In an atom of any element there are electrons in the valence shell . Each shell has a fixed no of sub shells that are characterized by specific quantum nos. So this holds true for the valence shell also . Depending on the distance of the valence electrons from the nucleus and its electro static effect on the valence electrons these valence electrons absorb energy from any high energy source that comes in its proximity. Now the entire atom has become a high energy species but by the law of thermodynamics
(and nature )
every body in the universe tends to have minimum energy and achieve stability. So these high energy electrons tend to emit the absorbed energy and come back to a lower energy state for maximum stability .In the process the emitted energy is observed as spectral lines in a spectrometer .These spetral lines together form what we call as emission spectrum
Photons released from the electrons.
Not sure exactly what this question refers to, but it may be asking about the atomic emission spectra where each element of the periodic table emits certain colors of light when excited.
The Sun spectra is considered continuous.
I'm not sure what the question is referring to . . . the "sides of the sun" don't have frequencies.So, as we always do in the case of a garbled or almost meaningless question, I'll search thethings I know about to find a question that might match this one, and then answer a questionthat I can find.Maybe it's talking about the emission spectrum of the hot gases on the surface of the sun.We do know that the characteristic 'benchmarks' in an emission spectrum are shiftedtoward higher frequencies if the source is approaching us, and toward lower frequenciesif the source is receding from us. So the emission spectra from the sun's left and right'edges' (limbs) would be shifted in opposite directions, because the sun is rotating . . .one edge is moving toward us and the other edge is moving away from us.How do you feel about that question and answer ?
The light generated by stars is mostly generated by hydrogen fusion. The light emitted from hydrogen has a distinctive emission spectrum. The emission spectrum undergoes shifting when the source and the receiver (Hubble) are moving in relation to each other. The spectrum will shift to the higher frequencies and shorter wavelengths ("blue shift") when the source and receiver are moving towards each other. Due to the "fact" that the universe is expanding, the source and receiver are moving away from each other. This causes the emission spectrum to shift to lower frequencies and longer wavelengths ("red shift"). The amount of red shift is an indication of the rate at which the cource and the receiver are moving away from each other. The expanding of the universe implies that the farther a source is from the receiver, the farther away the source and receiver are from each other. The red shifts of current objects have estimated that the farthest objects that we see are ~10-15 (not sure of exact number) billion light years distant from earth. As for absorption, the light emitted from a star that passes through gases of interspace and of planets will be absorbed at different wavelengths depending on the elements contained within the gas. This allows the determination of planetary atmospheres and intergalactic clouds.
Dark-line spectrum is a "photo-negative" of emission spectrum. It is the gaps that appear in precisely the same location as corresponding bright lines. produced by a cool gas with a hot solid and you
thomas Jefferson
The same.
The emission spectrum can be used to determine the composition of a material
The atomic level is affected by the movement of electrons so as to give rise to the observed energy. This is what is used to explain the atomic emission spectra.
There are three main types of infrared spectra: absorption spectra, emission spectra, and reflection spectra. Absorption spectra are produced when a material absorbs infrared energy, emission spectra are produced when a material emits infrared radiation, and reflection spectra result from the reflection of infrared radiation off a material.
Source modulation is employed to distinguish between atomic absorption (an ac signal) and flame emission (a dc signal).
there is no atomic emission from the sun.
advantages of atomic emission
The colors of light given off when an element loses energy
R. K Winge has written: 'Inductively coupled plasma-atomic emission spectroscopy' -- subject(s): Chemical elements, Spectra
an emission spectrum that consists of a continuum of wavelengths.
Because an emission spectrum is specific to an element.It can be used to identify the element