Yes it has! the specific heat of water at constant volume is given by
cV : Heat capacity at constant volume
cP : Heat capacity at constant pressure
: Thermal expansion coefficient
: Isothermal compressibility
: Density
Density Specific Volume Pressure Temperature Viscoisy Gas Constant Heat Specific
To calculate the volume of water boiled off, you need to know the initial volume of water, the heat input, the time it was heated, and the specific heat capacity of water. You can use the equation Q = mcΔT, where Q is the heat energy, m is the mass of water, c is the specific heat capacity of water, and ΔT is the change in temperature. Once you have the heat energy, you can convert it to volume using the density of water.
No, water splashing out of the calorimeter will not affect the specific heat of the metal. The specific heat of a substance is an intrinsic property that remains constant regardless of the environment.
Another way of stating this, is that the volume-specific heat capacity (volumetric heat capacity) of solar elements is roughly constant. The molar volume of the solid.
Xenon, a noble gas, has a specific heat capacity of approximately 0.159 J/g·K at constant pressure (Cp) and about 0.124 J/g·K at constant volume (Cv). This means it requires 0.159 joules of energy to raise the temperature of one gram of xenon by one Kelvin under constant pressure conditions. Its relatively low specific heat reflects its status as a heavy and inert gas.
This is the necessary heat to raise the temprataure of 1 mol with 1 kelvin, at constant volume.
Density Specific Volume Pressure Temperature Viscoisy Gas Constant Heat Specific
c = specific heat .16902 = air at constant volume (since the cylinder size stays the same) 1.405 = specific heat of air at constant pressure divided by specific heat of air at constant volume *pressure doesn't necessarily stay constant as cylinder could be air compressor so c= 0.16902 (1.3-1.405/1.3-1) c= 0.169024 (-0.105/.3) c= 0.169024 (-0.35) c= -0.059158 or -0.059
Specific heat capacity at constant pressure (cp) is used for gases because the heat transfer is generally at constant pressure conditions. For solids, heat transfer typically occurs at constant volume since solids do not easily change their volume. Therefore, the specific heat capacity at constant volume (cv) is used for solids in heat transfer calculations.
For gases, there is heat specific heat capacity under the assumption that the volume remains constant, and under the assumption that the pressure remains constant. The reason the values are different is that when heating up a gas, in the case of constant pressure it requires additional energy to expand the gas. For solids and liquids, "constant volume" isn't used, since it would require a huge pressure to maintain the constant volume.
The adiabatic index of liquid water is about 4/3 or 1.33. This value represents the ratio of specific heat at constant pressure to specific heat at constant volume. Different liquids may have slightly different adiabatic indices depending on their molecular structure and interactions.
The value of the specific heat ratio (gamma) in air is approximately 1.4 at room temperature. It represents the ratio of specific heats, which is the ratio of the heat capacity at constant pressure to the heat capacity at constant volume.
The specific heat at constant pressure is larger than the molar specific heat at constant volume because if heat is added to a system it not only heats up but expands in volume. Therefore the system is doing work against the external pressure and the heat is not only stored as kinetic and potential energy but is also required to perform work. In general more heat can be stored in a system at constant pressure than one at constant volume. The specific heat at constant pressure is larger than the molar specific heat at constant volume because if heat is added to a system it not only heats up but expands in volume. Therefore the system is doing work against the external pressure and the heat is not only stored as kinetic and potential energy but is also required to perform work. In general more heat can be stored in a system at constant pressure than one at constant volume.
The specific heat at constant volume for a diatomic gas is typically 5R/2. The specific heat ratio, or gamma (γ), is defined as the ratio of the specific heat at constant pressure to the specific heat at constant volume. Therefore, for a diatomic gas with (C_v = \frac{5R}{2}), the gamma will be (\gamma = \frac{C_p}{C_v} = \frac{7R/2}{5R/2} = \frac{7}{5}) or 1.4.
To calculate the volume of water boiled off, you need to know the initial volume of water, the heat input, the time it was heated, and the specific heat capacity of water. You can use the equation Q = mcΔT, where Q is the heat energy, m is the mass of water, c is the specific heat capacity of water, and ΔT is the change in temperature. Once you have the heat energy, you can convert it to volume using the density of water.
Specific heat has nothing to do with specific volume.
The specific heat of water is greater than the specific heat of air.