If a certain mass of water falls a distance of 50.0 meters and all the energy...

Assuming that all the energy of the water is converted to heat, calculate the temperature rise...

Assuming that all the energy of the water is converted to heat, calculate the temperature rise of the water in degrees Celsius after falling over California'a Yosemite Falls, a distance of 739 m. Potential energy of the water at the top of the falls is equal to mass of the water times the acceleration due to gravity times the height. 1 kg m2/s2 is equal to _____ Joule. Assume 1.00 kg of water falling over Yosemite. The change in potential...

The potential energy stored in a spring is 1/2kx2, where k is the force constant of...

The potential energy stored in a spring is 1/2kx2, where k is the force constant of the spring and x is the distance the spring is stretched from equilibrium. Suppose a spring with force constant 300 N/m is stretched by 10.0 cm, placed in 40 g of water in an adiabatic container, and released. The mass of the spring is 20 g, and its specific heat capacity is 0.30 cal/(g °C). The initial temperature of the water and the spring...

The potential energy stored in a spring is 1/2kx2, where k is the force constant of...

The potential energy stored in a spring is 1/2kx2, where k is the force constant of the spring and x is the distance the spring is stretched from equilibrium. Suppose a spring with force constant 150 N/m is stretched by 10.0 cm, placed in 10 g of water in an adiabatic container, and released. The mass of the spring is 20 g, and its specific heat capacity is 0.30 cal/(g °C). The initial temperature of the water and the spring...

A 40.0 g Ice Cube floats in 200.0 g of water in a 100.0 g copper...

A 40.0 g Ice Cube floats in 200.0 g of water in a 100.0 g copper cup! All are at a temperature of 0.000C. Then, a piece of lead at 98.00C is dropped into the cup, and the final equilibrium temperature is 12.00C. The specific heat of water and ice is 1.00 cal/g 0C, the specific heat of copper is 0.0924 cal/g 0C, the specific heat of lead is 0.0305 cal/g 0C, and the heat of fusion of ice is...

A rock of mass 0.309 kg falls from rest from a height of 23.4 m into...

A rock of mass 0.309 kg falls from rest from a height of 23.4 m into a pail containing 0.444 kg of water. The rock and water have the same initial temperature. The specific heat capacity of the rock is 1880 J/kg C°. Ignore the heat absorbed by the pail itself, and determine the rise in temperature of the rock and water in Celsius degrees.

A rock of mass 0.354 kg falls from rest from a height of 25.0 m into...

A rock of mass 0.354 kg falls from rest from a height of 25.0 m into a pail containing 0.438 kg of water. The rock and water have the same initial temperature. The specific heat capacity of the rock is 1880 J/kg C°. Ignore the heat absorbed by the pail itself, and determine the rise in temperature of the rock and water in Celsius degrees.

We have an unknown mass of liquid water at 30 ° C. It is heated by...

We have an unknown mass of liquid water at 30 ° C. It is heated by 18,000 calories and it produces the mixture: liquid water-water vapor. Water vapor is 40% of the mixture. The specific heat of liquid water is 1.00 cal / g ° C, and its latent heat of boiling is 539.7 cal / g. Determine the initial mass of liquid water.

We have an unknown mass of liquid water at 15 °C. It is heated by 15,000...

We have an unknown mass of liquid water at 15 °C. It is heated by 15,000 calories and its produces the mixture: liquid water-steam. Water vapor is 40% of the mixture. The specific heat of liquid water is 1.00 cal/g °C, and its latent heat of boiling is 539.7 cal/g. Determine the initial mass of liquid water.

In a constant-pressure calorimeter, 50.0 mL of 0.930 M H2SO4 was added to 50.0 mL of...

In a constant-pressure calorimeter, 50.0 mL of 0.930 M H2SO4 was added to 50.0 mL of 0.290 M NaOH. The reaction caused the temperature of the solution to rise from 21.88 °C to 23.86 °C. If the solution has the same density and specific heat as water (1.00 g/mL and 4.184 J/g·K, respectively), what is ΔH for this reaction (per mole of H2O produced)? Assume that the total volume is the sum of the individual volumes.

A mass falls x meters in t seconds. The same mass falls the last half this...

A mass falls x meters in t seconds. The same mass falls the last half this distance in 1 sec. What is t? Group of answer choices 2.42 s 6.84 s 3.41 s 0.505 s