The functions of mitochondrians are to give ENERGY to the body creating ATP energy which is composed of ADP+P The functions of mitochondrians are to give ENERGY to the body creating ATP energy which is composed of ADP+P The functions of mitochondrians are to give ENERGY to the body creating ATP energy which is composed of ADP+P
A*D*2P
4 times p or 4p
3p
(p+9)(p+6)
ATP plus H2O release energy (endergonic reaction) and P. Now, this P plus ADP becomes ATP (exergonic reaction). It's a cyclic process. It starts all over again at ATP plus H2O..
A) ADP plus P → ATP would result in the greatest release of energy as it is the process of phosphorylation where energy is stored in the phosphate bonds of ATP. The other options involve reactions that release energy through the breakdown of molecules but do not involve the formation of high-energy phosphate bonds.
adp+p(i)--->atp ADP +P ---> ATP
The functions of mitochondrians are to give ENERGY to the body creating ATP energy which is composed of ADP+P The functions of mitochondrians are to give ENERGY to the body creating ATP energy which is composed of ADP+P The functions of mitochondrians are to give ENERGY to the body creating ATP energy which is composed of ADP+P
A*D*2P
In biology, ADP refers to adenine diphosphate, where adenosine is connected with two highly energized phosphate molecules. When another phosphate (P) is connected, it forms ATP, or adenosine triphosphate. This is the primary form of energy that we use.
One molecule of ADP can be easily formed to make one form of ATP. All you need to do is add one phosphate group to the ADP and ATP is formed.ADP + P + energy --> ATPADP + P + energy --> ATP
ADP + P + Energy
ATP releases a phosphate group and becomes ADP ATP = ADP + P + energy.
Energy
ADP (adenosine diphosphate) + P (another phosphate group) ---usable energy--> ATP (Adenosine triphoshate)
There is no specific site. Anywhere where energy is needed