Laboratory Techniques in Organic Chemistry
4th Edition
ISBN: 9781464134227
Author: Jerry R. Mohrig, David Alberg, Gretchen Hofmeister, Paul F. Schatz, Christina Noring Hammond
Publisher: W. H. Freeman
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Chapter 25, Problem 3Q
Interpretation Introduction
Interpretation:
The molar absorption coefficient for compound X is to be calculated.
Concept introduction:
Organic compounds absorb in ultraviolet or visible part of
In case of conjugated compounds,
UV and VIS spectroscopy help in the characterization of
In UV and VIS spectroscopy, a spectrum is obtained as a plot of absorbance versus wavelength in nanometers. Absorbance is calculated by Beers Lambert's law which is as follows:
Where,
- is molar absorptivity coefficient.
Beers Lambert's law is utilized for estimation of the concentration of a solution as the absorbance of a solution is directly related to the concentration of the solution.
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An ethanol solution of 3.5 mg/100 ml of compound Y (150.0 g/mol) in a 1.00 cm
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An ethanol solution of 3.5 mg/100 ml of compound Y (150.0 g/mol) in a 1.00 cm quartz cell has an absorbance (A) of 0.972 at λmax=235 nm. What is its molar extinction coefficient? Report your answer to the correct number of significant figures. Do not include units in your answer.
An ethanol solution of 3.5 mg/100 ml of compound Y (150.0 g/mol) in a 1.00 cm quartz cell has an absorbance (A) of 0.972 at λmax=235 nm. What is its molar extinction coefficient? Report your answer to the correct number of significant figures. Do not include units in your answer.©GMU 2020
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Laboratory Techniques in Organic Chemistry
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