Subjective Type

Figure shows a process on a gas in which pressure and volume both change.The molar heat capacity for this process is C

Solution

SIMILAR QUESTIONS

Thermodynamics

The molar heat capacity of oxygen gas at STP is nearly 2.5 R. As the temperature is increased, it gradually increases and approaches 3.5 R. The most appropriate reason for this behaviour is that at high temperature :

Thermodynamics

The ratio of specific heat capacity to molar heat capacity of a body

Thermodynamics

Two moles of an ideal gas at a temperature of $$T=273\ K$$ was isothermally expanded $$4$$ times the initial volume and then heated isochorically, so that the final pressure becomes equal to the initial pressure. The ratio of molar specific heat capacities if total amount of heat imparted to the gas equals $$Q=27.7\ kJ$$, is

Thermodynamics

Molar heat capacity is directly related to :

Thermodynamics

In an industrial process the volume of $$25.0$$ mol of a monoatomic ideal gas is reduced at a uniform rate from $$0.616\ m^3$$ to $$0.308\ m^3$$ in $$2.00\ h$$ while its temperature is increased at a uniform rate from $$27.0^oC$$ to $$450^oC$$. Through out the process, thegas passes through thermodyamic equilibrium states. What are the molar specific heat for the process? $$\displaystyle \int \dfrac {a+bx}{A+Bx}dx=\dfrac {bx}{B}+\dfrac {aB-bA}{B^2}\ln (A+Bx)$$ an indefinite integral. Suppose is replaced with a two step process that reaches the same final state. In step $$1$$, the gas volume is reduced at constant temperature, and in step $$2$$ the temperature is increased at constant volume. For this process,

Thermodynamics

In an industrial process the volume of $$25.0$$ mol of a monoatomic ideal gas is reduced at a uniform rate from $$0.616\ m^3$$ to $$0.308\ m^3$$ in $$2.00\ h$$ while its temperature is increased at a uniform rate from $$27.0^oC$$ to $$450^oC$$. Through out the process, thegas passes through thermodyamic equilibrium states. What are the molar specific heat for the process? $$\displaystyle \int \dfrac {a+bx}{A+Bx}dx=\dfrac {bx}{B}+\dfrac {aB-bA}{B^2}\ln (A+Bx)$$ an indefinite integral. Suppose is replaced with a two step process that reaches the same final state. In step $$1$$, the gas volume is reduced at constant temperature, and in step $$2$$ the temperature is increased at constant volume. For this process,

Thermodynamics

Air at $$0.000^oC$$ and $$1.00$$ atm pressure has a density of $$1.29\times10^{-3} g/ cm^3$$, and the speed of sound is $$331\ m/s$$ at that temperature. Compute the ratio $$\gamma $$ of the molar specific heats of air.

Thermodynamics

A certain substance has a mass per mole of $$50.0\ mol$$. When $$314\ J$$ is added to a $$30.0\ g$$ sample, the sample's temperature rises from $$25.0^oC$$ to $$45.0^oC$$. What are the molar specific heat of this substance?

Thermodynamics

Specific heat depends on __________, ____________ and ___________.

Thermodynamics

State whether true or false : The substance with more specific heat has greater ability to store heat.

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