An ice cube at 0 Celcius melts when placed inside a room at 22 Celcius. Based on the concepts of enthalpy, entropy, and Gibbs free energy, which of the following best explains why the process is thermodynamically favorable? A. Melting ice releases energy, delta H < 0, and delta S < 0 because the motion of the H2O molecules decreases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is smaller than delta H, resulting in a thermodynamically favorable process with delta G < 0. B. Melting ice releases energy, delta H < 0, and delta S > 0 because the motion of the H2O molecules increases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is greater than delta H, resulting in a thermodynamically favorable process with delta G > 0. C. Melting ice requires energy, delta H > 0, and delta S < 0 because the motion of the H2O molecules decreases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is smaller than delta H, resulting in a thermodynamically favorable process with delta G > 0. D. Melting ice requires energy, delta H > 0, and delta S > 0 because the motion of the H2O molecules increases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is greater than delta H, resulting in a thermodynamically favorable process with delta G < 0.
An ice cube at 0 Celcius melts when placed inside a room at 22 Celcius. Based on the concepts of enthalpy, entropy, and Gibbs free energy, which of the following best explains why the process is thermodynamically favorable? A. Melting ice releases energy, delta H < 0, and delta S < 0 because the motion of the H2O molecules decreases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is smaller than delta H, resulting in a thermodynamically favorable process with delta G < 0. B. Melting ice releases energy, delta H < 0, and delta S > 0 because the motion of the H2O molecules increases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is greater than delta H, resulting in a thermodynamically favorable process with delta G > 0. C. Melting ice requires energy, delta H > 0, and delta S < 0 because the motion of the H2O molecules decreases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is smaller than delta H, resulting in a thermodynamically favorable process with delta G > 0. D. Melting ice requires energy, delta H > 0, and delta S > 0 because the motion of the H2O molecules increases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is greater than delta H, resulting in a thermodynamically favorable process with delta G < 0.
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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An ice cube at 0 Celcius melts when placed inside a room at 22 Celcius. Based on the concepts of enthalpy, entropy, and Gibbs free energy, which of the following best explains why the process is thermodynamically favorable?
A. Melting ice releases energy, delta H < 0, and delta S < 0 because the motion of the H2O molecules decreases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is smaller than delta H, resulting in a thermodynamically favorable process with delta G < 0.
B. Melting ice releases energy, delta H < 0, and delta S > 0 because the motion of the H2O molecules increases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is greater than delta H, resulting in a thermodynamically favorable process with delta G > 0.
C. Melting ice requires energy, delta H > 0, and delta S < 0 because the motion of the H2O molecules decreases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is smaller than delta H, resulting in a thermodynamically favorable process with delta G > 0.
D. Melting ice requires energy, delta H > 0, and delta S > 0 because the motion of the H2O molecules increases as it transitions from solid to liquid. At a temperature higher than 0 Celcius, the term T delta S is greater than delta H, resulting in a thermodynamically favorable process with delta G < 0.
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