Use the following data to calculate the total heat in kJ to convert 2.50 g solid sulfur dioxide at -73.0 oC to a gas at a temperature of 60.0 oC. Melting point of SO2 = -73.0 oC Boiling point of SO2 = -10.0 oC ΔHfusion of SO2 = 8.62 kJ/mole ΔHvaporization of SO2 = 25.7 kJ/mole Specific heat capacity for liquid SO2 = 0.995 J/(mole⋅oC) Specific heat capacity for gas SO2 = 0.622 J/(mole⋅oC) Group of answer choices 150.8 kJ 86.2 kJ 1.34 kJ 1.00 kJ 5.49 kJ
Use the following data to calculate the total heat in kJ to convert 2.50 g solid sulfur dioxide at -73.0 oC to a gas at a temperature of 60.0 oC. Melting point of SO2 = -73.0 oC Boiling point of SO2 = -10.0 oC ΔHfusion of SO2 = 8.62 kJ/mole ΔHvaporization of SO2 = 25.7 kJ/mole Specific heat capacity for liquid SO2 = 0.995 J/(mole⋅oC) Specific heat capacity for gas SO2 = 0.622 J/(mole⋅oC) Group of answer choices 150.8 kJ 86.2 kJ 1.34 kJ 1.00 kJ 5.49 kJ
Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Chapter1: Introduction
Section: Chapter Questions
Problem 1.1P
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Use the following data to calculate the total heat in kJ to convert 2.50 g solid sulfur dioxide at -73.0 oC to a gas at a temperature of 60.0 oC.
Melting point of SO2 = -73.0 oC
Boiling point of SO2 = -10.0 oC
ΔHfusion of SO2 = 8.62 kJ/mole
ΔHvaporization of SO2 = 25.7 kJ/mole
Specific heat capacity for liquid SO2 = 0.995 J/(mole⋅oC)
Specific heat capacity for gas SO2 = 0.622 J/(mole⋅oC)
Group of answer choices
150.8 kJ
86.2 kJ
1.34 kJ
1.00 kJ
5.49 kJ
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