2 Use the References to access important values if needed for this question.a. Use strain energy increments in the OWL Table Reference (see References button, Strain Energy Increments) to calculate theenergy difference between the two chair conformations of the compound below.b. Specify substituent positions (axial or equatorial) in the more stable chair.c. Estimate the percent of the more stable chair at equilbrium at 25°C.(To determine the percent of the more stable chair at equilibrium, first calculate Kegy and then use this value tofind the percentage.)CH,Answers:a. The energy difference isb. In the more stable chair:k/mol.6 The chloro group is in thee The methyl group is in theposition.v position.c. At 25°C the equilibrium percent of the more stable chair conformation is approximately

One 1,3-diaxialinteraction creates 0.9 kcal/mol of energy. And gives instability to the compound.

Use the References to access important values if needed for this question. a. Use strain energy increments in the OWL Table Reference (see References button, Strain Energy Increments) to calculate the energy difference between the two chalir conformations of the compound below. b. Specify substituent positions (axial or equatorial) in the more stable chair. c. Estimate the percent of the more stable chair at equilibrlum at 25°C. (To determine the percent of the more stable chair at equilibrium, first calculate Keg and then use this value to find the percentage.) CH Answers: a. The energy difference is b. In the more stable chair: k3/mol. o The chloro group is in the e The methyl group is in the v position, v position. C. At 25°C the equilibrium percent of the more stable chair conformation is approximately

Use the References to access important values if needed for this question. a. Use strain energy increments in the OWL Table Reference (see References button, Strain Energy Increments) to calculate the energy difference between the two chalir conformations of the compound below. b. Specify substituent positions (axial or equatorial) in the more stable chair. c. Estimate the percent of the more stable chair at equilibrlum at 25°C. (To determine the percent of the more stable chair at equilibrium, first calculate Keg and then use this value to find the percentage.) CH Answers: a. The energy difference is b. In the more stable chair: k3/mol. o The chloro group is in the e The methyl group is in the v position, v position. C. At 25°C the equilibrium percent of the more stable chair conformation is approximately

Organic Chemistry: A Guided Inquiry

2nd Edition

ISBN:9780618974122

Author:Andrei Straumanis

Publisher:Andrei Straumanis

Chapter7: Cycloalkanes

Section: Chapter Questions

Problem 17E: Build a model of methylcyclohexane, and use the model to complete the following Newmanprojections of...

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Use strain energy increments in the OWL Table Reference (see References button, Strain Energy Increments) to calculate the energy difference between the two chair conformations of the compound below. Specify substituent positions (axial or equatorial) in the more stable chair. Estimate the percent of the more stable chair at equilibrium at 25°C. (To determine the percent of the more stable chair at equilibrium, first calculate Keq, and then use this value to find the percentage.)
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