Energy release is to condensation as energy input is to vaporization. Vaporization requires energy input to happen, while condensation releases energy.
The condensation of ADP and Pi to make ATP is an endergonic reaction because it requires energy input. This process is driven by energy from cellular respiration or photosynthesis.
Yes, the process of bond breaking requires energy input, not release.
Breaking covalent bonds requires input of energy, not the release of energy. When covalent bonds are broken, energy is absorbed by the molecules involved in the process.
Endergonic reactions require an input of energy to occur, while exergonic reactions release energy.
No, not all reactions release energy. Some reactions require an input of energy to proceed, and these are called endothermic reactions. Endothermic reactions absorb heat from the surroundings rather than releasing it.
No, condensation does not require an input of energy. It is the process in which a gas transforms into a liquid state by releasing heat energy. This heat energy is typically given off to the surroundings.
I feel like it takes an input of thermal energy for condensation to occur since it is a warming process. Because the evaporation of a liquid is a cooling process, so for the vapor to condense back into liquid droplets I'm pretty sure that energy is required.
The condensation of ADP and Pi to make ATP is an endergonic reaction because it requires energy input. This process is driven by energy from cellular respiration or photosynthesis.
Yes, the process of bond breaking requires energy input, not release.
No, anabolic reactions require energy input to build larger molecules and do not release energy during the process.
No they do not. An endergonic reaction requires a net input of energy to force it to occur.
The total energy input can be calculated using the formula: Energy input = Useful energy output / Efficiency Substitute the given values into the formula: Energy input = 20 / 0.25 Energy input = 80 units.
Efficiency compares the useful energy output of a system to the total energy input. It provides a measure of how well a system converts input energy into useful output energy.
Input energy is typically more useful than output energy because input energy is the initial energy put into a system to produce the desired output. Output energy, on the other hand, is the energy produced by the system after losses and inefficiencies have occurred, so it is usually less than the input energy. By maximizing input energy efficiency, we can achieve a more effective output.
Breaking covalent bonds requires input of energy, not the release of energy. When covalent bonds are broken, energy is absorbed by the molecules involved in the process.
The ratio of energy output to energy input is the efficiency of a system, and is typically less than 100% due to energy losses. Work input is the amount of energy needed to perform a specific task or operation, and it is dependent on the efficiency of the system.
Input energy is when. . .say. . .you eat fruits or vegetables, and you get energy from them. You BRING IN energy or get energy. Output energy in when. . .say. . .you go run a mile or 2, and you use energy. You are PUTTING OUT energy.