this is a stupid question.
For enthalpy to be equivalent to the total flow of heat, the process must occur at constant pressure. Under these conditions, the change in enthalpy (ΔH) directly corresponds to the heat added or removed from the system. If pressure changes, the relationship between enthalpy and heat transfer becomes more complex due to work done by or on the system.
The unit of heat equivalent to 4.184 joules is the calorie.
It is the ratio of room sensible heat to the total heat.
Netsu < sounds like "ne tzu" > is the equivalent word of " heat."
The temperature scale where 0 indicates a total lack of heat is the Kelvin scale. In this scale, 0 Kelvin (absolute zero) represents the theoretical point at which molecular motion ceases entirely, signifying no thermal energy. This is equivalent to -273.15 degrees Celsius and -459.67 degrees Fahrenheit.
-625 Degress Fahrenheit = -365 Degress Celcius unfortunately there is no such temperature... absolute zero or the total absence of heat is around -284 C
Temperature is a measure of the average kinetic energy of the particles in a substance, not the total heat energy. Heat energy is the total energy associated with the movement of particles in a substance. Temperature is one way to quantify the amount of heat energy present in a system, but it is not the same as measuring the total heat energy.
The total heat of steam, also known as enthalpy of steam, is the amount of heat required to raise the temperature of water to its boiling point and then convert it into steam without changing its temperature. It is the sum of sensible heat and latent heat of vaporization.
this is a stupid question.
It is the mechanical equivalent of heat.
Heat is the cause and temperature is the effect. Heat is energy but temperature is outcome of storage of such heat energy in a body. If same amount of heat is given to the same mass of water and aluminium, then temperature will be more in aluminium but less in water. This is similar to the collecting air in different containers. Air is equivalent to heat and pressure created is equivalent to temperature.
The total heat lost by the granite is greater than the total heat gained by the room-temperature water because granite has a higher specific heat capacity, allowing it to store and release more thermal energy as it cools. Additionally, the temperature difference between the granite and the water drives a more significant heat transfer, resulting in more heat being lost by the granite. This imbalance accounts for the greater heat loss from the granite compared to the heat gain experienced by the water.