what is the density (g/mL) of the irregular solid of weight 66.2 grams, if the initial...
A solid has a mass of 21.15 grams and a density of 1.688 g/mL. The solid is dropped into a graduated cylinder containing water with volume of 15.00 mL. When the solid is dropped into the graduated cylinder, the volume of the water goes up. Using the information given, calculate the final volume of the water in the graduated cylinder.
Given the following information, calculate the density in g/mL of an irregular solid. Mass of weighing vessel 1.005g Mass of solid + weighing vessel 9.441g Volume of liquid in graduated cylinder 3.45 mL Volume of liquid in graduated cylinder + volume of solid 5.15 mL
An irregular lump of an unknown metal has a measured density of 5.33 g/mL. The metal is heated to a temperature of 157 °C and placed in a graduated cylinder filled with 25.0 mL of water at 25.0°C. After the system has reached thermal equilibrium, the volume in the cylinder is read at 33.7 mL, and the temperature is recorded as 37.8 °C. What is the specific heat of the unknown metal sample? Assume no heat is lost to the...
An irregular lump of an unknown metal has a measured density of 5.92 g/mL. The metal is heated to a temperature of 191 °C and placed in a graduated cylinder filled with 25.0 mL of water at 25.0 °C. After the system has reached thermal equilibrium, the volume in the cylinder is read at 34.3 mL, and the temperature is recorded as 40.8 °C. What is the specific heat of the unknown metal sample? Assume no heat is lost to...
An irregular lump of an unknown metal has a measured density of 4.51 g/mL. The metal is heated to a temperature of 171 °C and placed in a graduated cylinder filled with 25.0 mL of water at 25.0 °C. After the system has reached thermal equilibrium, the volume in the cylinder is read at 30.2 mL, and the temperature is recorded as 47.7 °C. What is the specific heat of the unknown metal sample? Assume no heat is lost to...
An irregular lump of an unknown metal has a measured density of 3.05 g/mL. The metal is heated to a temperature of 175 °C and placed in a graduated cylinder filled with 25.0 mL of water at 25.0 °C. After the system has reached thermal equilibrium, the volume in the cylinder is read at 31.4 mL, and the temperature is recorded as 43.8 °C. What is the specific heat of the unknown metal sample? Assume no heat is lost to...
An irregular lump of an unknown metal has a measured density of 4.04 g/mL. The metal is heated to a temperature of 161 °C and placed in a graduated cylinder filled with 25.0 mL of water at 25.0 °C. After the system has reached thermal equilibrium, the volume in the cylinder is read at 34.1 mL, and the temperature is recorded as 45.2 °C. What is the specific heat of the unknown metal sample? Assume no heat is lost to...
An irregular lump of an unknown metal has a measured density of 5.39 g/mL. The metal is heated to a temperature of 159 °C and placed in a graduated cylinder filled with 25.0 mL of water at 25.0 °C. After the system has reached thermal equilibrium, the volume in the cylinder is read at 30.1 mL, and the temperature is recorded as 47.6 °C. What is the specific heat of the unknown metal sample? Assume no heat is lost to...
An irregular lump of an unknown metal has a measured density of 3.84 g/mL. The metal is heated to a temperature of 161 °C and placed in a graduated cylinder filled with 25.0 mL of water at 25.0 °C. After the system has reached thermal equilibrium, the volume in the cylinder is read at 33.7 mL, and the temperature is recorded as 37.4 °C. What is the specific heat of the unknown metal sample? Assume no heat is lost to...
An irregular lump of an unknown metal has a measured density of 3.19 g/mL. The metal is heated to a temperature of 153°C and placed in a graduated cylinder filled with 25.0mL of water at 25.0°C. After the system has reached thermal equilibrium, the volume in the cylinder is read at 30.0mL, and the temperature is recorded as 37.1°C. What is the specific heat of the unknown metal sample? Assume no heat is lost to the surroundings. c=_____________J/g*C