Calculate the Boltzmann distribution for sodium (Na) atoms in an inductively coupled plasma a8000K. How many orders of magnitude larger is this distribution compared to Na in a flame at2700K?AE = 3.371 X 10 19 J for Na between the ground state and the lowest excited state.g* = 29o = 1Botlzmann's constant: k = 1.381 X 10-23 J/K%3DA. Boltzmann distribution for Na at 8000K is 4.73 X 102, which is 4 orders of magnitudelarger than for 2700K.O B. Boltzmann distribution for Na at 800OK is 4.73 X 102, which is 2 orders of magnitudelarger than for 2700K.C. Boltzmann distribution for Na at 8000K is 9.46 X 102, which is 2 orders of magnitudelarger than for 2700K.D. Boltzmann distribution for Na at 8000K is 9.46 X 102, which is 4 orders of magnitudelarger than for 2700K.

The Boltzmann distribution is basically the ratio of an upper state by a lower state. The formula…

Calculate the Boltzmann distribution for sodium (Na) atoms in an inductively coupled plasma a 8000K. How many orders of magnitude larger is this distribution compared to Na in a flame at 2700K? AE = 3.371 X 10 19 J for Na between the ground state and the lowest excited state. g* = 2 9o =1 Botlzmann's constant: k = 1.381X 10-23 J/K O A. Boltzmann distribution for Na at 800OK is 4.73 X 102, which is 4 orders of magnitude larger than for 2700K. O B. Boltzmann distribution for Na at 800OK is 4.73 X 102, which is 2 orders of magnitude larger than for 2700K. C. Boltzmann distribution for Na at 8000K is 9.46 X 102, which is 2 orders of magnitude larger than for 2700K. D. Boltzmann distribution for Na at 8000K is 9.46 X 102, which is 4 orders of magnitude larger than for 2700K.

Calculate the Boltzmann distribution for sodium (Na) atoms in an inductively coupled plasma a 8000K. How many orders of magnitude larger is this distribution compared to Na in a flame at 2700K? AE = 3.371 X 10 19 J for Na between the ground state and the lowest excited state. g* = 2 9o =1 Botlzmann's constant: k = 1.381X 10-23 J/K O A. Boltzmann distribution for Na at 800OK is 4.73 X 102, which is 4 orders of magnitude larger than for 2700K. O B. Boltzmann distribution for Na at 800OK is 4.73 X 102, which is 2 orders of magnitude larger than for 2700K. C. Boltzmann distribution for Na at 8000K is 9.46 X 102, which is 2 orders of magnitude larger than for 2700K. D. Boltzmann distribution for Na at 8000K is 9.46 X 102, which is 4 orders of magnitude larger than for 2700K.

Chemistry

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ISBN:9781305957404

Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

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Chapter1: Chemical Foundations

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Question

Calculate the Boltzmann distribution for sodium (Na) atoms in an inductively coupled plasma a
8000K. How many orders of magnitude larger is this distribution compared to Na in a flame at
2700K?
AE = 3.371 X 10 19 J for Na between the ground state and the lowest excited state.
g* = 2
9o = 1
Botlzmann's constant: k = 1.381 X 10-23 J/K
%3D
A. Boltzmann distribution for Na at 8000K is 4.73 X 102, which is 4 orders of magnitude
larger than for 2700K.
O B. Boltzmann distribution for Na at 800OK is 4.73 X 102, which is 2 orders of magnitude
larger than for 2700K.
C. Boltzmann distribution for Na at 8000K is 9.46 X 102, which is 2 orders of magnitude
larger than for 2700K.
D. Boltzmann distribution for Na at 8000K is 9.46 X 102, which is 4 orders of magnitude
larger than for 2700K.

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