The heat capacity at constant volume of hydrogen sulfide at low pressures is given by Eq. Q1-1: Co[kJ/(mol-°C)] 0.0252 + 1.547 × 10-T – 3.012 × 10-9T? Eq. Q1-1 %3D ........ Where, Tis temperature in °C. A quantity of H2S is kept in a piston-fitted cylinder with initial temperature, pressure, and volume equal to 25°C, 2.0 atm, and 3.0 liters, respectively. i- Calculate the heat (kJ) required to raise the gas temperature from 25°C to 1000°C, if the heating takes place at constant volume (i.e., if the piston does not move). ii- For a closed system at constant pressure with negligible kinetic and potential energy changes, the specific heat is determined by Eq. Q1-2: Cp = Cy + 0 008314 Eq. Q1-2 calculate the heat (J) required to raise the gas from 25°C to 1000°C at constant pressure. What would the piston do during this process? Given the gas constant = 0 08206 atm. Lit/ (mol. K)
The heat capacity at constant volume of hydrogen sulfide at low pressures is given by Eq. Q1-1: Co[kJ/(mol-°C)] 0.0252 + 1.547 × 10-T – 3.012 × 10-9T? Eq. Q1-1 %3D ........ Where, Tis temperature in °C. A quantity of H2S is kept in a piston-fitted cylinder with initial temperature, pressure, and volume equal to 25°C, 2.0 atm, and 3.0 liters, respectively. i- Calculate the heat (kJ) required to raise the gas temperature from 25°C to 1000°C, if the heating takes place at constant volume (i.e., if the piston does not move). ii- For a closed system at constant pressure with negligible kinetic and potential energy changes, the specific heat is determined by Eq. Q1-2: Cp = Cy + 0 008314 Eq. Q1-2 calculate the heat (J) required to raise the gas from 25°C to 1000°C at constant pressure. What would the piston do during this process? Given the gas constant = 0 08206 atm. Lit/ (mol. K)
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
Problem 1.1MA
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Question
![Q1)
The heat capacity at constant volume of hydrogen sulfide at low pressures is given by Eq. Q1-1:
Co[kJ/(mol•°C)]
= 0.0252 + 1.547 × 10-T – 3.012 × 10-9T²
Eq. Q1-1
........
Where, Tis temperature in °C.
A quantity of H2S is kept in a piston-fitted cylinder with initial temperature, pressure, and
volume equal to 25°C, 2.0 atm, and 3.0 liters, respectively.
i- Calculate the heat (kJ) required to raise the gas temperature from 25°C to 1000°C, if the
heating takes place at constant volume (i.e., if the piston does not move).
ii- For a closed system at constant pressure with negligible kinetic and potential energy changes,
the specific heat is determined by Eq. Q1-2:
Cp
= Cy + 0 008314
Eq. Q1-2
calculate the heat (J) required to raise the gas from 25°C to 1000°C at constant
pressure.
What
would the piston do during this process?
Given the gas constant = 0 08206 atm. Lit/ (mol. K)](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F8d3eaef6-a95a-4504-ad29-66e7b74a735e%2F210de5e0-7145-4ef8-b4ea-0287b55e2fc1%2F9ho1es_processed.jpeg&w=3840&q=75)
Transcribed Image Text:Q1)
The heat capacity at constant volume of hydrogen sulfide at low pressures is given by Eq. Q1-1:
Co[kJ/(mol•°C)]
= 0.0252 + 1.547 × 10-T – 3.012 × 10-9T²
Eq. Q1-1
........
Where, Tis temperature in °C.
A quantity of H2S is kept in a piston-fitted cylinder with initial temperature, pressure, and
volume equal to 25°C, 2.0 atm, and 3.0 liters, respectively.
i- Calculate the heat (kJ) required to raise the gas temperature from 25°C to 1000°C, if the
heating takes place at constant volume (i.e., if the piston does not move).
ii- For a closed system at constant pressure with negligible kinetic and potential energy changes,
the specific heat is determined by Eq. Q1-2:
Cp
= Cy + 0 008314
Eq. Q1-2
calculate the heat (J) required to raise the gas from 25°C to 1000°C at constant
pressure.
What
would the piston do during this process?
Given the gas constant = 0 08206 atm. Lit/ (mol. K)
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