is the part of the EM spectrum the
human eye is the most sensitive to. Visible light (and near-infrared light) is typically absorbed and emitted by electrons in molecules and atoms that move from one energy level to another. This action allows the chemical mechanisms that underlie human vision and plant photosynthesis. The light that excites the human
visual system is a very small portion of the electromagnetic spectrum. A
rainbow shows the optical (visible) part of the electromagnetic spectrum; infrared (if it could be seen) would be located just beyond the red side of the rainbow whilst
ultraviolet would appear just beyond the opposite violet end. Electromagnetic radiation with a
wavelength between 380
nm and 760 nm (400–790 terahertz) is detected by the human eye and perceived as visible light. Other wavelengths, especially near infrared (longer than 760 nm) and ultraviolet (shorter than 380 nm) are also sometimes referred to as light, especially when the visibility to humans is not relevant. White light is a combination of lights of different wavelengths in the visible spectrum. Passing white light through a prism splits it up into the several colours of light observed in the visible spectrum between 400 nm and 780 nm. If radiation having a frequency in the visible region of the EM spectrum reflects off an object, say, a bowl of fruit, and then strikes the eyes, this results in
visual perception of the scene. The brain's visual system processes the multitude of reflected frequencies into different shades and hues, and through this insufficiently understood psychophysical phenomenon, most people perceive a bowl of fruit. At most wavelengths, however, the information carried by electromagnetic radiation is not directly detected by human senses. Natural sources produce EM radiation across the spectrum, and technology can also manipulate a broad range of wavelengths.
Optical fiber transmits light that, although not necessarily in the visible part of the spectrum (it is usually infrared), can carry information. The modulation is similar to that used with radio waves.
Ultraviolet radiation Next in frequency comes
ultraviolet (UV). In frequency (and thus energy), UV rays sit between the violet end of the
visible spectrum and the X-ray range. The UV wavelength spectrum ranges from 399 nm to 10 nm and is divided into 3 sections: UVA, UVB, and UVC. UV is the lowest energy range energetic enough to
ionize atoms, separating
electrons from them, and thus causing
chemical reactions. UV, X-rays, and gamma rays are thus collectively called
ionizing radiation; exposure to them can damage living tissue. UV can also cause substances to glow with visible light; this is called
fluorescence. UV fluorescence is used by forensics to detect any evidence like blood and urine, that is produced by a crime scene. Also UV fluorescence is used to detect counterfeit money and IDs, as they are laced with material that can glow under UV. At the middle range of UV, UV rays cannot ionize but can break chemical bonds, making molecules unusually reactive.
Sunburn, for example, is caused by the disruptive effects of middle range UV radiation on
skin cells, which is the main cause of
skin cancer. UV rays in the middle and shorter range can irreparably damage the complex
DNA molecules in the cells producing
thymine dimers making it a very potent
mutagen. Due to skin cancer caused by UV, the sunscreen industry was invented to combat UV damage. Short range wavelengths are called UVC. UVB and UVC lights such as germicidal lamps utilize the destructive nature of these wavelengths to sterilize and have other scientific applications. The Sun emits UV radiation (about 10% of its total power), including extremely short wavelength UV that could potentially destroy most life on land (ocean water would provide some protection for life there). However, most of the Sun's damaging UV wavelengths are absorbed by the atmosphere before they reach the surface. The higher energy (shortest wavelength) ranges of UV (called "vacuum UV") are absorbed by nitrogen and, at longer wavelengths, by simple diatomic
oxygen in the air. Most of the UV in the mid-range of energy is blocked by the ozone layer, which absorbs strongly in the important 200–315 nm range, the lower energy part of which is too long for ordinary
dioxygen in air to absorb. This leaves less than 3% of sunlight at sea level in UV, with all of this remainder at the lower energies. The remainder is UV-A, along with some UV-B. The very lowest energy range of UV between 315 nm and visible light (called UV-A) is not blocked well by the atmosphere, but does not cause sunburn and does less biological damage. However, it is not harmless and does create oxygen radicals, mutations and skin damage.
X-rays After UV come
X-rays, which, like the upper ranges of UV are also ionizing. However, due to their higher energies, X-rays can also interact with matter by means of the
Compton effect. Hard X-rays have shorter wavelengths than soft X-rays and as they can pass through many substances with little absorption, they can be used to 'see through' objects with 'thicknesses' less than that equivalent to a few meters of water. One notable use is diagnostic X-ray imaging in medicine (a process known as
radiography). X-rays are useful as probes in high-energy physics. In astronomy, the accretion disks around
neutron stars and
black holes emit X-rays, enabling studies of these phenomena. X-rays are also emitted by
stellar corona and are strongly emitted by some types of
nebulae. However,
X-ray telescopes must be placed outside the Earth's atmosphere to see astronomical X-rays, since the great depth of the
atmosphere of Earth is opaque to X-rays (with
areal density of 1000 g/cm2), equivalent to 10 meters thickness of water. This is an amount sufficient to block almost all astronomical X-rays (and also astronomical gamma rays—see below).
Gamma rays After hard X-rays come
gamma rays, which were discovered by
Paul Ulrich Villard in 1900. These are the most energetic
photons, having no defined lower limit to their wavelength. In
astronomy they are valuable for studying high-energy objects or regions, however as with X-rays this can only be done with telescopes outside the Earth's atmosphere. Gamma rays are used experimentally by physicists for their penetrating ability and are produced by a number of
radioisotopes. They are used for
irradiation of foods and seeds for sterilization, and in medicine they are occasionally used in
radiation cancer therapy. More commonly, gamma rays are used for diagnostic imaging in
nuclear medicine, an example being
PET scans. The wavelength of gamma rays can be measured with high accuracy through the effects of
Compton scattering. == See also ==