If you product has for example, dissociation of chlorine, it will have 2 atoms of chlorine in atomization, 0.5chlorine on balancing will give you only 1 mole of chlorine atom not 2 moles of atoms like dissociation enthalpy.
Strong car-carbon bonds help explain the stability of carbon compounds.
The energy needed to break a bond between two atoms is the called the bond energy. The SI units for bond energy are kJ/mol.
Based on the question, my answer is "bond energy." I doubt that we need to step too far into chemistry and cover bond-dissociation energy (or BDE).
Rochow electronegativity is based on the effective nuclear charge of an atom and by extension the attraction a valence electron feels to the nucleus. Pauling electronegativity is based on bonding energies and states that the heteroatomic bond A-B's dissociation energy should be an average of the homoatomic bond A-A and B-B's dissociation energies. Any additional energy differences will be a result of electronegativity. Aside** Muliken electronegativity is an average of the ionization energy and electron affinity of a gas phase atom. All 3 electronegativities increase going up and to the right on the periodic table.
They are chemically inert at room temperature because of their high bond dissociation energy.
remember dissociation energy is the energy required to break a bond between to covalently bonded atoms. dissociation energy corresponds to the strength of a covalent bond. carbon compounds however have very high dissociation energy meaning it would be harder to break the bond between them than it is for a bond of lower dissociation energy. if the bonds cannot be broken then they cannot be used to form covalent bonds and thus are unreactive. they are unreactive partly because their dissociation energy is high. in other words for the slow ones jk lol: the higher the dissociation energy the less reactive. ex carbon compounds like C-C, C-H are unreactive
The strength of the bond increases as the bond dissociation energy increases.
higher is the no of shared pairs of electrons higher will be the bond dissociation energy.
Strong car-carbon bonds help explain the stability of carbon compounds.
The dissociation of a compound is when a molecular compound, for example: HCl(g) is broken apart to give H+ and Cl- ions when it is dissolved in water. Example the dissociation of compound HCl(g): HCl(g) --(H2O)--> H+ (aq) + Cl-(aq)
Greater the bond strength, greater is the bond dissociation energy. (So they are proportional to each other).
If the bond dissociation energy for reactants is high then activation energy required for the reaction also will be high.
The energy needed to break a bond between two atoms is the called the bond energy. The SI units for bond energy are kJ/mol.
Charles W. Bauschlicher has written: 'Theoretical study of the C-H bond dissociation energy of acetylene' -- subject(s): Chemical bonds, Acetylene, Kinetics, Dissociation, Heat of dissociation 'On the electron affinities of the Ca, Sc, Ti and Y atoms' -- subject(s): Electrons 'Theoretical study of the dissociation energy and the red and violet band systems of CN' -- subject(s): Dissociation, Solar Spectrum, Spectrum, Solar
Bond Dissociation Enthalpy is the energy required for breaking the bonds. This energy is supplied mostly by giving thermal energy (Heat).
gas. a plasma has more energy but this is also a dissociation of the atoms.
That this bond is strong and needs a higher influx of energy to have disassociation happen.