Without heat from the sun the water cycle would not work .
Energy in the water cycle refers to heat from the sun, which powers the whole cycle, in particular the movement of water from oceans into the atmosphere (evaporation).
The sun is the primary heat source that powers the water cycle in nature. Solar energy causes water to evaporate from oceans, lakes, and rivers, forming clouds. When the clouds cool, the water vapor condenses and falls back to Earth as precipitation, completing the water cycle.
Evaporation is the first step of water cycle. In this process water gets evaporated by the action of sun's heat.
The global water cycle is the most efficient in heat transferring, as water has a high heat capacity and can absorb and release large amounts of heat. This cycle involves the continuous movement of water between the Earth's surface, the atmosphere, and back again through processes like evaporation, condensation, and precipitation, helping to regulate Earth's temperature.
In dual combustion cycle heat is added at constant volume which increases the efficiency of cycle, whereas heat addition at constant pressure limits the maximum pressure of the cycle.
Without heat from the sun the water cycle would not work .
the difference is the heat addition type In Otto Cycle the heat addition is Isochoric ((constant volume)) In Diesel Cycle the heat addition is Isobaric ((constant pressure))
The water cycle transfers heat in the form of liquid.
metamorphic rock
Possibly metamorphism.
No evaporation will take place. Water cycle won't continue.
Pressure increases due to load(or heat intake from evaps).if asking about off cycle. If asking about compression cycle,its the compression of vapor into a higher pressure side of system along with heat of compression adding to temp-pressure relationship.
The vegetation's role in the water cycle is cooling the heat of the rain
the Carnot cycle has 2 constant specific volume processes (heat in & heat out) the air refrigeration cycle is based on a brayton cycle which has two constant pressure processes.
Heat and pressure
heat and pressure