Energy required to break one bond in DNA is approximately

The energy required to break one bond in DNA is 10^(-20)J . This value in eV is nearly:

Express (a) the energy required to break one bond in DNA (10^(-10)J) in eV. (b) the kinetic energy of an air molecule (10^(-21)J) in eV. (c) the daily intake of a human adult (10^(7)J) in kilocalories.

Total energy required to break all the bonds in the gaseous state molecule of AB_(2) is xkJmol^(-1) . Then the bond energy of the bond A-B in the molecule will be ________.

The amount of energy required to break a bond is same as the amount of energy released when the same bond is formed. In gaseous state, the enrgy required for hololytic cleavage of a bond is called Bond Dissociation Energy(BDE) or Bond Strength. BDE is affected by s-character of the bond and the stability of the radicals formed. Shorter bonds typically stronger bonds. BDEs for some bonds are given below: Correct match of the C-H bonds(shown in bold) in column J with their BDE in column K is

The amount of energy required to break a bond is same as the amount of energy released when the same bond is formed. In gaseous state, the enrgy required for hololytic cleavage of a bond is called Bond Dissociation Energy(BDE) or Bond Strength. BDE is affected by s-character of the bond and the stability of the radicals formed. Shorter bonds typically stronger bonds. BDEs for some bonds are given below: For the following reaction CH_4(g) + Cl_2(g) overset(light)rarr CH_3Cl(g) + HCl(g) the correct statement is

The net enthalpy change of a reaction is the amount of energy required to break all the bonds in reactant molecules minus amount of energy required to form all the bonds in the product molecules.What will be the enthalpy change for the following reaction. H_(2)(g) + Br_(2)(g) to 2HBr(g) Given that bond energy of H_(2), Br_(2) and HBr is 435 kJ mol^(-1) , 192 kJ mol^(-1) and 368 kJ mol^(-1) respectively.