A certain monatomic gas has specific heat cV = 0.0356 kcal/kg⋅C∘, which changes little over a...

The heat capacity at constant volume of a certain amount of a monatomic gas is 53.7...

The heat capacity at constant volume of a certain amount of a monatomic gas is 53.7 J/K. (a) Find the number of moles of the gas. in mol (b) What is the internal energy of the gas at T = 286 K? in kJ (c) What is the heat capacity of the gas at constant pressure? in J/k

1. A flask holds 9.73 kg of a monatomic ideal gas (mass number 86.4). If the...

1. A flask holds 9.73 kg of a monatomic ideal gas (mass number 86.4). If the gas changes temperature isochorically (constant volume) from temperature 802o C to 376o C, find the change in the internal energy of the gas, in kJ. A positive answer means the internal energy increased; a negative answer means the internal energy decreased.   2. A flask holds 2.25 kg of a diatomic ideal gas (mass number of the gas 92.1). If the gas changes temperature isochorically...

A 2.0 mol sample of ideal gas with molar specific heat Cv = (5/2)R is initially...

A 2.0 mol sample of ideal gas with molar specific heat Cv = (5/2)R is initially at 300 K and 100 kPa pressure. Determine the final temperature and the work done on the gas when 1.6 kJ of heat is added to the gas during each of these separate processes (all starting at same initial temperature and pressure: (a) isothermal (constant temperature) process, (b) isometric (constant volume) process, and (c) isobaric (constant pressure) process. Hint: You’ll need the 1st Law...

28 moles of an ideal gas with a molar specific heat at constant volume of cv=3.2R...

28 moles of an ideal gas with a molar specific heat at constant volume of cv=3.2R is initially in state "A" at pressure 73390 Pa and volume 1.0 m3. The gas then expands isobarically to state "B" which has volume 2.6?3m3. The gas then cools isochorically to state "C". The gas finally returns from state "C" to "A" via an isothermal process. What is the adiabatic constant γ for this gas? What is Q during the expansion from "A" to...

A typical human has a mass of 70 kg and produces about 2000 kcal of metabolic...

A typical human has a mass of 70 kg and produces about 2000 kcal of metabolic heat per day. Find the rate of heat production in watts and in calories per hour. If none of the metabolic heat were lost, and assuming that the specific heat of the human body is 1.0 cal/g·°C, find the rate at which the body temperature would rise (°C per hour).

You have 1.3 moles of a fictitious ideal gas whose molar specific heat values are Cv...

You have 1.3 moles of a fictitious ideal gas whose molar specific heat values are Cv = 13.43 J/(mol·K) and Cp = 21.74 J/(mol·K). The gas is heated from T = 26.5 °C to T = 120.7 °C at a constant volume of 0.0306 m3 1. How much work is done by the gas? 2. How much thermal energy (heat) flows into the gas? 3. What is the change in the internal energy of the gas?

8.33 kg of steam at temperature of 150 ∘C has 2.23×107 J of heat removed from...

8.33 kg of steam at temperature of 150 ∘C has 2.23×107 J of heat removed from it. Determine the final temperature and phase of the result once the heat has been removed if the heat is removed at constant pressure during the gas phase. For this problem, use the specific heat (at constant pressure) for water as 1850 J/kg∘C , the latent heat of vaporization as 2.256×106 J/kg , the specific heat of liquid water as 4186 J/kg∘C , the...

The specific heat of a certain type of cooking oil is 1.75 J/(g·°C). How much heat...

The specific heat of a certain type of cooking oil is 1.75 J/(g·°C). How much heat energy is needed to raise the temperature of 2.62 kg of this oil from 23 °C to 191 °C?

A 0.250-kg aluminum bowl holding 0.800 kg of soup at 26.2°C is placed in a freezer....

A 0.250-kg aluminum bowl holding 0.800 kg of soup at 26.2°C is placed in a freezer. What is the final temperature if 428 kJ of energy is transferred from the bowl and soup? Assume the soup has the same thermal properties as that of water, the specific heat of the liquid soup is 1.00 kcal/(kg · °C), frozen soup is 0.500 kcal/(kg · °C), and the latent heat of fusion is 79.8 kcal/kg. The specific heat of aluminum is 0.215...

Consider a mole of an ideal monatomic gas, Xe, inside a container with rigid walls. The...

Consider a mole of an ideal monatomic gas, Xe, inside a container with rigid walls. The ideal gas is heated up as a flame is applied to the container’s exterior. The molar mass of Xe is 0.131 kg. The gas does not transfer any heat to the container. Answer the following questions. A.) Before the flame is lit, the pressure of the gas inside the container is 10.1x10^5 Pa and the temperature of the gas is 295 K. If at...