For each system listed in the first column of the table below, decide (if possible) whether the change described in the second column will increase the entropy S of the system, decrease S, or leave S unchanged. If you don't have enough information to decide, check the "not enough information" button in the last column. Note for advanced students: you may assume ideal gas and ideal solution behaviour. System Change AS O AS <0 The solution is put into a semipermeable bag immersed in the water, and 50. mL of pure water flows through the bag into the sucrose solution. A 0.35 M solution of sucrose in O AS = 0 water, and a beaker of pure water, both at 37.°C. O AS > 0 not enough information O AS < 0 A solution made of potassium iodide O AS = 0 50. mL of pure water is added to (KI) in water, at 9°C. the solution. O AS > 0 not enough information O AS < 0 20. L of pure carbon dioxide (CO,) O AS = 0 The gases are mixed, with the gas and 20.0 L of pure hydrogen pressure kept constant at 3 atm. O AS > 0 (H,) gas, both at 3 atm and 26°C. not enough O information
For each system listed in the first column of the table below, decide (if possible) whether the change described in the second column will increase the entropy S of the system, decrease S, or leave S unchanged. If you don't have enough information to decide, check the "not enough information" button in the last column. Note for advanced students: you may assume ideal gas and ideal solution behaviour. System Change AS O AS <0 The solution is put into a semipermeable bag immersed in the water, and 50. mL of pure water flows through the bag into the sucrose solution. A 0.35 M solution of sucrose in O AS = 0 water, and a beaker of pure water, both at 37.°C. O AS > 0 not enough information O AS < 0 A solution made of potassium iodide O AS = 0 50. mL of pure water is added to (KI) in water, at 9°C. the solution. O AS > 0 not enough information O AS < 0 20. L of pure carbon dioxide (CO,) O AS = 0 The gases are mixed, with the gas and 20.0 L of pure hydrogen pressure kept constant at 3 atm. O AS > 0 (H,) gas, both at 3 atm and 26°C. not enough O information
Chemistry: The Molecular Science
5th Edition
ISBN:9781285199047
Author:John W. Moore, Conrad L. Stanitski
Publisher:John W. Moore, Conrad L. Stanitski
Chapter16: Thermodynamics: Directionality Of Chemical Reactions
Section: Chapter Questions
Problem 121QRT
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Question
For each system listed in the first column of the table below, decide (if possible) whether the change described in the second column will increase the entropy S
of the system, decrease S, or leave S unchanged. If you don't have enough information to decide, check the "not enough information" button in the last column.
Note for advanced students: you may assume ideal gas and ideal solution behaviour.
Transcribed Image Text:For each system listed in the first column of the table below, decide (if possible) whether the change described in the second column will increase the entropy S
of the system, decrease S, or leave S unchanged. If you don't have enough information to decide, check the "not enough information" button in the last column.
Note for advanced students: you may assume ideal gas and ideal solution behaviour.
System
Change
AS
O AS < 0
The solution is put into a
semipermeable bag immersed in the
water, and 50. mL of pure water
flows through the bag into the
sucrose solution.
A 0.35 M solution of sucrose in
O AS = 0
water, and a beaker of pure water,
both at 37.°C.
O AS > 0
not enough
information
O AS < 0
A solution made of potassium iodide
O AS = 0
50. mL of pure water is added to
(KI) in water, at 9°C.
the solution.
O AS > 0
not enough
information
O AS < 0
20. L of pure carbon dioxide (CO,)
O AS = 0
The gases are mixed, with the
gas and 20.0 L of pure hydrogen
pressure kept constant at 3 atm,
O AS > 0
(H,) gas, both at 3 atm and 26°C.
not enough
O information
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