return overlib('A relatively flat sheet of gas and dust surrounding a newborn star, a black hole, or any massive object growing in size by attracting material. ',BELOW)
}
function accretion_dtt() {
return overlib('Accumulation of dust and gas onto larger bodies such as stars, planets and moons. ',BELOW)
}
function AGN_dtt() {
return overlib('A class of galaxies which spew massive amounts of energy from their centers, far more than ordinary galaxies. Many astronomers believe supermassive black holes may lie at the center of these galaxies and power their explosive energy output. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function angstrom_dtt() {
return overlib('A unit of length equal to 0.00000001 centimeters. This may also be written as 1 x 10<SUP>-8</SUP> cm (see scientific notation). ',BELOW)
}
function angular_momentum_dtt() {
return overlib('A quantity obtained by multiplying the mass of an orbiting body by its velocity and the radius of its orbit. According to the conservation laws of physics, the angular momentum of any orbiting body must remain constant at all points in the orbit, i.e., it cannot be created or destroyed. If the orbit is elliptical the radius will vary. Since the mass is constant, the velocity changes. Thus planets in elliptical orbits travel faster at periastron and more slowly at apastron. A spinning body also possesses spin angular momentum. ',BELOW)
}
function apastron_dtt() {
return overlib('The point of greatest separation between two stars which are in orbit around each other. See binary stars. Opposite of periastron. ',BELOW)
}
function aphelion_dtt() {
return overlib('The point in its orbit where a planet is farthest from the Sun. Opposite of perihelion. ',BELOW)
}
function apoapsis_dtt() {
return overlib('The point in an orbit when the two objects are farthest apart. Special names are given to this orbital point for commonly used systems: see apastron, aphelion, and apogee. ',BELOW)
}
function apogee_dtt() {
return overlib('The point in its orbit where an Earth satellite is farthest from the Earth. Opposite of perigee. ',BELOW)
}
function Ariel_5_dtt() {
return overlib('A UK X-ray mission, also known as UK-5 <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function ASCA_dtt() {
return overlib('The Japanese Asuka spacecraft (formerly Astro-D), an X-ray mission <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function ASM_dtt() {
return overlib('All Sky Monitor. An instrument designed to observe large areas of the sky for interesting astronomical phenomena. An ASM measures the intensity of many sources across the sky and looks for new sources. Many high-energy satellites have carried ASM detectors, including the ASM on Vela 5B, Ariel V, and the Rossi X-ray Timing Explorer. ',BELOW)
}
function astronomy_dtt() {
return overlib('The scientific study of matter in outer space, especially the positions, dimensions, distribution, motion, composition, energy, and evolution of celestial bodies and phenomena. ',BELOW)
}
function astrophysics_dtt() {
return overlib('The part of astronomy that deals principally with the physics of the universe, including luminosity, density, temperature, and the chemical composition of stars, galaxies, and the interstellar medium. ',BELOW)
}
function Astro_E_dtt() {
return overlib('A X-ray/gamma-ray mission built jointly by the United States and Japan. Astro E was destroyed in February 2000, when a Japanese M-5 rocket failed to lift the instrument into orbit. A replacement mission, Astro-E2, is planned for 2005. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function AU_dtt() {
return overlib('149,597,870 km; the average distance from the Earth to the Sun. ',BELOW)
}
function atmosphere_dtt() {
return overlib('The gas that surrounds a planet or star. The Earth’s atmosphere is made up of mostly nitrogen, while the Sun’s atmosphere consists of mostly hydrogen. ',BELOW)
}
function AXAF_dtt() {
return overlib('The Advanced X-ray Astrophysics Facility. AXAF was renamed Chandra X-ray Observatory, CXO, and launched in July 1999. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function Balmer_lines_dtt() {
return overlib('Emission or absorption lines in the spectrum of hydrogen that arise from transitions between the second (or first excited) state and higher energy states of the hydrogen atom. They were discovered by Swiss physicist J. J. Balmer. ',BELOW)
}
function baryon_dtt() {
return overlib('Any of the subatomic particles which interact via the strong nuclear force. Most commonly, these are protons and neutrons. Their presence in the universe is determined through their gravitational and electromagnetic interactions. ',BELOW)
}
function BATSE_dtt() {
return overlib('BATSE (Burst and Transient Source Experiment) was an instrument aboard the Compton Gamma Ray Observatory that detected and located gamma-ray bursts in the sky. ',BELOW)
}
function BBXRT_dtt() {
return overlib('The Broad Band X-Ray Telescope, which was flown on the Astro-1 space shuttle flight (Dec. 1990) <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function big_bang_dtt() {
return overlib('A theory of cosmology in which the expansion of the universe is presumed to have begun with a primeval explosion (referred to as the "Big Bang"). ',BELOW)
}
function binary_stars_dtt() {
return overlib('Binary stars are two stars that orbit around a common center of mass. An X-ray binary is a special case where one of the stars is a collapsed object such as a white dwarf, neutron star, or black hole, and the separation between the stars is small enough so that matter is transferred from the normal star to the compact star star, producing X-rays in the process. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function black_dwarf_dtt() {
return overlib('A non-radiating ball of gas resulting from a white dwarf that has radiated all its energy. ',BELOW)
}
function black_hole_laws_dtt() {
return overlib('1 First law of black hole dynamics: For interactions between black holes and normal matter, the conservation laws of mass-energy, electric charge, linear momentum, and angular momentum, hold. This is analogous to the first law of thermodynamics. 2 Second law of black hole dynamics: With black-hole interactions, or interactions between black holes and normal matter, the sum of the surface areas of all black holes involved can never decrease. This is analogous to the second law of thermodynamics, with the surface areas of the black holes being a measure of the entropy of the system. ',BELOW)
}
function black_hole_dtt() {
return overlib('An object whose gravity is so strong that not even light can escape from it<br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function blackbody_radiation_dtt() {
return overlib('Blackbody radiation is produced by an object which is a perfect absorber of heat. Perfect absorbers must also be perfect radiators. For a blackbody at a temperature T, the intensity of radiation emitted I at a particular energy E is given by Plank’s law: I(E,T) = 2 E3[h2c2(eE/kT - 1)]-1 where h is Planck’s constant, k is Boltzmann’s constant, and c is the the speed of light. ',BELOW)
}
function blackbody_temperature_dtt() {
return overlib('The temperature of an object if it is re-radiating all the thermal energy that has been added to it; if an object is not a blackbody radiator, it will not re-radiate all the excess heat and the leftover will go toward increasing its temperature. ',BELOW)
}
function blueshift_dtt() {
return overlib('An apparent shift toward shorter wavelengths of spectral lines in the radiation emitted by an object caused by motion between the object and the observer which decreases the distance between them. See also Doppler effect. ',BELOW)
}
function bolometric_dtt() {
return overlib('The total energy radiated by an object at all wavelengths, usually given in joules per second (identical to watts). ',BELOW)
}
function Boltzmann_constant_dtt() {
return overlib('A constant which describes the relationship between temperature and kinetic energy for molecules in an ideal gas. It is equal to 1.380622 x 10<sup>-23</sup> J/K (see scientific notation). ',BELOW)
}
function brahe_dtt() {
return overlib('(a.k.a Tyge Ottesen) Danish astronomer whose accurate astronomical observations of Mars in the last quarter of the 16th century formed the basis for Johannes Kepler’s laws of planetary motion. Brahe lost his nose in a dual in 1566 with Manderup Parsberg (a fellow student and nobleman) at Rostock over who was the better mathematician. He died in 1601, not of a burst bladder as legend suggests, but from high levels of mercury in his blood (which he may have taken as medication after falling ill from the infamous meal). <br><font color=990000>A link to a picture of Tycho Brahe is available in the dictionary.</font>',BELOW)
}
function bremsstrahlung_dtt() {
return overlib('"braking radiation", the main way very fast charged particles lose energy when traveling through matter. Radiation is emitted when charged particles are accelerated. In this case, the acceleration is caused by the electromagnetic fields of the atomic nuclei of the medium. ',BELOW)
}
function calibration_dtt() {
return overlib('A process for translating the signals produced by a measuring instrument (such as a telescope) into something that is scientifically useful. This procedure removes most of the errors caused by environmental and instrumental instabilities. ',BELOW)
}
function cataclysmic_variable_dtt() {
return overlib('Binary star systems with one white dwarf star and one normal star, in close orbit about each other. Material from the normal star falls onto the white dwarf, creating a burst of X-rays. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function Cepheid_dtt() {
return overlib('A type of variable star which exhibits a regular pattern of changing brightness as a function of time. The period of the pulsation pattern is directly related to the star’s intrinsic brightness. Thus, Cepheid variables are a powerful tool for determining distances in modern astronomy. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function CGRO_dtt() {
return overlib('The Compton Gamma Ray Observatory <br><font color=990000>More links available in the dictionary.</font> ',BELOW)
}
function Chandrasekhar_limit_dtt() {
return overlib('A limit which mandates that no white dwarf (a collapsed, degenerate star) can be more massive than about 1.4 solar masses. Any degenerate object more massive must inevitably collapse into a neutron star. ',BELOW)
}
function Chandrasekhar_dtt() {
return overlib('Indian astrophysicist reknowned for creating theoretical models of white dwarf stars, among other achievements. His equations explained the underlying physics behind the creation of white dwarfs, neutron stars and other compact objects. ',BELOW)
}
function Chandra_dtt() {
return overlib('One of NASA’s Great Observatories in Earth orbit, launched in July 1999, and named after S. Chandrasekhar. It was previously named the Advanced X-ray Astrophysics Facility (AXAF). ',BELOW)
}
function cluster_of_galaxies_dtt() {
return overlib('A system of galaxies containing from a few to a few thousand member galaxies which are all gravitationally bound to each other. ',BELOW)
}
function collecting_area_dtt() {
return overlib('The amount of area a telescope has that is capable of collecting electromagnetic radiation. Collecting area is important for a telescope’s sensitivity: the more radiation it can collect (that is, the larger its collecting area), the more likely it is to detect dim objects. ',BELOW)
}
function Compton_effect_dtt() {
return overlib('An effect that demonstrates that photons (the quantum of electromagnetic radiation) have momentum. A photon fired at a stationary particle, such as an electron, will impart momentum to the electron and, since its energy has been decreased, will experience a corresponding decrease in frequency. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function OAO_3_dtt() {
return overlib('NASA ultraviolet/X-ray mission, also known as OAO-3 <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function copernicus_dtt() {
return overlib('Polish astronomer who advanced the theory that the Earth and other planets revolve around the Sun (the "heliocentric" theory). This was highly controversial at the time, since the prevailing Ptolemaic model held that the Earth was the center of the universe, and all objects, including the sun, circle it. The Ptolemaic model had been widely accepted in Europe for 1000 years when Copernicus proposed his model. (It should be noted, however, that the heliocentric idea was first put forth by Aristarcus of Samos in the 3rd century B.C., a fact known to Copernicus but long ignored by others prior to him.). <br><font color=990000>A link to a picture of Nicholas Copernicus is available in the dictionary.</font>',BELOW)
}
function corona_dtt() {
return overlib('The uppermost level of a star’s atmosphere. In the sun, the corona is characterized by low densities and high temperatures (> 1,000,000 degrees K). ',BELOW)
}
function COS_B_dtt() {
return overlib('A satellite launched in August 1975 to study extraterrestrial sources of gamma-ray emission. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function cosmic_background_dtt() {
return overlib('The background of radiation mostly in the frequency range 3 x 10<sup>8</sup> to 3 x 10<sup>11</sup> Hz (see scientific notation) discovered in space in 1965. It is believed to be the cosmologically redshifted radiation released by the Big Bang itself. ',BELOW)
}
function cosmic_microwave_dtt() {
return overlib('The background of radiation mostly in the frequency range 3 x 10<sup>8</sup> to 3 x 10<sup>11</sup> Hz (see scientific notation) discovered in space in 1965. It is believed to be the cosmologically redshifted radiation released by the Big Bang itself. ',BELOW)
}
function cosmic_rays_dtt() {
return overlib('Atomic nuclei (mostly protons) and electrons that are observed to strike the Earth’s atmosphere with exceedingly high energies. ',BELOW)
}
function cosmological_constant_dtt() {
return overlib('A constant term (labeled Lambda) which Einstein added to his general theory of relativity in the mistaken belief that the Universe was neither expanding nor contracting. The cosmological constant was found to be unnecessary once observations indicated the Universe was expanding. Had Einstein believed what his equations were telling him, he could have claimed the expansion of the Universe as perhaps the greatest and most convincing prediction of general relativity; he called this the "greatest blunder of my life". ',BELOW)
}
function cosmological_distance_dtt() {
return overlib('A distance far beyond the boundaries of our Galaxy. When viewing objects at cosmological distances, the curved nature of spacetime could become apparent. Possible cosmological effects include time dilation and redshift . ',BELOW)
}
function cosmological_redshift_dtt() {
return overlib('An effect where light emitted from a distant source appears redshifted because of the expansion of spacetime itself. Compare Doppler effect . ',BELOW)
}
function cosmology_dtt() {
return overlib('The astrophysical study of the history, structure, and dynamics of the universe. ',BELOW)
}
function CXO_dtt() {
return overlib('The Chandra X-ray Observatory. CXO was launched by the Space Shuttle in July 1999, and named for S. Chandrasekhar. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function dark_matter_dtt() {
return overlib('Name given to the amount of mass whose existence is deduced from the analysis of galaxy rotation curves but which until now, has escaped all detections. There are many theories on what dark matter could be. Not one, at the moment is convincing enough and the question is still a mystery.',BELOW)
}
function de_Broglie_wavelength_dtt() {
return overlib('The quantum mechanical "wavelength" associated with a particle, named after the scientist who discovered it. In quantum mechanics, all particles also have wave characteristics, where the wavelength of a particle is inversely proportional to its momentum and the constant of proportionality is the Planck constant. ',BELOW)
}
function declination_dtt() {
return overlib('A coordinate which, along with Right Ascension, may be used to locate any position in the sky. Declination is analogous to latitude for locating positions on the Earth, and ranges from +90 degrees to -90 degrees. ',BELOW)
}
function deconvolution_dtt() {
return overlib('An image processing technique that removes features in an image that are caused by the telescope itself rather than from actual light coming from the sky. For example, the optical analog would be to remove the spikes and halos which often appear on images of bright stars because of light scattered by the telescope’s internal supports. ',BELOW)
}
function density_dtt() {
return overlib('The ratio between the mass of an object and its volume. In the metric system, density is measured in grams per cubic centimeter (or kilograms per liter); the density of water is 1.0 gm/cm3; iron is 7.9gm/cm3; lead is 11.3.gm/cm3. ',BELOW)
}
function dewar_dtt() {
return overlib('A container (akin to a thermos bottle) that keeps cold material cold. In astronomy, these are often used for liquid nitrogen (at 77K), but can also be used for solid neon (17K) or liquid helium (1.3K). Some astronomical detectors work better at cold temperatures.',BELOW)
}
function disk_dtt() {
return overlib('<b>A.</b> A flattened, circular region of gas, dust, and/or stars. It may refer to material surrounding a newly-formed star; material accreting onto a black hole or neutron star; or the large region of a spiral galaxy containing the spiral arms. </p><p><b>B.</b> The apparent circular shape of the Sun, a planet, or the moon when seen in the sky or through a telescope. ',BELOW)
}
function Doppler_effect_dtt() {
return overlib('The apparent change in wavelength of sound or light caused by the motion of the source, observer or both. Waves emitted by a moving object as received by an observer will be blueshifted (compressed) if approaching, redshifted (elongated) if receding. It occurs both in sound and light. How much the frequency changes depends on how fast the object is moving toward or away from the receiver. Compare cosmological redshift. ',BELOW)
}
function dust_tail_dtt() {
return overlib('A stream of dust particles emitted from the nucleus of a comet. It is the most visible part of a comet. ',BELOW)
}
function dust_dtt() {
return overlib('<B>Not</B> the dust one finds around the house (which is typically fine bits of fabric, dirt, and dead skin cells). Rather, irregularly shaped grains of carbon and/or silicates measuring a fraction of a micron across which are found between the stars. Dust is most evident by its absorption, causing large dark patches in regions of our Milky Way Galaxy and dark bands across other galaxies. ',BELOW)
}
function eccentricity_dtt() {
return overlib('A value that defines the shape of an ellipse or planetary orbit. The eccentricity of an ellipse (planetary orbit) is the ratio of the distance between the foci and the major axis. Equivalently the eccentricity is (ra-rp)/(ra+rp) where ra is the apoapsis distance and rp is the periapsis distance. ',BELOW)
}
function eccentric_dtt() {
return overlib('Non-circular; elliptical (applied to an orbit). ',BELOW)
}
function eclipse_dtt() {
return overlib('The passage of one celestial body in front of another, cutting off the light from the second body (e.g. an eclipse of the sun by the moon, or one star in a binary system eclipsing the other). It may also be the passage of all or part of one body through the shadow of another (e.g. a lunar eclipse in which the moon passes through the Earth’s shadow). ',BELOW)
}
function ecliptic_dtt() {
return overlib('The plane of Earth’s orbit about the Sun. ',BELOW)
}
function Eddington_limit_dtt() {
return overlib('The theoretical limit at which the photon pressure would exceed the gravitational attraction of a light-emitting body. That is, a body emitting radiation at greater than the Eddington limit would break up from its own photon pressure. ',BELOW)
}
function Einstein_observatory_dtt() {
return overlib('The first fully imaging x-ray telescope in space, launched by NASA in 1978. Originally named "HEAO-2" (High Energy Astrophysics Observatory 2), it was renamed for Albert Einstein upon launch. Also see HEAO. ',BELOW)
}
function einstein_dtt() {
return overlib('German-American physicist; developed the Special and General Theories of Relativity which along with Quantum Mechanics is the foundation of modern physics. <br><font color=990000>A link to a picture of Albert Einstein is available in the dictionary.</font>',BELOW)
}
function ejecta_dtt() {
return overlib('Material that is ejected. Used mostly to describe the content of a massive star that is propelled outward in a supernova explosion. Also used to describe the material that is blown radially outward in a meteor impact on the surface of a planet or moon.',BELOW)
}
function em_spectrum_dtt() {
return overlib('The full range of frequencies, from radio waves to gamma rays, that characterizes light. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function em_waves_dtt() {
return overlib('Another term for light. Light waves are fluctuations of electric and magnetic fields in space. ',BELOW)
}
function electron_volt_dtt() {
return overlib('The change of potential energy experienced by an electron moving from a place where the potential has a value of V to a place where it has a value of (V+1 volt). This is a convenient energy unit when dealing with the motions of electrons and ions in electric fields; the unit is also the one used to describe the energy of X-rays and gamma rays. A keV (or kiloelectron volt) is equal to 1000 electron volts. An MeV is equal to one million electron volts. A GeV is equal to one billion (10<sup>9</sup>) electron volts. A TeV is equal to a million million (10<sup>12</sup>) electron volts. ',BELOW)
}
function electron_dtt() {
return overlib('A negatively charged particle commonly found in the outer layers of atoms. The electron has only 0.0005 the mass of the proton. ',BELOW)
}
function elements_dtt() {
return overlib('The fundamental kinds of atoms that make up the building blocks of matter, which are each shown on the periodic table of the elements. The most abundant elements in the universe are hydrogen and helium. These two elements make up about 80and 20 % of all the matter in the universe respectively. Despite comprising only a very small fraction the universe, the remaining heavy elements can greatly influence astronomical phenomena. About 2 % of the Milky Way’s disk is comprised of heavy elements. ',BELOW)
}
function ellipse_dtt() {
return overlib('Oval. That the orbits of the planets are ellipses, not circles, was first discovered by Johannes Kepler based on the careful observations by Tycho Brahe. ',BELOW)
}
function erg_sec_dtt() {
return overlib('A form of the metric unit for power. It is equal to 10<sup>-10</sup> kilowatts (see scientific notation). ',BELOW)
}
function event_horizon_dtt() {
return overlib('The distance from a black hole within which nothing can escape. In addition, nothing can prevent a particle from hitting the singularity in a very short amount of proper time once it has entered the horizon. In this sense, the event horizon is a "point of no return". See Schwarzschild radius. ',BELOW)
}
function evolved_star_dtt() {
return overlib('A star near the end of its lifetime when most of its fuel has been used up. This period of the star’s life is characterized by loss of mass from its surface in the form of a stellar wind. ',BELOW)
}
function EXOSAT_dtt() {
return overlib('European Space Agency’s X-ray Observatory <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function extragalactic_dtt() {
return overlib('Outside of, or beyond, our own galaxy. ',BELOW)
}
function FFT_dtt() {
return overlib('A Fourier Transform is the mathematical operation that takes measurements made with a radio interferometer and transforms them into an image of the radio sky. The Fast Fourier Transform is technique used by computer programs that allows the Fourier Transform to be computed very quickly. ',BELOW)
}
function fermi_acceleration_dtt() {
return overlib('In order to explain the origins of cosmic rays, Enrico Fermi (1949) introduced a mechanism of particle acceleration, whereby charged particles bounce off moving interstellar magnetic fields and either gain or lose energy, depending on whether the "magnetic mirror" is approaching or receding. In a typical environment, he argued, the probability of a head-on collision is greater than a head-tail collision, so particles would be accelerated on average. This random process is now called 2nd order Fermi acceleration, because the mean energy gain per "bounce" is dependent on the "mirror" velocity squared. ',BELOW)
}
function flux_dtt() {
return overlib('A measure of the amount of energy given off by an astronomical object over a fixed amount of time and area. Because the energy is measured per time and area, flux measurements make it easy for astronomers to compare the relative energy output of objects with very different sizes or ages. ',BELOW)
}
function frequency_dtt() {
return overlib('A property of a wave that describes how many wave patterns or cycles pass by in a period of time. Frequency is often measured in Hertz (Hz), where a wave with a frequency of 1 Hz will pass by at 1 cycle per second. ',BELOW)
}
function FTOOLS_dtt() {
return overlib('A suite of software tools developed at NASA’s Goddard Space Flight Center for analyzing high-energy astronomy data. ',BELOW)
}
function FTP_dtt() {
return overlib('File Transfer Protocol -- A widely available method for transferring files over the Internet. ',BELOW)
}
function nuclear_fusion_dtt() {
return overlib('A nuclear process whereby several small nuclei are combined to make a larger one whose mass is slightly smaller than the sum of the small ones. The difference in mass is converted to energy by Einstein’s famous equivalence "Energy = Mass times the Speed of Light squared". This is the source of the Sun’s energy. ',BELOW)
}
function fusion_dtt() {
return overlib('The process in which atomic nuclei collide so fast that they stick together and emit a large amount of energy. In the center of most stars, hydrogen fuses into helium. The energy emitted by fusion supports the star’s enormous mass from collapsing in on itself, and causes the star to glow. ',BELOW)
}
function galactic_halo_dtt() {
return overlib('A spherical region surrounding the center of a galaxy. This region may extend beyond the luminous boundaries of the galaxy and contain a significant fraction of the galaxy’s mass. Compared to cosmological distances, objects in the halo of our galaxy would be very nearby. ',BELOW)
}
function Seyfert_galaxy_dtt() {
return overlib('A spiral galaxy whose nucleus shows bright emission lines; one of a class of galaxies first described by C. Seyfert. ',BELOW)
}
function galaxy_dtt() {
return overlib('A component of our universe made up of gas and a large number (usually more than a million) of stars held together by gravity. When capitalized, Galaxy refers to our own Milky Way galaxy. ',BELOW)
}
function Galileo_dtt() {
return overlib('An Italian scientist, Galileo was renowned for his epoch making contribution to physics, astronomy, and scientific philosophy. He is regarded as the chief founder of modern science. He developed the telescope, with which he found craters on the Moon and discovered the largest moons of Jupiter. Galileo was condemned by the Catholic Church for his view of the cosmos based on the theory of Copernicus. Show me a picture of Galileo ! ',BELOW)
}
function GRB_dtt() {
return overlib('Plural is GRBs. A burst of gamma rays from space lasting from a fraction of a second to many minutes. There is no clear scientific consensus as to their cause. Recently, their distances were determined to be large, placing the origins of the bursts in other galaxies.<br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function gamma_ray_dtt() {
return overlib('The highest energy, shortest wavelength electromagnetic radiations. Usually, they are thought of as any photons having energies greater than about 100 keV. (It's "gamma-ray" when used as an adjective and "gamma ray" when used as a noun.) ',BELOW)
}
function globular_cluster_dtt() {
return overlib('A spherically symmetric collection of stars which shared a common origin. The cluster may contain up to millions of stars spanning up to 50 parsecs. ',BELOW)
}
function gravitational_collapse_dtt() {
return overlib('When a massive body collapses under its own weight. (For example, interstellar clouds collapse to become stars until the onset of nuclear fusion stops the collapse.) ',BELOW)
}
function gravitational_constant_dtt() {
return overlib('The constant of proportionality in Newton’s law of universal gravitation and which plays an analogous role in A. Einstein’s general relativity. It is equal to 6.664 x 10<sup>-11</sup> newtons per square meter per kilogram squared (see scientific notation). ',BELOW)
}
function gravitationally_bound_dtt() {
return overlib('Objects held in orbit about each other by their gravitational attraction. For example, satellites in orbit around the earth are gravitationally bound to Earth since they can’t escape Earth’s gravity. By contrast, the Voyager spacecraft, which explored the outer solar system, was launched with enough energy to escape Earth’s gravity altogether, and hence it is not gravitationally bound. ',BELOW)
}
function GRIP_dtt() {
return overlib('A balloon-borne gamma-ray telescope made by a group at the California Institute of Technology. It has had many successful flights. ',BELOW)
}
function GRIS_dtt() {
return overlib('A balloon-borne instrument which uses germanium detectors for high resolution gamma-ray spectroscopy. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function general_relativity_dtt() {
return overlib('The geometric theory of gravitation developed by Albert Einstein, incorporating and extending the theory of special relativity to accelerated frames of reference and introducing the principle that gravitational and inertial forces are equivalent. The theory has consequences for the bending of light by massive objects, the nature of black holes, and the fabric of space and time. ',BELOW)
}
function GMC_dtt() {
return overlib('Massive clouds of gas in interstellar space composed primarily of hydrogen molecules (two hydrogen atoms bound together), though also containing other molecules observable by radio telescopes. These clouds can contain enough mass to make several million stars like our Sun and are often the sites of star formation. ',BELOW)
}
function GLAST_dtt() {
return overlib('Gamma-ray Large Area Space Telescope (GLAST) is an international mission planned for launch in 2006. GLAST will study the universe in the energy range 10 keV - 300 GeV. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function Ginga_dtt() {
return overlib('The third Japanese X-ray mission, also known as Astro-C. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function gravitational_collapse_dtt() {
return overlib('When a massive body collapses under its own weight. (For example, interstellar clouds collapse to become stars until the onset of <A HREF="#nuclear_fusion">nuclear fusion</A> stops the collapse.);',BELOW)
}
function gravitational_radius_dtt() {
return overlib('See event horizon. ',BELOW)
}
function gravitational_waves_dtt() {
return overlib('Ripples in space-time caused by the motion of objects in the universe. The most notable sources are orbiting neutron stars, merging black holes, and collapsing stars. Gravitational waves are also thought to eminate from the Big Bang.',BELOW)
}
function gravity_dtt() {
return overlib('A mutual physical force attracting two bodies. ',BELOW)
}
function GSFC_dtt() {
return overlib('Goddard Space Flight Center, one of the centers operated by NASA. ',BELOW)
}
function guest_star_dtt() {
return overlib('The ancient Chinese term for a star that newly appears in the night sky, and then later disappears. Later, the Europeans called this a nova. ',BELOW)
}
function Hawking_radiation_dtt() {
return overlib('A theory first proposed by British physicist Stephen Hawking, that due to a combination of properties of quantum mechanics and gravity, under certain conditions black holes can seem to emit radiation. ',BELOW)
}
function Hawking_temperature_dtt() {
return overlib('The temperature inferred for a black hole based on the Hawking radiation detected from it. ',BELOW)
}
function HEAO_dtt() {
return overlib('The High Energy Astrophysical Observatory satellite series <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function HEASARC_dtt() {
return overlib('High Energy Astrophysics Science Archive Research Center, located at NASA’s Goddard Space Flight Center. The HEASARC creates and maintains archives of data from ultraviolet, x-ray and gamma-ray satellites for use by astronomers around the world. ',BELOW)
}
function helium_dtt() {
return overlib('The second lightest and second most abundant element. The typical helium atom consists of a nucleus of two protons and two neutrons surrounded by two electrons. Helium was first discovered in our Sun. Roughly 25 percent of our Sun is helium. ',BELOW)
}
function herschel_dtt() {
return overlib('Sir William Herschel was a renowned astronomer who first detected the infrared region of the electromagnetic spectrum in 1800. ',BELOW)
}
function Heinrich_Hertz_dtt() {
return overlib('A German physics professor who did the first experiments with generating and receiving electromagnetic waves, in particular radio waves. In his honor, the units associated with measuring the cycles per second of the waves (or the number of times the tip-tops of the waves pass a fixed point in space in 1 second of time) is called the hertz. ',BELOW)
}
function hertz_dtt() {
return overlib('The derived SI unit of frequency, defined as a frequency of 1 cycle per second. ',BELOW)
}
function HST_dtt() {
return overlib('Hubble Space Telescope ',BELOW)
}
function Hubble_constant_dtt() {
return overlib('The constant which determines the relationship between the distance to a galaxy and its velocity of recession due to the expansion of the Universe. After many years in which the Hubble constant was only known to be somewhere between 50 and 100 km/s/Mpc, it has been determined to be 70 km/s/Mpc ▒ 7 km/s/Mpc by the Hubble Space Telescope’s Key Project team. (Advances in cosmology have shown that since the Universe is self gravitating, Ho is not truly constant. Astronomers thus seek its present value.) ',BELOW)
}
function Hubble_law_dtt() {
return overlib('A relationship between a galaxy’s distance from us and its velocity through space. The farther away a galaxy is from us, the faster it is receding from us. The constant of proportionality is the Hubble constant, Ho, named after Edwin P. Hubble who discovered the relationship. Hubble’s Law is interpreted as evidence that the Universe is expanding. ',BELOW)
}
function hubble_dtt() {
return overlib('American astronomer whose observations proved that galaxies are "island universes", not nebulae inside our own galaxy. His greatest discovery, called "Hubble’s Law", was the linear relationship between a galaxy’s distance and the speed with which it is moving. The Hubble Space Telescope is named in his honor. <br><font color=990000>A link to a picture of Edwin Hubble is available in the dictionary.</font>',BELOW)
}
function huygens_dtt() {
return overlib('A Dutch physicist who was the leading proponent of the wave theory of light. He also made important contributions to mechanics, stating that in a collision between bodies, neither loses nor gains ``motion’’ (his term for momentum). In astronomy, he discovered Titan (Saturn’s largest moon) and was the first to correctly identify the observed elongation of Saturn as the presence of Saturn’s rings. <br><font color=990000>A link to a picture of Christian Huygens is available in the dictionary.</font>',BELOW)
}
function hydrogen_dtt() {
return overlib('The lightest and most abundant element. A hydrogen atom consists of one proton and one electron. Hydrogen composes about 75 percent of the Sun, but only a tiny fraction of the Earth. ',BELOW)
}
function IKI_dtt() {
return overlib('The Space Research Institute in Russia. It is the equivalent of NASA in the U.S. ',BELOW)
}
function implosion_dtt() {
return overlib('A violent inward collapse. An inward explosion. ',BELOW)
}
function infrared_dtt() {
return overlib('Electromagnetic radiation at wavelengths longer than the red end of visible light and shorter than microwaves (roughly between 1 and 100 microns). Almost none of the infrared portion of the electromagnetic spectrum can reach the surface of the Earth, although some portions can be observed by high-altitude aircraft (such as the Kuiper Observatory) or telescopes on high mountaintops (such as the peak of Mauna Kea in Hawaii). ',BELOW)
}
function inclination_dtt() {
return overlib('The inclination of a planet’s orbit is the angle between the plane of its orbit and the ecliptic; the inclination of a moon’s orbit is the angle between the plane of its orbit and the plane of its primary’s equator. ',BELOW)
}
function image_dtt() {
return overlib('In astronomy, a picture of the sky. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function ISM_dtt() {
return overlib('The gas and dust between stars, which fills the plane of the Galaxy much like air fills the world we live in. For centuries, scientists believed that the space between the stars was empty. It wasn’t until the eighteenth century, when William Herschel observed nebulous patches of sky through his telescope, that serious consideration was given to the notion that interstellar space was something to study. It was only in the last century that observations of interstellar material suggested that it was not even uniformly distributed through space, but that it had a unique structure. ',BELOW)
}
function ionized_gas_dtt() {
return overlib('Gas whose atoms have lost or gained electrons, causing them to be electrically charged. In astronomy, this term is most often used to describe the gas around hot stars where the high temperature causes atoms to lose electrons. ',BELOW)
}
function ions_dtt() {
return overlib('An atom with one or more electrons stripped off, giving it a net positive charge. ',BELOW)
}
function IUE_dtt() {
return overlib('International Ultraviolet Explorer, an ultraviolet space observatory launch in 1978. Originally designed for a 3 year mission, IUE exceeded all expectations and functioned for over 18 years, finally ceasing operation in September 1996. ',BELOW)
}
function jets_dtt() {
return overlib('Beams of particles, usually coming from an active galactic nucleus or a pulsar. Unlike a jet airplane, when the stream of gas is in one direction, astrophysical jets come in pairs with each jet aiming in opposite directions. ',BELOW)
}
function kelvin_dtt() {
return overlib('The fundamental SI unit of thermodynamic temperature defined as 1/273.16 of the thermodynamic temperature of the triple point of water. More practically speaking, the Kelvin temperature scale measures an object’s temperature above absolute zero, the theoretical coldest possible temperature. On the Kelvin scale the freezing point of water is 273 ( = 0o C = 32o F) [ K = 273 + C = 273 + 5/9 * (F-32)]. The Kelvin temperature scale is often used in sciences such as astronomy. ',BELOW)
}
function Keplers_laws_dtt() {
return overlib('Kepler’s first law A planet orbits the Sun in an ellipse with the Sun at one focus. ',BELOW)
}
function kepler_dtt() {
return overlib('German astronomer and mathematician. Considered a founder of modern astronomy, he formulated the famous three laws of planetary motion. They comprise a quantitative formulation of Copernicus’s theory that the planets revolve around the Sun. <br><font color=990000>A link to a picture of Johannes Kepler is available in the dictionary.</font>',BELOW)
}
function kilogram_dtt() {
return overlib('The fundamental SI unit of mass. The kilogram is the only SI unit still maintained by a physical artifact (a platinum-iridium bar) kept in the International Bureau of Weights and Measures at Sevres, France. One kilogram is equivalent to 1,000 grams or about 2.2 pounds; the mass of a liter of water. ',BELOW)
}
function kinematics_dtt() {
return overlib('Refers to the calculation or description of the underlying mechanics of motion of an astronomical object. For example, in radioastronomy, spectral line graphs are used to determine the kinematics or relative motions of material at the center of a galaxy or surrounding a star as it is born. ',BELOW)
}
function Kirchhoffs_law_dtt() {
return overlib('The emissivity of a body is equal to its absorbance at the same temperature. ',BELOW)
}
function L0_dtt() {
return overlib('A representation of the luminosity of an object in terms of Solar luminosity. The average luminosity of the Sun is about 4x10<SUP>33</SUP> erg/sec. Astronomers often express units for other objects in terms of solar units, which makes the resulting numbers smaller and easier to deal with. ',BELOW)
}
function Lagrange_points_dtt() {
return overlib('Points in the vicinity of two massive bodies (such as the Earth and the Moon) where each others’ respective gravities balance. There are five, labeled L1 through L5. L1, L2, and L3 lie along the centerline between the centers of mass between the two masses; L1 is on the inward side of the secondary, L2 is on the outward side of the secondary; and L3 is on the outward side of the primary. L4 and L5, the so-called Trojan points, lie along the orbit of the secondary around the primary, sixty degrees ahead and behind of the secondary. ',BELOW)
}
function lagrange_dtt() {
return overlib('A French mathematician of the eighteenth century. His work Mecanique Analytique (Analytical Mechanics; 1788) was a mathematical masterpiece. It contained clear, symmetrical notation and covered almost every area of pure mathematics. Lagrange developed the calculus of variations, established the theory of differential equations, and provided many new solutions and theorems in number theory. His classic Theorie des fonctions analytiques laid some of the foundations of group theory. Lagrange also invented the method of solving differential equations known as variation of parameters. <br><font color=990000>A link to a picture of Joseph Lagrange is available in the dictionary.</font>',BELOW)
}
function laser_dtt() {
return overlib('Laser is an acronym for Light Amplification by Stimulated Emission of Radiation. It’s a device that produces a coherent beam of optical radiation by stimulating electronic, ionic, or molecular transitions to higher levels so that when they return to lower energy levels they emit energy. ',BELOW)
}
function LHEA_dtt() {
return overlib('Laboratory for High Energy Astrophysics, located at NASA’s Goddard Space Flight Center. The scientists, programmers and technicians working here study the astrophysics of objects which emit cosmic ray, x-ray and gamma-ray radiation. ',BELOW)
}
function light_curve_dtt() {
return overlib('A graph showing how the radiation from an object varies over time. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function light_year_dtt() {
return overlib('A unit of length used in astronomy which equals the distance light travels in a year. At the rate of 300,000 kilometers per second (671 million miles per hour), 1 light-year is equivalent to 9.46053 x 10<SUP>12</SUP> km, 5,880,000,000,000 miles or 63,240 AU (see scientific notation). ',BELOW)
}
function speed_of_light_dtt() {
return overlib('The speed at which electromagnetic radiation propagates in a vacuum; it is defined as 299 792 458 m/s (186,000 miles/second). Einstein’s Theory of Relativity implies that nothing can go faster than the speed of light. ',BELOW)
}
function light_dtt() {
return overlib('The common term for electromagnetic radiation, usually referring to that portion visible to the human eye. However, other bands of the e-m spectrum are also often referred to as different forms of light. ',BELOW)
}
function limb_dtt() {
return overlib('The outer edge of the apparent disk of a celestial body. ',BELOW)
}
function LISA_dtt() {
return overlib('Laser Interferometer Space Antenna - A NASA mission which will detect gravitational waves. LISA will consist of three satellites that use laser interferometry to monitor their positions relative to each other. Gravitational waves passing by the satellites cause small changes in the distances between the satellites.',BELOW)
}
function luminosity_dtt() {
return overlib('The rate at which a star or other object emits energy, usually in the form of electromagnetic radiation. ',BELOW)
}
function M0_dtt() {
return overlib('A representation of the mass of an object in terms of Solar mass. The average mass of the Sun is about 2x10<SUP>33</SUP> grams. Astronomers often express units for other objects in terms of solar units, since it makes the resulting numbers smaller and easier to deal with. ',BELOW)
}
function magnetic_field_dtt() {
return overlib('A description of the strength of the magnetic force exerted by an object. Bar magnets have "di-polar fields", as the force is exerted from the two ends of the bar. In simple terms, the earth, the sun, stars, pulsars all have dipolar magnetic fields. ',BELOW)
}
function magnetic_pole_dtt() {
return overlib('Either of two limited regions in a magnet at which the magnet’s field is most intense. The two regions have opposing polarities, which we label "north" and "south", after the two poles on the Earth. ',BELOW)
}
function magnetosphere_dtt() {
return overlib('The region of space in which the magnetic field of an object (e.g., a star or planet) dominates the radiation pressure of the stellar wind to which it is exposed. ',BELOW)
}
function magnetotail_dtt() {
return overlib('The portion of a planetary magnetosphere which is pushed in the direction of the solar wind. ',BELOW)
}
function magnitude_dtt() {
return overlib('The degree of brightness of a celestial body designated on a numerical scale, on which the brightest star has magnitude -1.4 and the faintest visible star has magnitude 6, with the scale rule such that a decrease of one unit represents an increase in apparent brightness by a factor of 2.512; also called apparent magnitude. ',BELOW)
}
function solar_mass_dtt() {
return overlib('A unit of mass equivalent to the mass of the Sun. 1 solar mass = 1 M<SUB>sun</SUB> = 2 x 10<SUP>33</SUP> grams. ',BELOW)
}
function mass_dtt() {
return overlib('A measure of the total amount of material in a body, defined either by the inertial properties of the body or by its gravitational influence on other bodies. ',BELOW)
}
function matter_dtt() {
return overlib('A word used for any kind of stuff which contains mass. ',BELOW)
}
function megaton_dtt() {
return overlib('A unit of energy used to describe nuclear warheads. The same amount energy as 1 million tons of TNT. ',BELOW)
}
function messier_dtt() {
return overlib('The 18th century French astronomer who compiled a list of approximately 100 fuzzy, diffuse looking objects which appeared at fixed positions in the sky. Being a comet-hunter, Messier compiled this list of objects which he knew were not comets. His list is now well known to professional and amateur astronomers as containing the brightest and most striking nebulae, star clusters, and galaxies in the sky. ',BELOW)
}
function meter_dtt() {
return overlib('The fundamental SI unit of length, defined as the length of the path traveled by light in vacuum during a period of 1/299 792 458 s. A unit of length equal to about 39 inches. A kilometer is equal to 1000 meters. ',BELOW)
}
function metric_dtt() {
return overlib('See SI. ',BELOW)
}
function microquasar_dtt() {
return overlib('Microquasars are stellar mass black holes, that display characteristics of the supermassive black holes found at the centers of some galaxies. For instance, they have radio jets - something not every black hole has. ',BELOW)
}
function microwave_dtt() {
return overlib('Electromagnetic radiation which has a longer wavelength (between 1 mm and 30 cm) than visible light. Microwaves can be used to study the Universe, communicate with satellites in Earth orbit, and cook popcorn. ',BELOW)
}
function NASA_dtt() {
return overlib('The National Aeronautics and Space Administration, founded in 1958 as the successor to the National Advisory Committee for Aeronautics. ',BELOW)
}
function planetary_nebula_dtt() {
return overlib('A shell of gas ejected from stars like our Sun at the end of their lifetime. This gas continues to expand out from the remaining white dwarf. ',BELOW)
}
function nebula_dtt() {
return overlib('A diffuse mass of interstellar dust and gas. A <B>reflection nebula</B> shines by light reflected from nearby stars. An <B>emission nebula</B> shines by emitting light as electrons recombine with protons to form hydrogen. The electrons were made free by the ultraviolet light of a nearby star shining on a cloud of hydrogen gas. A <A HREF="dictionary.html#planetary_nebula"> planetary nebula</a> results from the explosion of a solar-like type star. ',BELOW)
}
function neutrino_dtt() {
return overlib('A fundamental particle produced in massive numbers by the nuclear reactions in stars; they are very hard to detect because the vast majority of them pass completely through the Earth without interacting. ',BELOW)
}
function neutron_star_dtt() {
return overlib('The imploded core of a massive star produced by a supernova explosion . (typical mass of 1.4 times the mass of the Sun, radius of about 5 miles, density of a neutron.) According to astronomer and author Frank Shu, "A sugar cube of neutron-star stuff on Earth would weigh as much as all of humanity!" Neutron stars can be observed as pulsars. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function neutron_dtt() {
return overlib('A particle with approximately the mass of a proton, but zero charge, commonly found in the nucleus of atoms. ',BELOW)
}
function newton_dtt() {
return overlib('English cleric and scientist; discovered the classical laws of motion and gravity; the bit with the apple is probably apocryphal. <br><font color=990000>A link to a picture of Isaac Newton is available in the dictionary.</font>',BELOW)
}
function law_of_gravity_dtt() {
return overlib('Two bodies attract each other with equal and opposite forces; the magnitude of this force is proportional to the product of the two masses and is also proportional to the inverse square of the distance between the centers of mass of the two bodies. ',BELOW)
}
function noise_dtt() {
return overlib('The random fluctuations that are always associated with a measurement that is repeated many times over. Noise appears in astronomical images as fluctuations in the image background. These fluctuations do not represent any real sources of light in the sky, but rather are caused by the imperfections of the telescope. If the noise is too high, it may obscure the dimmest objects within the field of view. ',BELOW)
}
function nova_dtt() {
return overlib('A star that experiences a sudden outburst of radiant energy, temporarily increasing its luminosity by hundreds to thousands of times before fading back to its original luminosity. ',BELOW)
}
function occultation_dtt() {
return overlib('The blockage of light by the intervention of another object; a planet can occult (block) the light from a distant star. ',BELOW)
}
function opacity_dtt() {
return overlib('A property of matter that prevents light from passing through it. The opacity or opaqueness of something depends on the frequency of the light. For instance, the atmosphere of Venus is transparent to ultraviolet light, but is opaque to visible light. ',BELOW)
}
function orbit_dtt() {
return overlib('The path of an object that is moving around a second object or point. ',BELOW)
}
function OSO_3_dtt() {
return overlib('Orbiting Solar Observatory 3 <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function OSO_8_dtt() {
return overlib('Orbiting Solar Observatory 8 <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function pair_production_dtt() {
return overlib('The physical process whereby a gamma-ray photon, usually through an interaction with the electromagnetic field of a nucleus, produces an electron and an anti-electron (positron). The original photon no longer exists, its energy having gone to the two resulting particles. The inverse process, pair annihilation, creates two gamma-ray photons from the mutual destruction of an electron/positron pair. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function parallax_dtt() {
return overlib('The apparent motion of a relatively close object compared to a more distant background as the location of the observer changes. Astronomically, it is half the angle which a a star appears to move as the earth moves from one side of the sun to the other. ',BELOW)
}
function parsec_dtt() {
return overlib('The distance to an object which has a parallax of one arc second. It is equal to 3.26 light years, or 3.1 x 10<sup>18</sup> cm (see scientific notation ). A kiloparsec (kpc) is equal to 1000 parsecs. A megaparsec (Mpc) is equal to a million (10<sup>6</sup>) parsecs. ',BELOW)
}
function periapsis_dtt() {
return overlib('The point in an orbit when two objects are closest together. Special names are given to this point for commonly used systems: see periastron , perihelion, and perigee. The opposite of apoapsis. ',BELOW)
}
function periastron_dtt() {
return overlib('The point of closest approach of two stars, as in a binary star orbit. Opposite of apastron. ',BELOW)
}
function perigee_dtt() {
return overlib('The point in its orbit where an Earth satellite is closest to the Earth. Opposite of apogee. ',BELOW)
}
function perihelion_dtt() {
return overlib('The point in its orbit where a planet is closest to the Sun. Opposite of aphelion. ',BELOW)
}
function photoelectric_effect_dtt() {
return overlib('An effect explained by A. Einstein which demonstrates that light seems to be made up of particles, or photons. Light can excite electrons (called photoelectrons in this context) to be ejected from a metal. Light with a frequency below a certain threshold, at any intensity, will not cause any photoelectrons to be emitted from the metal. Above that frequency, photoelectrons are emitted in proportion to the intensity of incident light. ',BELOW)
}
function photon_dtt() {
return overlib('The smallest (quantum) unit of light/electromagnetic energy. Photons are generally regarded as particles with zero mass and no electric charge. ',BELOW)
}
function pi_dtt() {
return overlib('The constant equal to the ratio of the circumference of a circle to its diameter, which is approximately 3.141593. ',BELOW)
}
function Planck_constant_dtt() {
return overlib('The fundamental constant equal to the ratio of the energy of a quantum of energy to its frequency. It is the quantum of action. It has the value 6.626196 x 10<sup>-34</sup> J s (see scientific notation). ',BELOW)
}
function Planck_equation_dtt() {
return overlib('The quantum mechanical equation relating the energy of a photon E to its frequency nu: E = h x nu ',BELOW)
}
function plasma_dtt() {
return overlib('A low-density gas in which the individual atoms are ionized (and therefore charged), even though the total number of positive and negative charges is equal, maintaining an overall electrical neutrality. ',BELOW)
}
function pointing_dtt() {
return overlib('The direction in the sky to which the telescope is pointed. Pointing also describes how accurately a telescope can be pointed toward a particular direction in the sky. ',BELOW)
}
function polarization_dtt() {
return overlib('A special property of light; light has three properties, brightness, color and polarization. Polarization is a condition in which the planes of vibration of the various rays in a light beam are at least partially aligned. ',BELOW)
}
function positron_dtt() {
return overlib('The antiparticle to the electron. The positron has most of the same characteristics as an electron except it is positively charged. ',BELOW)
}
function protostar_dtt() {
return overlib('Very dense regions (or cores) of molecular clouds where stars are in the process of forming. ',BELOW)
}
function proton_dtt() {
return overlib('A particle with a positive charge commonly found in the nucleus of atoms. ',BELOW)
}
function Ptolemy_dtt() {
return overlib('A.k.a. Claudius Ptolemaeus. Ptolemy believed the planets and Sun to orbit the Earth in the order Mercury, Venus, Sun, Mars, Jupiter, Saturn. This system became known as the Ptolemaic system and predicted the positions of the planets accurately enough for naked-eye observations (although it made some ridiculous predictions, such as that the distance to the moon should vary by a factor of two over its orbit). He authored a book called Mathematical Syntaxis (widely known as the Almagest). The Almagest included a star catalog containing 48 constellations, using the names we still use today. <br><font color=990000>A link to a picture of Ptolemy is available in the dictionary.</font>',BELOW)
}
function pulsar_dtt() {
return overlib('A rotating neutron star which generates regular pulses of radiation. Pulsars were discovered by observations at radio wavelengths but have since been observed at optical, X-ray, and gamma-ray energies. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function PVO_dtt() {
return overlib('Pioneer Venus Orbiter <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function quasar_dtt() {
return overlib('An enormously bright object at the edge of our universe which emits massive amounts of energy. In an optical telescope, they appear point-like, similar to stars, from which they derive their name (quasar = quasi-stellar). Current theories hold that quasars are one type of AGN. ',BELOW)
}
function QSS_dtt() {
return overlib('Sometimes also called quasi-stellar object (QSO); A stellar-appearing object of very large redshift that is a strong source of radio waves; presumed to be extragalactic and highly luminous. ',BELOW)
}
function radial_velocity_dtt() {
return overlib('The speed at which an object is moving away or toward an observer. By observing spectral lines, astronomers can determine how fast objects are moving away from or toward us; however, these spectral lines cannot be used to measure how fast the objects are moving across the sky. ',BELOW)
}
function radiation_belt_dtt() {
return overlib('Regions of charged particles in a magnetosphere. ',BELOW)
}
function synchrotron_radiation_dtt() {
return overlib('Electromagnetic radiation given off when very high energy electrons encounter magnetic fields. ',BELOW)
}
function radiation_dtt() {
return overlib('Energy emitted in the form of waves (light) or particles (photons). ',BELOW)
}
function radian_dtt() {
return overlib('The supplementary SI unit of angular measure, defined as the central angle of a circle whose subtended arc is equal to the radius of the circle. One radian is approximately 57o. ',BELOW)
}
function radio_dtt() {
return overlib('Electromagnetic radiation which has the lowest frequency, the longest wavelength, and is produced by charged particles moving back and forth; the atmosphere of the Earth is transparent to radio waves with wavelengths from a few millimeters to about twenty meters. ',BELOW)
}
function Rayleigh_criterion_dtt() {
return overlib('A criterion for how finely a set of optics may be able to distinguish the location of objects which are near each other. It begins with the assumption that the central ring of one image should fall on the first dark ring of another image; for an objective lens with diameter d and employing light with a wavelength lambda (usually taken to be 560 nm), the resolving power is approximately given by 1.22 x lambda/d ',BELOW)
}
function Rayleigh_Taylor_dtt() {
return overlib('Rayleigh-Taylor instabilities occur when a heavy (more dense) fluid is pushed against a light fluid -- like trying to balance water on top of air by filling a glass 1/2 full and carefully turning it over. Rayleigh-Taylor instabilities are important in many astronomical objects, because the two fluids trade places by sticking "fingers" into each other. These "fingers" can drag the magnetic field lines along with them, thus both enhancing and aligning the magnetic field. This result is evident in the example of a supernova remnant in the diagram below, from Chevalier (1977): ',BELOW)
}
function red_giant_dtt() {
return overlib('A star that has low surface temperature and a diameter that is large relative to the Sun. ',BELOW)
}
function redshift_dtt() {
return overlib('An apparent shift toward longer wavelengths of spectral lines in the radiation emitted by an object caused by the emitting object moving away from the observer. See also Doppler effect. ',BELOW)
}
function reflection_law_dtt() {
return overlib('For a wavefront intersecting a reflecting surface, the angle of incidence is equal to the angle of reflection, in the same plane defined by the ray of incidence and the normal. ',BELOW)
}
function relativity_principle_dtt() {
return overlib('The principle, employed by Einstein’s relativity theories, that the laws of physics are the same, at least locally, in all coordinate frames. This principle, along with the principle of the constancy of the speed of light, constitutes the founding principles of special relativity. ',BELOW)
}
function special_relativity_dtt() {
return overlib('The physical theory of space and time developed by Albert Einstein, based on the postulates that all the laws of physics are equally valid in all frames of reference moving at a uniform velocity and that the speed of light from a uniformly moving source is always the same, regardless of how fast or slow the source or its observer is moving. The theory has as consequences the relativistic mass increase of rapidly moving objects, time dilatation, and the principle of mass-energy equivalence. See also general relativity. ',BELOW)
}
function relativity_dtt() {
return overlib('Theories of motion developed by Albert Einstein, for which he is justifiably famous. Relativity More accurately describes the motions of bodies in strong gravitational fields or at near the speed of light than Newtonian mechanics. All experiments done to date agree with relativity’s predictions to a high degree of accuracy. (Curiously, Einstein received the Nobel prize in 1921 not for Relativity but rather for his 1905 work on the photoelectric effect.) ',BELOW)
}
function spatial_resolution_dtt() {
return overlib('In astronomy, the ability of a telescope to differentiate between two objects in the sky which are separated by a small angular distance. The closer two objects can be while still allowing the telescope to see them as two distinct objects, the higher the resolution of the telescope. ',BELOW)
}
function spectral_resolution_dtt() {
return overlib('Similar to spatial resolution except that it applies to frequency, spectral resolution is the ability of the telescope to differentiate two light signals which differ in frequency by a small amount. The closer the two signals are in frequency while still allowing the telescope to separate them as two distinct components, the higher the spectral resolution of the telescope. ',BELOW)
}
function resonance_dtt() {
return overlib('A relationship in which the orbital period of one body is related to that of another by a simple integer fraction, such as 1/2, 2/3, 3/5. ',BELOW)
}
function retrograde_dtt() {
return overlib('The rotation or orbital motion of an object in a clockwise direction when viewed from the north pole of the ecliptic; moving in the opposite sense from the great majority of solar system bodies. ',BELOW)
}
function revolution_dtt() {
return overlib('The movement of one celestial body which is in orbit around another. It is often measured as the "orbital period." ',BELOW)
}
function RA_dtt() {
return overlib('A coordinate which, along with declination, may be used to locate any position in the sky. Right ascension is analogous to longitude for locating positions on the Earth. ',BELOW)
}
function ritter_dtt() {
return overlib('Ritter is credited with discovering and investigating the ultraviolet region of the electromagnetic spectrum. ',BELOW)
}
function Roche_limit_dtt() {
return overlib('The smallest distance from a planet or other body at which purely gravitational forces can hold together a satellite or secondary body of the same mean density as the primary. At less than this distance the tidal forces of the larger object would break up the smaller object. ',BELOW)
}
function Roche_lobe_dtt() {
return overlib('The volume around a star in a binary system in which, if you were to release a particle, it would fall back onto the surface of that star. A particle released above the Roche lobe of either star will, in general, occupy the `circumbinary’ region that surrounds both stars. The point at which the Roche lobes of the two stars touch is called the inner Lagrangian or L1 point. If a star in a close binary system evolves to the point at which it `fills’ its Roche lobe, theoretical calculations predict that material from this star will overflow both onto the companion star (via the L1 point) and into the environment around the binary system. ',BELOW)
}
function ROSAT_dtt() {
return overlib('Roentgen Satellite <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function roentgen_dtt() {
return overlib('A German scientist who fortuitously discovered X-rays in 1895. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function synchronous_rotation_dtt() {
return overlib('Said of a satellite if the period of its rotation about its axis is the same as the period of its orbit around its primary. This implies that the satellite always keeps the same hemisphere facing its primary (e.g. the Moon). It also implies that one hemisphere (the leading hemisphere) always faces in the direction of the satellite’s motion while the other (trailing) one always faces backward. ',BELOW)
}
function rotation_dtt() {
return overlib('The spin of a celestial body on its own axis. In high energy astronomy, this is often measured as the "spin period."',BELOW)
}
function RXTE_dtt() {
return overlib('X-ray Timing Explorer, also known as the Rossi X-ray Timing Explorer (RXTE) <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function SAS_2_dtt() {
return overlib('The second Small Astronomy Satellite: a NASA satellite launched November 1972 with a mission dedicated to gamma-ray astronomy. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function SAS_3_dtt() {
return overlib('The third Small Astronomy Satellite: a NASA satellite launched May 1975 to determine the location of bright X-ray sources and search for X-ray novae and other transient phenomena. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function satellite_dtt() {
return overlib('A body that revolves around a larger body. For example, the moon is a satellite of the earth. ',BELOW)
}
function Schwarzschild_black_hole_dtt() {
return overlib('A black hole described by solutions to Einstein’s equations of general relativity worked out by Karl Schwarzschild in 1916. The solutions assume the black hole is not rotating, and that the size of its event horizon is determined solely by its mass. ',BELOW)
}
function Schwarzschild_radius_dtt() {
return overlib('The radius r of the event horizon for a Schwarzschild black hole. ',BELOW)
}
function scientific_notation_dtt() {
return overlib('A compact format for writing very large or very small numbers, most often used in scientific fields. The notation separates a number into two parts: a decimal fraction, usually between 1 and 10, and a power of ten. Thus 1.23 x 10<sup>4</sup> means 1.23 times 10 to the fourth power or 12,300; 5.67 x 10<sup>-8</sup> means 5.67 divided by 10 to the eighth power or 0.0000000567. ',BELOW)
}
function second_dtt() {
return overlib('The fundamental SI unit of time, defined as the period of time equal to the duration of 9,192,631,770 periods of the radiation corresponding to the transition between two hyperfine levels of the ground state of the cesium-133 atom. A nanosecond is equal to one-billionth (10<sup>-9</sup>) of a second. ',BELOW)
}
function semimajor_axis_dtt() {
return overlib('The semimajor axis of an ellipse (e.g. a planetary orbit) is half the length of the major axis, which is the line segment passing through the foci of the ellipse with endpoints on the ellipse itself. The semimajor axis of a planetary orbit is also the average distance from the planet to its primary. The periapsis and apoapsis distances can be calculated from the semimajor axis and the eccentricity by rp = a(1-e) and ra = a(1+e). ',BELOW)
}
function sensitivity_dtt() {
return overlib('A measure of how bright objects need to be in order for that telescope to detect these objects. A highly sensitive telescope can detect dim objects, while a telescope with low sensitivity can detect only bright ones. ',BELOW)
}
function shock_wave_dtt() {
return overlib('A strong compression wave where there is a sudden change in gas velocity, density, pressure and temperature. ',BELOW)
}
function singularity_dtt() {
return overlib('The center of a black hole, where the curvature of spacetime is maximal. At the singularity, the gravitational tides diverge; no solid object can even theoretically survive hitting the singularity. Although singularities generally predict inconsistencies in theory, singularities within black holes do not necessarily imply that general relativity is incomplete so long as singularities are always surrounded by event horizons. ',BELOW)
}
function solar_flares_dtt() {
return overlib('Violent eruptions of gas on the Sun’s surface. ',BELOW)
}
function spectral_line_dtt() {
return overlib('Light given off at a specific frequency by an atom or molecule. Every different type of atom or molecule gives off light at its own unique set of frequencies; thus, astronomers can look for gas containing a particular atom or molecule by tuning the telescope to one of the gas’s characteristic frequencies. For example, carbon monoxide (CO) has a spectral line at 115 Gigahertz (or a wavelength of 2.7 mm). ',BELOW)
}
function spectrometer_dtt() {
return overlib('The instrument connected to a telescope that separates the light signals into different frequencies, producing a spectrum. ',BELOW)
}
function spectroscopy_dtt() {
return overlib('The study of spectral lines from different atoms and molecules. Spectroscopy is an important part of studying the chemistry that goes on in stars and in interstellar clouds. ',BELOW)
}
function spectrum_dtt() {
return overlib('A plot of the intensity of light at different frequencies. Or the distribution of wavelengths and frequencies. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function star_cluster_dtt() {
return overlib('A bunch of stars (ranging in number from a few to hundreds of thousands) which are bound to each other by their mutual gravitational attraction. ',BELOW)
}
function star_dtt() {
return overlib('A large ball of gas that creates and emits its own radiation. ',BELOW)
}
function Stefan_Boltzmann_constant_dtt() {
return overlib('The constant of proportionality present in the Stefan-Boltzmann law. It is equal to 5.6697 x 10<sup>-8</sup> Watts per square meter per degree Kelvin to the fourth power (see scientific notation). ',BELOW)
}
function Boltzmann_law_dtt() {
return overlib('The radiated power P (rate of emission of electromagnetic energy) of a hot body is proportional to the radiating surface area, A, and the fourth power of the thermodynamic temperature, T. The constant of proportionality is the Stefan-Boltzmann constant. ',BELOW)
}
function stellar_classification_dtt() {
return overlib('Stars are given a designation consisting of a letter and a number according to the nature of their spectral lines which corresponds roughly to surface temperature. The classes are: O, B, A, F, G, K, and M; O stars are the hottest; M the coolest. The numbers are simply subdivisions of the major classes. The classes are oddly sequenced because they were assigned long ago before we understood their relationship to temperature. O and B stars are rare but very bright; M stars are numerous but dim. The Sun is designated G2. ',BELOW)
}
function stellar_wind_dtt() {
return overlib('The ejection of gas off the surface of a star. Many different types of stars, including our Sun, have stellar winds; however, a star’s wind is strongest near the end of its life when it has consumed most of its fuel. ',BELOW)
}
function steradian_dtt() {
return overlib('The supplementary SI unit of solid angle defined as the solid central angle of a sphere that encloses a surface on the sphere equal to the square of the sphere’s radius. ',BELOW)
}
function supernova_dtt() {
return overlib('The death explosion of a massive star, resulting in a sharp increase in brightness followed by a gradual fading. At peak light output, supernova explosions can outshine a galaxy. The outer layers of the exploding star are blasted out in a radioactive cloud. This expanding cloud, visible long after the initial explosion fades from view, forms a supernova remnant (SNR). <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function sunspots_dtt() {
return overlib('Cooler (and thus darker) regions on the sun where the magnetic field loops up out of the solar surface. ',BELOW)
}
function SXG_dtt() {
return overlib('The Spectrum X-Gamma mission <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function Swift_dtt() {
return overlib('Swift is a NASA mid-sized mission whose primary goal is to study gamma-ray bursts and address the mysteries surrounding their nature, origin, and causes. Swift is set to launch in 2003.<br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function SI_dtt() {
return overlib('The coherent and rationalized system of units, derived from the MKS system (which itself is derived from the metric system), in common use in physics today. The fundamental SI unit of length is the meter, of time is the second, and of mass is the kilogram. ',BELOW)
}
function Tenma_dtt() {
return overlib('The second Japanese X-ray mission, also known as Astro-B. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function William_Thomson_dtt() {
return overlib('Also known as Lord Kelvin, the British physicist who developed the Kelvin temperature scale and who supervised the laying of a trans-Atlantic cable. <br><font color=990000>A link to a picture of Lord Kelvin is available in the dictionary.</font>',BELOW)
}
function time_dilation_dtt() {
return overlib('The increase in the time between two events as measured by an observer who is outside of the reference frame in which the events take place. The effect occurs in both special and general relativity, and is quite pronounced for speeds approaching the speed of light, and in regions of high gravity. ',BELOW)
}
function Uhuru_dtt() {
return overlib('NASA’s first Small Astronomy Satellite, also known as SAS-1. Uhuru was launched from Kenya on 12 December, 1970; The seventh anniversary of Kenya’s independence. The satellite was named "Uhuru" (Swahili for "freedom") in honor of its launch date. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function ultraviolet_dtt() {
return overlib('Electromagnetic radiation at wavelengths shorter than the violet end of visible light; the atmosphere of the Earth effectively blocks the transmission of most ultraviolet light. ',BELOW)
}
function universe_dtt() {
return overlib('Everything that exists, including the Earth, planets, stars, galaxies, and all that they contain; the entire cosmos. ',BELOW)
}
function Vela_5B_dtt() {
return overlib('US Atomic Energy Commission (now the Department of Energy) satellite with an all-sky X-ray monitor <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function Venera_dtt() {
return overlib('The Venera satellites were a series of probes (fly-bys and landers) sent by the Soviet Union to the planet Venus. Several Venera satellites carried high-energy astrophysics detectors. <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function visible_dtt() {
return overlib('Electromagnetic radiation at wavelengths which the human eye can see. We perceive this radiation as colors ranging from red (longer wavelengths; ~ 700 nanometers) to violet (shorter wavelengths; ~400 nanometers.) ',BELOW)
}
function wave_particle_duality_dtt() {
return overlib('The principle of quantum mechanics which implies that light (and, indeed, all other subatomic particles) sometimes act like a wave, and sometimes act like a particle, depending on the experiment you are performing. For instance, low frequency electromagnetic radiation tends to act more like a wave than a particle; high frequency electromagnetic radiation tends to act more like a particle than a wave. ',BELOW)
}
function wavelength_dtt() {
return overlib('The distance between adjacent peaks in a series of periodic waves. Also see electromagnetic spectrum. ',BELOW)
}
function white_dwarf_dtt() {
return overlib('A star that has exhausted most or all of its nuclear fuel and has collapsed to a very small size. Typically, a white dwarf has a radius equal to about 0.01 times that of the Sun, but it has a mass roughly equal to the Sun’s. This gives a white dwarf a density about 1 million times that of water! <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function Wiens_law_dtt() {
return overlib('For a blackbody, the product of the wavelength corresponding to the maximum radiancy and the thermodynamic temperature is a constant. As a result, as the temperature rises, the maximum of the radiant energy shifts toward the shorter wavelength (higher frequency and energy) end of the spectrum. ',BELOW)
}
function WMAP_dtt() {
return overlib('Wilkinson Microwave Anistropy Probe - A NASA satellite designed to detect fluctuations in the cosmic microwave background. From its initial results published in Feb 2003, astronomers pinpointed the age of the universe, its geometry, and when the first stars appeared.',BELOW)
}
function WWW_dtt() {
return overlib('The World Wide Web -- a loose linkage of Internet sites which provide data and other services from around the world. ',BELOW)
}
function X_ray_dtt() {
return overlib('Electromagnetic radiation of very short wavelength and very high-energy; X-rays have shorter wavelengths than ultraviolet light but longer wavelengths than gamma rays. ',BELOW)
}
function XSELECT_dtt() {
return overlib('A software tools used by astrophysicists in conjunction with the FTOOLS software to analyze certain types of astronomical data. ',BELOW)
}
function XTE_dtt() {
return overlib('X-ray Timing Explorer, also known as the Rossi X-ray Timing Explorer (RXTE) <br><font color=990000>More links available in the dictionary.</font>',BELOW)
}
function Z_dtt() {
return overlib('The ratio of the observed change in wavelength of light emitted by a moving object to the rest wavelength of the emitted light. See Doppler Effect. See the dictionary for more information.',BELOW)
