Water - but strictly speaking a Specific Heat Capacity is more correct.
Metals typically have lower specific heat capacities compared to liquids. This means that metals heat up and cool down faster than liquids when exposed to the same amount of heat. Liquids have higher specific heat capacities, so they can absorb or release more heat before their temperature changes significantly.
The temperature drop varies among liquids due to differences in their specific heat capacities. Liquids with higher specific heat capacities require more energy to change their temperature, resulting in a smaller temperature drop when heat is removed. Conversely, liquids with lower specific heat capacities exhibit larger temperature drops when heat is extracted.
Metallic substances have higher specific heat capacities than nonmetallic substances because metallic bonds allow for more energy to be absorbed without a large increase in temperature. This means that metallic substances can store more heat energy per unit mass compared to nonmetallic substances.
The metal with the lowest specific heat capacity will experience the largest temperature change when the same amount of heat is added. This is because metals with lower specific heat capacities require less heat to raise their temperature compared to metals with higher specific heat capacities. Therefore, you should select the metal with the lowest specific heat capacity from the chart to determine which one will experience the largest temperature change.
Different substances have varied molar heat capacities. The molar heat capacity of a substance refers to the amount of heat energy needed to raise 1 mole of that substance by 1 degree Celsius.
Substances with a low specific heat capacity will experience the greatest increase in temperature when 100g of heat is added. This means that metals like copper or aluminum, which have low specific heat capacities, will increase in temperature the most compared to substances like water or sand which have higher specific heat capacities.
Because of large heat capacities temperature rise will be very low so large amount of heat can be stored.
Gold has the lowest specific heat capacity.
Murked It
Substances with high specific heat capacities require more energy to heat up a unit mass by 1 degree Celsius. Water has one of the highest specific heat capacities of common substances, meaning it requires a significant amount of energy to raise its temperature. Metals like lead and mercury, on the other hand, have lower specific heat capacities and require less energy to heat up.
Metals typically have lower specific heat capacities compared to liquids. This means that metals heat up and cool down faster than liquids when exposed to the same amount of heat. Liquids have higher specific heat capacities, so they can absorb or release more heat before their temperature changes significantly.
There is a formula in physics ΔQ=m*c*ΔT, where m is the mass of the substance you are heating, ΔQ is the heat you supply to the substance, c is the specific heat which has a different value for different substances and ΔT is the change in temperature. If your substances are different and they have the same mass then by supplying the same amount of heat the change in temperature will be different.
The temperature drop varies among liquids due to differences in their specific heat capacities. Liquids with higher specific heat capacities require more energy to change their temperature, resulting in a smaller temperature drop when heat is removed. Conversely, liquids with lower specific heat capacities exhibit larger temperature drops when heat is extracted.
To determine the final temperature of a system, you can use the principle of conservation of energy. This involves calculating the total heat gained or lost by each component in the system based on their initial temperatures and heat capacities. By equating the total heat gained to the total heat lost, you can solve for the final temperature of the system.
Materials with lower heat capacities and higher thermal conductivities typically warm up the fastest when heat is applied. This can include metals like copper or aluminum, which have low specific heat capacities and good thermal conductivity. Conversely, materials like water or concrete have higher heat capacities and warm up more slowly.
A substance with a high specific heat capacity is one that needs a lot of heat energy pumped into it in order to raise its temperature. Substances with relatively high specific heat capacities include water, rock, and potatoes.
Heat Capacity Ratio "C" is Zero for both Condensor & Evaporator