Statement-1 : When 1 gm of water at 100^...

Statement-1 : When `1 gm` of water at `100^(@)C` is converted to steam at `100^(@)C`, the internal energy of the system doesn't change.
Statement-2 : For `dU=nC_(v)dT`, if temperature of system remains constant, then `dU=0` i.e. internal energy remains constant.

Statement-1 is True, Statement-2 is True, Statement-2 is a correct explantion for Statement-1

Statement-1 is True, Statement-2 is True, Statement-2 is NOT a correct explantion for Statement-1

Statement-1 is True, Statement-2 is False

Statement-1 is False, Statement-2 is True.

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Statement-1 : When `1 gm` of water at `100^(@)C` is converted to steam at `100^(@)C`, the internal energy of the system doesn't change. Statement-2 : For `dU=nC_(v)dT`, if temperature of system remains constant, then `dU=0` i.e. internal energy remains constant.

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Statement-1 : When `1 gm` of water at `100^(@)C` is converted to steam at `100^(@)C`, the internal energy of the system doesn't change.
Statement-2 : For `dU=nC_(v)dT`, if temperature of system remains constant, then `dU=0` i.e. internal energy remains constant.