"This is a difficult question to answer exactly since (1) potential
energy is not something that is directly measured - it can only be
deduced from the heats produced or absorbed in a transformation, and
(2) the heat produced or absorbed (enthalpy) in a chemical
transformation vary from substance to substance.
In general, we expect that when chemical bonds are formed, energy is
released - imagine the individual atoms as having energy and have to
be slowed down in order that chemical bonds can form. Alternatively,
and more accurately, when two atoms spontaneously form a chemical
bond it must mean that the entropy of this system has increased,
since two separate atoms have more disorganization (entropy) then
one complete molecule, then in order for the process to be
spontaneous (entropy increases), there must be some heat released.
The problem now is relating heat to potential energy. I would rather
you relate this to internal energy rather than potential energy
(which is not quite directly applicable to chemical systems). If we
think of internal energy, we know, by definition, that internal
energy is a function of the heat and work that goes in and out of
the system. Since most chemical transformations do not involve work,
then internal energy is mostly a function of the heat that enters or
leaves the system.
Thus, when a chemical bond is formed spontaneously, heat leaves the
system, the internal energy of the system goes down. You may then
think of internal energy as a kind of potential energy and say that
because the system is less energetic (since heat left the system)
that it must now have a lower potential energy."
Chemical bonds are made and broken by chemical reactions. After chemical bonds have been broken, then energy is released, and if a chemical bond is made, then energy is absorbed.
A chemical reaction involves the making and breaking of strong chemical bonds. Explanation: Chemical reactions are characterized by the formation of new substances, and the making and breaking of strong chemical bonds. In practice it is usually fairly easy to discriminate between a chemical change, new substances formed, and a phase change, where bonds may have been broken but no new substances formed. Examples of chemical reactivity where chemical bonds are manifestly formed include hydrocarbon combustion, the which drives our industrial society, and in which C − C and C − H bonds are clearly broken, and O − H and C O bonds are clearly formed in the products.
By definition, a compound can, somehow, be broken down into its elements. Whether this process is easy depends on the strength of the chemical bonds in the compound and the definition of "easy"!
The formation of chemical bonds releases energy. It is an exothermic process. The breaking of chemical bonds takes energy. It is an endothermic process.
First let me define covalent and non-covalent bonds.Covalent bonds are bonds BETWEEN the atoms of a chemical - the atoms share electrons.Noncovalent bonds are the interactions between atoms (and chemicals) that do NOT involve sharing of electrons. (hydrophobic, hydrophilic, and ionic bonds are non-covalent bonds)Physical Change: breaking wood in half, melting ice, deflating a balloon, heating/cooling something (burning NOT included), dissolving something (as long as it does not react with solvent). Physical changes do not make or break covalent bonds. Physical changes only break/make non-covalent bonds (such as hydrophobic, ionic or hydrogen bonds).Chemical Change: burning something, changing the actual chemical makeup in any way - usually by reactions like redox (reduction-oxidation reactions), decomposition and combustion reactions among others. Chemical changes do make and/or break covalent bonds. If the breaking and/or making of covalent bonds occurs - the change is chemical - since you are actually changing the chemical into something new.
ATP
It is stored in bonds and released in energy. Energy is needed to break the chemical bonds, and energy is released when bonds are broken.
in chemical reactions, energy is absorbed or released when chemical bonds are broken and new ones are formed.
ATP
Potential chemical energy is stored in chemical bonds.
A normal battery also a car battery, oil, food and etc.
Chemical energy is a type of potential energy that is stored in the bonds of chemical compounds. It is released when those bonds are broken during a chemical reaction. An example is the energy released when you burn wood in a fire, as the chemical bonds in the wood are broken down to release heat and light.
energy
Chemical energy is stored in the bonds between atoms within a molecule. When these bonds are broken, energy is released in the form of heat or light. This energy can then be used to power various processes in living organisms or in chemical reactions.
Yes, chemical bonds store potential energy that is released when the bonds are broken. This energy can be released in the form of heat, light, or other forms of energy, depending on the type of bond and the elements involved.
Chemical bonds are broken.
Chemical bonds are made and broken by chemical reactions. After chemical bonds have been broken, then energy is released, and if a chemical bond is made, then energy is absorbed.