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An electric coffee maker has a heating element that operates at 120 V and with a current of 2.00 A. Assuming the water absorbs all the energy delivered to the heating element, calculate the time interval (in s) during which the temperature of 0.419 kg of water rises from room temperature (23.0∘C) to the boiling point. (The specific heat of water is 4, 186 J/(kg⋅∘C).)

An electric coffee maker has a heating element that operates at 120 V and with a current of 2.00 A. Assuming the water absorbs all the energy delivered to the heating element, calculate the time interval (in s) during which the temperature of 0.419 kg of water rises from room temperature (23.0∘C) to the boiling point. (The specific heat of water is 4, 186 J/(kg⋅∘C).)

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An electric coffee maker has a heating element that operates at 120 V and with a current of 2.00 A . Assuming the water absorbs all the energy delivered to the heating element, calculate the time interval (in s) during which the temperature of 0.419 k g of water rises from room temperature ( 23.0 C ) to the boiling point. (The specific heat of water is 4 , 186 J / ( k g C ) . )

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