How many `Cl` atoms can you ionise in the process `ClrarrCl^(o+)+e^(-)` by the energy liberated for the process `Cl+e^(-) rarr Cl^(ɵ)` for one Avogadro number of atoms. Given `IP=13.0eV` and `EA = 3.60 eV`.

How many Cl atoms can you ionise in the process Cl rarr Cl^+ + e, by the energy liberated for the process Cl + e rarr rarr Cl^- for one Avogadro's number of atoms ? (Given : IP = 13. 0 eV and EA = 3.60 eV ) .

How many chlorine atoms can you ionize in the process Cl rarr Cl^+ + e , by the energy liberated from the following process ? Cl + e^- rarr Cl^(-) for 6 xx 10^23 "atoms" Given electron affinity ofm Cl = 3.61 eV , and I P of Cl = 17.422 eV .

Half of the energy released from the reaction A rightarrow B;Delta G^(@)=-9264kJ/mol is used for the conversion Cl_(2)rightarrow ClO_(3)^(-);E^(o)=-1.6V . Select the correct statement(s): (A) Given process Cl_(2)rightarrow ClO_(3)^(-) is a spontaneous process. (B) Given process Cl_(2)rightarrow ClO_(3)^(-) is a non-spontaneous process. (C) Moles of ClO_(3) formed when one mole of A is converted to B are 2 (D) Moles of ClO_(3) formed when one mole of A is converted to B are 6

The ionisation potential of hydrogen is 13.60 eV . Calculate the energy required to produce one mole of H^(o+) ion (1 eV = 96.3 kJ mol^(-1)) .

The number of process (es) rquiring the absorption of energy/are a. Cl rarr Cl^(ɵ) , b. O^(ɵ) rarr O^(2-) c. Fe^(+3) rarr Fe^(+2) , d. Ar rarr Ar^(ɵ)

A hydrogen sample is prepared in a particular excited state. Photons of energy 2.55 eV get absorbed into the sample to take some of the electrons to a further excited state B . Find orbit numbers of the states A and B . Given the allowed energies of hydrogen atom: E_(1)=-13.6 eV, E_(2)=-3.4 eV, E_(3)=-1.5 eV, E_(4)=-0.85 eV. E_(6)=-0.54 eV

Hydrogen atom in its ground state is excited by means of monochromatic radiation of wavelength 970.6 Å . How many lines are possible in the resulting emission spectrum ? Calculate the longest wavelength amongst them. You may assume that the ionisation energy for hydrogen atom is 13.6 eV. Given Planck's constant = 6.6 xx 10^(-34)Js, " " c = 3 xx 10(8) ms^(-1)

The energy required to remove an electron from the outermost shell of an isolate gaseous atom is known as IE_(1) of that atom. Similarly, the enrgy required for the removal of the electron from the unipositive ion, diapositive ion and tripositive ion are known as IE_(2),IE_(3) and IE_(4) respectively, and are called successive ionisation energies. The magnitude of the charge depends on the size of the orbital of electron. Electrons in smaller orbitals are on average close with each other and have more repulsion. Thus for Be(2s^(2)) , the IE_(1) and IE_(2) are 9.3 and 18.2 eV "atom"^(1) , whereas for Ca(4s^(2)) , the values are 6.1 and 11.9 eV . Which of the following are isoelectronic species? 1 rarrCH_(3)^(o+),IIrarrNH_(2)^(ɵ),IIIrarrNH_(4)^(o+),IVrarrNH_(3)

The amount of energy released when 10^(12) atoms of Cl vapours are converted to Cl^(ɵ) ions, according to the equation : Cl_((g))+e^(-) rarr Cl_((g))^(ɵ) is 58 xx 10^(-10)J Calculate the Delta_(eg)H^(ɵ) of Cl atom in kJ mol^(-1) and eV "atom"^(-1) .

The principal quantum number of H-atom orbital, if the energy of e^(-) is -3.4eV , will be: