At the boiling point the energy goes into breaking the intermolecular bonds, but the average kinetic energy stays constant and so does the temperature until all of the bonds are broken and the substance is in the vapor state.
it is good accurate and high dimintional
At engineering level technically both process are same except there definition both process give hyperbolic curve in P-V diagram and straight line in T-S diagram. and even in polytropic process PV^n=constant if n=1 then it is not hyperbolic process it is isothermal process even though the definition says pv=c is hyperbolic process.
no, a Carnot cycle is not practiclly possible.bcz carnot consist of two cycles. i.e 1-rev. adiabatic 2-isothermal
The solution of the equation.
It is the LODMAT, Lowest One Day Mean Ambient Temperature, (API 650, Figure 4.2) plus 15 degrees F. The LODMAT figure is a map of the USA and it has Isothermal lines on it indicating temperatures for different locations.
The process equation for this is PV up to the nth power which equals C. The polytrophic process is 1.25 which is the n in the equation.
No, an isothermal process is not necessarily internally reversible.
The equation that relates the change in entropy (S) to the temperature (T), volume (V), and ideal gas constant (R) in a reversible isothermal process is S q / T.
An isobaric process is when pressure remains constant, while an isothermal process is when temperature remains constant in thermodynamics.
An isothermal PV diagram illustrates a thermodynamic process where the temperature remains constant.
Isothermal process is a process in which change in pressure and volume takes place at a constant temperature.
An isothermal process in thermodynamics is when the temperature remains constant, while an isobaric process is when the pressure remains constant.
In an isothermal process, the internal energy of a system remains constant because the temperature does not change. This means that the relationship between internal energy and temperature is that they are directly proportional in an isothermal process.
An isothermal process is one which does not take in or give off heat; it is perfectly insulated. Iso = same, thermal = heat. In real life there are very few isothermal processes. Heat loss accounts for most process inefficiencies.
In thermodynamics, the key difference between an adiabatic and isothermal graph is how heat is transferred. In an adiabatic process, there is no heat exchange with the surroundings, while in an isothermal process, the temperature remains constant throughout the process.
Temperature is constant during an isothermal process. The work done (W) is equal to the heat added (Q). The change in internal energy (ΔU) is zero for an isothermal process. The pressure can vary during an isothermal process, depending on the specific conditions.
The process is known as an isothermal process. In an isothermal process, the energy transferred to the gas as heat and work results in no change in the gas's internal energy because the temperature remains constant throughout the process.