Question 3 ( Which statement below describes why it is more energetically favorable for individual nonpolar molecules in an aqueous solution to form a single large nonpolar complex than to remain as separate nonpolar molecules? Because a large complex reduces the total surface area of the individual nonpolar molecules exposed to the aqueous solution, which allows more water molecules to have free rotation in solution; increased entropy is energetically favorable. Because a large complex reduces the total surface area of the individual nonpolar molecules exposed to the aqueous solution, which allows more water molecules to from multiple hydrogen bonds; increased enthalpy is energetically favorable. Because a large complex increases the total surface area of the nonpolar molecules exposed to the aqueous solution, which allows more water molecules to form a large cage structure; decreased entropy is energetically favorable. Because a large complex increases the total surface area of the nonpolar molecules exposed to the aqueous solution, which allows fewer water molecules to have free rotation in solution; increased entropy is energetically favorable.

Question 3 ( Which statement below describes why it is more energetically favorable for individual nonpolar molecules in an aqueous solution to form a single large nonpolar complex than to remain as separate nonpolar molecules? Because a large complex reduces the total surface area of the individual nonpolar molecules exposed to the aqueous solution, which allows more water molecules to have free rotation in solution; increased entropy is energetically favorable. Because a large complex reduces the total surface area of the individual nonpolar molecules exposed to the aqueous solution, which allows more water molecules to from multiple hydrogen bonds; increased enthalpy is energetically favorable. Because a large complex increases the total surface area of the nonpolar molecules exposed to the aqueous solution, which allows more water molecules to form a large cage structure; decreased entropy is energetically favorable. Because a large complex increases the total surface area of the nonpolar molecules exposed to the aqueous solution, which allows fewer water molecules to have free rotation in solution; increased entropy is energetically favorable.

Chemistry

10th Edition

ISBN:9781305957404

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

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

Chapter1: Chemical Foundations

Section: Chapter Questions

Problem 1RQ: Define and explain the differences between the following terms. a. law and theory b. theory and...

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