Lets say we have a tank with a fixed mass of liquid at atmospheric pressure and room temperature. How do we influence the temperature when we exert pressure (e. g., with a piston) on the liquid? Are pressure-enthalpy diagrams the key for that question?

EDIT: If it is incompressible, temperature would not change, since the applied force does no work, right? Somehow this collides with my understanding of the microscopic realm, since I associate higher pressure with more microscopic movement and more energy per particle.

Lets say we have a tank with a fixed mass of liquid at atmospheric pressure and room temperature. How do we influence the temperature when we exert pressure (e. g., with a piston) on the liquid? Are pressure-enthalpy diagrams the key for that question?

If it is incompressible, temperature would not change, since the applied force does no work, right?

Somehow this collides with my understanding of the microscopic realm, since I associate higher pressure with more microscopic movement and more energy per particle.

Lets say we have a tank with a fixed mass of liquid at atmospheric pressure and room temperature. How do we influence the temperature when we exert pressure (e. g., with a piston) on the liquid? Are pressure-enthalpy diagrams the key for that question?

Lets say we have a tank with a fixed mass of liquid at atmospheric pressure and room temperature. How do we influence the temperature when we exert pressure (e. g., with a piston) on the liquid? Are pressure-enthalpy diagrams the key for that question?

EDIT: If it is incompressible, temperature would not change, since the applied force does no work, right? Somehow this collides with my understanding of the microscopic realm, since I associate higher pressure with more microscopic movement and more energy per particle.