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What is the work done during an isothermal compression?

What is the work done during an isothermal compression?

For an isothermal reversible process, Q=−w i.e. work done by the system equals the heat absorbed by the system.

When the gas expand isothermally the work is?

Isothermal Expansion This shows the expansion of gas at constant temperature against weight of an object’s mass (m) on the piston. Temperature is held constant, therefore the change in energy is zero (U=0). So, the heat absorbed by the gas equals the work done by the ideal gas on its surroundings.

Is work Positive in isothermal?

Explain. Since the expansion is isothermal and of an ideal gas, the change in internal energy is zero. This means q = -w and for a compression, w is positive.

What is gas compression?

Gas compression is done to increase the pressure of the gas, this is accompanied by change of state of the gas which means change in temperature and volume of a quantum of gas going under compression. Adiabatic compression: For gas compressors without any cooling, gas temperature rises with rise in pressure.

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What happens to the internal energy of a gas during isothermal expansion and adiabatic expansion?

(i) In isothermal expansion ,temperature remains constant. Therefore internal energy which is a function of temperature will remain constant. Thus ,in an adiabatic expansion , the internal energy of the system will decrease.

How do you calculate work done by a gas?

Pressure-volume work

  1. Work is the energy required to move something against a force.
  2. The energy of a system can change due to work and other forms of energy transfer such as heat.
  3. Gases do expansion or compression work following the equation: work = − P Δ V \text {work} = -\text P\Delta \text V work=−PΔV.

What happens to work when an ideal gas expands reversibly and isothermally?

If the external pressure becomes equal to the pressure of the gas, there will be no change in the volume and thus ΔV = 0. The work done is also zero. Therefore work done in an isothermal reversible expansion of an ideal gas is maximum work.

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When a gas expands adiabatically what happens?

When an ideal gas is compressed adiabatically (Q=0), work is done on it and its temperature increases; in an adiabatic expansion, the gas does work and its temperature drops.

Is work done by gas positive?

The work done by a gas expanding against an external pressure is therefore negative, corresponding to work done by a system on its surroundings. Conversely, when a gas is compressed by an external pressure, ΔV < 0 and the work is positive because work is being done on a system by its surroundings.

Why is work done by gas negative?

When the gas expands against an external pressure, the gas has to transfer some energy to the surroundings. Thus, the negative work decreases the overall energy of the gas. When the gas is compressed, energy is transferred to the gas so the energy of the gas increases due to positive work.

What happens when a gas is compressed isothermally?

A gas is compressed isothermally to half its initial volume. The same gas is compressed separately through an adiabatic process until its volume is again reduced to half. Then. compressing the gas isothermally will require more work to be done.

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What is the work done on a gas when it is compressed?

On the other hand, if the gas is compressed, the work is done on the gas and is therefore negative. The work done for isothermal compression is given by, W = -2.3026 RT log10 (V2/V1) So, W =2.3026 RT log10 (V1/V2)

What is the value of H for isothermal compression?

The work done for isothermal compression is given by, W = -2.3026 RT log10 (V2/V1) So, W =2.3026 RT log10 (V1/V2) Therefore, H = 2.3026 (RT/J) log10 (V1/V2)

What is the work done of n moles in isothermal expansion?

From the above observation we conclude that, the work done of n moles of a van der Walls gas in an isothermal expansion from volume Vi to Vf would be (- nRT ln Vf –nb/ Vi –nb) –an2(1/Vf- 1/Vi). A quantity of ideal gas occupies an initial volume V0at a pressure p0 and a temperature T0.