Use the References to access important values if needed for this question. In the laboratory a "coffee cup" calorimeter, or constant pressure calorimeter, is frequently used to determine the specific heat of a solid, or to measure the energy of a solution phase reaction. A student heats 62.01 grams of titanium to 98.99 °C and then drops it into a cup containing 85.26 grams of water at 21.36 °C. She measures the final temperature to be 28.02 °C. The heat capacity of the calorimeter (sometimes referred to as the calorimeter constant) was determined in a separate experiment to be 1.89 J/°C. Assuming that no heat is lost to the surroundings calculate the specific heat of titanium. Specific Heat (Ti) · J/g°C.

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Use the References to access important values if needed for this question. In the laboratory a "coffee cup" calorimeter, or constant pressure calorimeter, is frequently used to determine the specific heat of a solid, or to measure the energy of a solution phase reaction. Thermometer Stirring rod A student heats 62.01 grams of titanium to 98.99 °C and then drops it into a cup containing 85.26 grams of water at 21.36 °C. She measures the final temperature to be 28.02 °C. The heat capacity of the calorimeter (sometimes referred to as the calorimeter constant) was determined in a separate experiment to be 1.89 J/°C. Water Assuming that no heat is lost to the surroundings calculate the specific heat of titanium. Metal sample J/g°C. e2000 Thomaon-BroksCole Specific Heat (Ti) =