Want this question answered?
The Frank-Condon Principle states that transitions between electronic states correspond to vertical lines on an energy vs. internuclear distance diagram. The basis of this principle is that electronic transitions happen on a timescale that is significantly smaller than the vibrational period of a given molecule and therefore the distance at which they happen can be assumed to be fixed during the transition. This is significant for spectroscopy because the most intense spectral lines will correspond to transitions to the vibrational state in the upper electronic state that have the most overlap with the ground vibrational state in the lower electronic state. (From Thomas Engel's Quantum Chemistry and Spectroscopy)
The spectral class is A0Va.
Antares has a spectral class of M1LB.
Spectral Mornings was created in 1979-01.
No. K spectral type stars (which are orange) temperature is ranging from 5,000-3,500. A spectral type stars (which are blue-white) temperature is ranging from 7,500-11,000.
Spectral interference occurs when spectral lines overlap. Inductively-coupled plasma mass spectrometry has more spectral interference as its higher energy allows more electron transitions.
The cause is the transition of electrons after the interaction with a photon.
im not sure but i guess a teacher should know
The Frank-Condon Principle states that transitions between electronic states correspond to vertical lines on an energy vs. internuclear distance diagram. The basis of this principle is that electronic transitions happen on a timescale that is significantly smaller than the vibrational period of a given molecule and therefore the distance at which they happen can be assumed to be fixed during the transition. This is significant for spectroscopy because the most intense spectral lines will correspond to transitions to the vibrational state in the upper electronic state that have the most overlap with the ground vibrational state in the lower electronic state. (From Thomas Engel's Quantum Chemistry and Spectroscopy)
The precise energy levels of each orbital vary depending on the nuclear charge. Since the spectral lines correspond to transitions between orbitals, each element will have different energies for these transitions, and therefore will have a unique spectrum.
Spectral lines are produced by electrons moving from high energy orbitals to lower energy orbitals. Electrons have a quality called "spin" - they either spin "up" or "down". The spin of an electron interacts with the applied magnetic field. As a result, where there was one transition from a higher to a lower orbital, the interaction between the electron spin and the applied magnetic field creates two slightly different energy transitions, one for the spin "up" electrons and the other for the spin "down" electrons. This is what produces two spectral lines in place of the original one line.
what is spectral evidence Spectrum (spectral) refers to different frequencies of light associated with a substance.
what is spectral evidence Spectrum (spectral) refers to different frequencies of light associated with a substance.
The spectral class is A0Va.
Charles H. Corliss has written: 'Energy levels of nickel, Ni i through Ni xxvii' -- subject(s): Nickel 'Experimental transition probabilities for spectral lines of seventy elements, derived from the NBS tables of spectral-line intensities..' -- subject(s): Spectrum analysis, Tables
Spectral disturbances means Ghost.
Our Sun has a spectral class of G2V.