Consider an isolated system containing two blocks of copper with equal mass. One block is initially...

Two copper blocks, each of mass 1.74 kg, initially have different temperatures,t1 = 18° C and...

Two copper blocks, each of mass 1.74 kg, initially have different temperatures,t1 = 18° C and t2 = 30° C. The blocks are placed in contact with each other and come to thermal equilibrium. No heat is lost to the surroundings. (a) Find the final temperature of the blocks. °C Find the heat transferred between them. J (b) Find the entropy change of each block during the time interval in which the first joule of heat flows. ?S1 = J/K...

Consider two blocks. The initial temperature of block 1 is 280 K and the initial temperature...

Consider two blocks. The initial temperature of block 1 is 280 K and the initial temperature of block 2 is 340 K. The heat capacities of blocks 1 and 2 are 400 J/K and 200 J/K, respectively. A. The two blocks are placed in thermal contact with one another but are perfectly insulated from the remainder of their surroundings. We will call the process that begins when the blocks are brought in contact with one another process A. Determine the...

A copper block of mass 17.5 kg initially at 481 K is immersed in 31.5 kg...

A copper block of mass 17.5 kg initially at 481 K is immersed in 31.5 kg of water initially at 298 K. CP,m(H2O,l)=75.3J⋅K−1⋅mol−1 CP,m(Cu,s)=24.4J⋅K−1⋅mol−1 Assume that the heat capacity of Cu remains constant at its 298.15 K value over the temperature interval of interest. 1) Calculate ΔS for the water. 2) Calculate ΔS for the Cu block.

Two solid bodies of equal mass and identical composition, isolated from the surroundings and each other...

Two solid bodies of equal mass and identical composition, isolated from the surroundings and each other and kept initially at temperature T1 and T2 are brought into thermal contact until they attain thermal equilibrium with each other. Compute the amount of entropy change of the universe in terms of T1, T2, and the heat capacity C_p of each body , assuming the process to take place at constant pressure exerted on them by the environment and show that the entropy...

A 50 kg copper block initially at 350 oC is quenched in a closed, rigid insulated...

A 50 kg copper block initially at 350 oC is quenched in a closed, rigid insulated tank containing 120 L of liquid water at 25 oC. Specific heat of copper, Cc = 385 J/(kgK), specific heat of liquid water, Cw = 4180J/(kgK). (i) Calculate the entropy change (kJ/K) of copper block. (ii) Determine the entropy change (kJ/K) of liquid water.

A block of copper has a mass of 100 kg and an initial temperature of 900...

A block of copper has a mass of 100 kg and an initial temperature of 900 K. Copper can be modeled as an incompressible substance with a specific heat capacity of 0.4 kJ/kg-K. a.) The copper block is dropped into a large lake at 300 K and allowed to come to thermal equilibrium. How much entropy is generated (kJ/K)? b.) If a reversible heat engine were connected between the lake and the copper block and operated until the temperature of...

A cooper block having a mass of 10 kg and at a temperature of 800 K...

A cooper block having a mass of 10 kg and at a temperature of 800 K is placed in a well-insulated vessel containing 100 kg of water initially at 290 K. Calculate: a) Calculate the entropy change for the block, the water, and the total process. b) What is the maximum amount of work that could have been obtained from the copper block and water in a Carnot engine? The heat capacities are 4.185 kJ/kg/K for water and 0.398 kJ/kg/K...

Please Show all work, thank you! A copper block with a mass of 400 grams is...

Please Show all work, thank you! A copper block with a mass of 400 grams is cooled to 77 K by being immersed in liquid nitrogen. The block is then placed in a Styrofoam cup containing some water that is initially at +50.0°C. Assume no heat is transferred to the cup or the surroundings. The specific heat of liquid water is 4186 J/(kg °C), of solid water is 2060 J/(kg °C), and of copper is 385 J/(kg °C). The latent...

Consider two blocks on a horizontal plane where block one has a small mass (m) with...

Consider two blocks on a horizontal plane where block one has a small mass (m) with some velocity (v) while block two has a large mass (M) and a spring with a spring constant of (k). Have block one collide with the spring of block two and stick so that the two blocks are allowed to oscillate. Ignore friction. 1) Find the internal energy change in the system 2) Now assume block two is instead an un-moving wall so that...