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Physics-

General

Easy

Question

A cyclic process ABCD is shown in the figure P-V diagram. Which of the following curves represent the same process

The correct answer is:

AB is isobaric process, BC is isothermal process, CD is isometric process and DA is isothermal process
These process are correctly represented by graph (a)

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A cyclic process for 1 mole of an ideal gas is shown in figure in the V-T, diagram. The work done in AB, BC and CA respectively

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In the following indicator diagram, the net amount of work done will be

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An ideal gas is taken through the cycle A ® B ® C ® A, as shown in the figure. If the net heat supplied to the gas in the cycle is 5 J, the work done by the gas in the process C → A is

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The P-V diagram of a system undergoing thermodynamic transformation is shown in figure. The work done on the system in going from A ® B ® C is 50 J and 20 cal heat is given to the system. The change in internal energy between A and C is

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In pressure-volume diagram given below, the isochoric, isothermal, and isobaric parts respectively, are

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Four curves A, B, C and D are drawn in the adjoining figure for a given amount of gas. The curves which represent adiabatic and isothermal changes are

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A thermodynamic process is shown in the figure. The pressures and volumes corresponding to some points in the figure are : $P subscript A end subscript equals 3 cross times 1 0 to the power of 4 end exponent P a comma P subscript B end subscript equals 8 cross times 1 0 to the power of 4 end exponent P a$ and $V subscript A end subscript equals 2 cross times 1 0 to the power of negative 3 end exponent m to the power of 3 end exponent comma V subscript D end subscript equals 5 cross times 1 0 to the power of negative 3 end exponent m to the power of 3 end exponent$
In process AB, 600 J of heat is added to the system and in process BC, 200 J of heat is added to the system. The change in internal energy of the system in process AC would be

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In process AB, 600 J of heat is added to the system and in process BC, 200 J of heat is added to the system. The change in internal energy of the system in process AC would be

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An ideal gas of mass m in a state A goes to another state B via three different processes as shown in figure. If $Q subscript 1 end subscript comma Q subscript 2 end subscript$ and $Q subscript 3 end subscript$ denote the heat absorbed by the gas along the three paths, then

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The P-V diagram shows seven curved paths (connected by vertical paths) that can be followed by a gas. Which two of them should be parts of a closed cycle if the net work done by the gas is to be at its maximum value

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A system goes from A to B via two processes I and II as shown in figure. If $capital delta U subscript 1 end subscript$ and $capital delta U subscript 2 end subscript$ are the changes in internal energies in the processes I and II respectively, then

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A cylindrical tube of uniform cross-sectional area A is fitted with two air tight frictionless pistons. The pistons are connected to each other by a metallic wire. Initially the pressure of the gas is P₀ and temperature is T₀, atmospheric pressure is also P₀. Now the temperature of the gas is increased to 2T₀, the tension in the wire will be

A cylindrical tube of uniform cross-sectional area A is fitted with two air tight frictionless pistons. The pistons are connected to each other by a metallic wire. Initially the pressure of the gas is P₀ and temperature is T₀, atmospheric pressure is also P₀. Now the temperature of the gas is increased to 2T₀, the tension in the wire will be

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The shaded region in the figure represents

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The rectangle box shown in fig has a partition which can slide without friction along the length of the box. Initially each of the two chambers of the box has one mole of monatomic ideal gas ( $gamma$ =5/(c) at a pressure $P subscript 0 end subscript$ , volume $V subscript 0 end subscript$ and temperature $T subscript 0 end subscript$ . The chamber on the left is slowly heated by an electric heater. The walls of the box and the partition are thermally insulated. The gas in the left chamber expands, pushing the partition until the final pressure in both chambers becomes (243/3(b) $P subscript 0 end subscript$ . The final temperature of the gas in left chamber is:

The rectangle box shown in fig has a partition which can slide without friction along the length of the box. Initially each of the two chambers of the box has one mole of monatomic ideal gas ( $gamma$ =5/(c) at a pressure $P subscript 0 end subscript$ , volume $V subscript 0 end subscript$ and temperature $T subscript 0 end subscript$ . The chamber on the left is slowly heated by an electric heater. The walls of the box and the partition are thermally insulated. The gas in the left chamber expands, pushing the partition until the final pressure in both chambers becomes (243/3(b) $P subscript 0 end subscript$ . The final temperature of the gas in left chamber is:

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