One that I can think of off the top of my head is Adenosine Triphosphate or ATP. It is the molecule that supplies almost all of your energy in the last covalent bond in the structure. It has three phosphates at the end of it, so imagine...
(Rest of molecule)-P-P-P
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all the energy is stored here in that bond. When the bond breaks, it releases energy, then forming ADP, or Adenosine Diphosphate.
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∙ 13y agoOrganic compounds with high energy bonds include ATP (adenosine triphosphate) and phosphoenolpyruvate. These molecules store energy in their phosphate bonds, which can be quickly released and used for various cellular processes.
Organic compounds decompose at high temperatures because the energy from the heat breaks the bonds holding the molecules together. This leads to the breakdown of the organic molecules into simpler compounds like carbon dioxide, water, and other byproducts. The specific products of decomposition depend on the structure of the organic compound.
The energy that is released during cellular respiration comes from chemical bonds. When these bonds are broken, free energy is released.Much of this energy is lost as heat, but some is trapped in new bonds, especially in the molecule ATP. Each time a large packet of energy is released during respiration, the cell synthesizes a molecule of ATP.The cell needs a high-energy chemical compound to start with, just as a car needs a high-energy fuel in the tank. One such compound is glucose, which has a significant amount of energy in its bonds. That energy got there when a plant trapped some light energy and used it to synthesize sugar from simpler compounds.Other high-energy compounds, such as glycogen and fats (lipids) can be used for cellular respiration. They are converted to glucose (in the case of glycogen and some other polysaccharides) or to some other compound in the respiration pathway.
The decomposition temperature depends on the compound. But many organic compounds do decompose on heating.
ATP has two high-energy bonds, located between the second and third phosphate groups. When these bonds are broken, energy is released for cellular processes.
The organic molecule that stores and releases chemical energy for use in body cells is called adenosine triphosphate (ATP). It is often referred to as the "energy currency" of the cell because it provides the energy needed for cellular processes through the hydrolysis of its high-energy phosphate bonds.
Organic compounds decompose at high temperatures because the energy from the heat breaks the bonds holding the molecules together. This leads to the breakdown of the organic molecules into simpler compounds like carbon dioxide, water, and other byproducts. The specific products of decomposition depend on the structure of the organic compound.
The energy locked inside an organic molecule is most readily accessible in its chemical bonds, particularly in high-energy bonds such as those found in ATP (adenosine triphosphate). These bonds can be rapidly broken during cellular metabolism to release energy for various cellular processes.
Anhydrous magnesium chloride is insoluble in organic solvents because it is a highly ionic compound that is held together by strong ionic bonds. Organic solvents are nonpolar in nature and cannot effectively break these ionic bonds to dissolve the compound. Additionally, the high charge density of magnesium ions makes them strongly attracted to water molecules, further decreasing their solubility in organic solvents.
Adenosine triphosphate (ATP) is the compound found in living things that supplies energy in one of its chemical bonds directly to cells. This high-energy molecule is often referred to as the "energy currency" of the cell because it helps in various cellular processes by releasing energy stored in its phosphate bonds.
ATP contains two high-energy bonds. These bonds are found between the phosphate groups of the molecule and store energy that can be readily released for cellular processes.
it contains 2 high energy bonds
The organic compound that stores and releases short-term energy in cells is adenosine triphosphate (ATP). ATP is a high-energy molecule that can rapidly provide energy for cellular processes through the release of its phosphate groups.
it contains 2 high energy bonds
Organic chemistry is the study of the structure, properties, and reactions of compounds containing carbon. Some of the differences between organic and inorganic compounds include: Organic: nonpolar covalent bonds, low melting and boiling points, strong odors, high flammability Inorganic: Ionic or polar bonds, water soluble, high melting and boiling points, generally odorless, and generally flame-resistant.
The energy that is released during cellular respiration comes from chemical bonds. When these bonds are broken, free energy is released.Much of this energy is lost as heat, but some is trapped in new bonds, especially in the molecule ATP. Each time a large packet of energy is released during respiration, the cell synthesizes a molecule of ATP.The cell needs a high-energy chemical compound to start with, just as a car needs a high-energy fuel in the tank. One such compound is glucose, which has a significant amount of energy in its bonds. That energy got there when a plant trapped some light energy and used it to synthesize sugar from simpler compounds.Other high-energy compounds, such as glycogen and fats (lipids) can be used for cellular respiration. They are converted to glucose (in the case of glycogen and some other polysaccharides) or to some other compound in the respiration pathway.
Energy-rich compounds refer to molecules that store energy within their chemical bonds. Examples include ATP, which is the primary energy currency of cells, and high-energy phosphate bonds found in molecules like phosphocreatine. These compounds release energy when their bonds are broken during metabolic processes.
The decomposition temperature depends on the compound. But many organic compounds do decompose on heating.