An iodine dissociates into atom after absorting light of wave length `4500Å` If quantum of radition is absorbed by each molecule calculate the kinetic energy of iodine (Bood energy of `I_(2) is 240 kJ(mol))`

An iodine molecule dissociates into atom after absorbing light of wavelength 4500 Å. If quantum of radiation is absorbed by each molecule calculate the kinetic energy of iodine (Bond energy of I_(2) is 240 kJ mol^(-1))

An iodine molecule dissociates into atom after absorbing light of wavelength 4500 Å. If quantum of radiation is absorbed by each molecule calculate the kinetic energy of iodine (Bond energy of I_(2) is 240 kJ mol^(-1))

On absorbing light of wavelength 3800 A, bromine molecule undergoes dissociation and form atoms. The kinetic energy of one bromine atom assuming that one quantum of radiation is absorbed by each molecule would be (Bond energy of Br_2=190(kJ) / (mol)

A photon of 4000 A^o is used to break the iodine molecule, then the % of energy converted to the K.E. of iodine atoms if bond dissociation energy of I_2 ​ molecule is 246.5 kJ/mol is:

A photon of 3000 A^o is used to break the iodine molecule, then the % of energy converted to the K.E. of iodine atoms if bond dissociation energy of I_2 ​ molecule is 255.5 kJ/mol is:

A photon of 5000 A^o is used to break the iodine molecule, then the % of energy converted to the K.E. of iodine atoms if bond dissociation energy of I_2 ​ molecule is 155.5 kJ/mol is:

Two masses m_1 and m_2 are connected by a light rod of length I. If rod is rotating about an axis with angular speed Omega . Such that its kinetic energy is minimum then its K.E. is

In a measurement of quantum efficiency of photosynthesis in green plants, it was found that 10 quanta of red light of wavelength 6850 Å were needed to release one molecule of O_(2) . The average energy storage in this process for 1 mol O_(2) evolved is 112 Kcal. What is the energy conversion efficieny in this experiment? Given: 1 cal =4.18 J, N_(A)=6xx10^(23),h=6.63xx10^(-34) J.s

Two hydrogen atoms undergo head on collision and end up with zero kinetic energy. Each particle then emits a photon of wavelength 1028 Å . Which transition leads to this wavelength ? Calculate the velocity of hydrogen atom before collision ( m_(H) =1.67 xx 10^(-27) kg)

Find the temperature at which the everage thermal kinetic energy is equal to the energy needed to take a hydrogen atom from its ground state n = 3 state hydrogen can now emit rod light of wavelength 653.1 nm because of maxwellan distribution of speeds a hydrogen sample emits red light at temperature much lower than that obtained from this problem Asuume that hydrogen that hydrogen molecules dissociate into atoms