Chemically it doesn't. Biologists get sloppy in these areas. Only the completion of a bond releases energy. So, when something is phosphorylated with that phosphate group then an energetic conformational/chemical/physical change takes place using the energy of that bonding.
The phosphate group is being removed to acquire the energy from the exothermic reaction that takes place during the splitting. The energy received is used for cell metabolism.
Chemical energy
ATP, or adinosine triphosphate, is simply an adenine, a sugar (ribose), and three phosphates. ADP is has two phosphates, and AMP has one phosphate. Each phosphate added creates more energy in the molecule, making it unstable. It is the phosphates coming apart from the molecule that is releasing the energy.
ATP is, on its own, a rather unstable molecule. Because of this, the conversion to a more stable molecule releases energy that can be used by other parts of the cell.
It requires energy. ADP is adenosine diphosphate and ATP is adenosone triphosphate. Basically, ATP has three phosphate groups (tri-phosphate) and ADP has two (di-phosphate). When ATP releases energy, a phosphate group is detached, forming energy and ADP. Therefore, to get ATP from ADP, energy is required to add one phosphate group onto the ADP.
ATP is a molecule made up of 3 phosphate molecules and one nitrogenous base. there is a high energy bond between the 3rd and 2nd phosphate, which can be broken down into ADP + P this is a reversible reaction.
ATP is adenosine triphosphate, and there are high-energy bonds between the phosphate bonds. ATP has three phosphates branching off of the adenosine in one triphosphate arm. To tap into the energy in ATP cells simply have to break the bonds using enzymes. After the ATP is broken down it will be turned into ADP (adenosin diphosphate)+phosphate, with no bond between the diphosphate and the leftover phosphate.
ATP (Adenosine triphosphate) looses a phosphate to form ADP (Adenosine diphosphate), and release energy.
The major molecule involved in energy release and storage is ADENOSINE TRIPHOSPHATE. It contains a large ADENOSINE molecule connected to three PHOSPHATE groups via PHOSPHATE bond. When the bond that connects one of the three PHOSPHATE groups to the ADENOSINE molecule is broken down, energy is released. The resulting molecule would be ADENOSINE DIPHOSPHATE, one free PHOSPHATE group and energy.
ATP, or adinosine triphosphate, is simply an adenine, a sugar (ribose), and three phosphates. ADP is has two phosphates, and AMP has one phosphate. Each phosphate added creates more energy in the molecule, making it unstable. It is the phosphates coming apart from the molecule that is releasing the energy.
ATP or adenosine triphosphate stores and releases energy by adding or breaking off one of the phosphate molecules on its tail. When a phosphate molecule breaks off of ATP it releases energy. Likewise, if an ADP (a ATP with one lose phosphate group than ATP) gains a phosphate group, energy is stored.
ATP (adinine triphosphate) loses a phosphate group to become ADP (adinine diphosphate). The phosphate group was released is referred to as inorganic phosphate. There is also a release of energy as the high energy phosphate bonds are cleaved.
The energy in ATP is stored in the bonds between the phosphate groups. To release energy ATP breaks off one of the phosphate groups, which makes it ATP.
Mainly it acts as a energy carrier.It stores energy between phosphate bonds.It release about 33kJ per mole.
ATP (Adenosine Triphosphate) is converted to ADP (Adenosine Diphosphate) when the 3rd phosphate bond is broken to release energy.
ATP is, on its own, a rather unstable molecule. Because of this, the conversion to a more stable molecule releases energy that can be used by other parts of the cell.
adenosine triphosphate, ATP
ATP contains three phosphate groups. The third phosphate group (the outermost one) is called the alpha phosphate. The breaking of this phosphate bond is accompanied by the release of a large amount of energy which can be used to drive key steps in metabolic reactions. With the removal of alpha phosphate, the remainder molecule is ADP
ATP stands for adenosine triphosphate. This means that there are 3 phosphate groups in the molecule, which are linked to the adenosine with very high energy covalent bonds. Whenever any of these phosphate groups' bonds is broken, it releases all of the energy that was involved in the bond. It is converted to ADP (adenosine diphosphate) and so on by enzymes, that can break the covalent bonds to phosphate groups and release the big pack of potential energy.