`CFSE` for `d^(6)` octahedral complex having `Delta =250` and `P =125kJmo1^(-1)` is .

Crystal field splitting energey (CFSE) for the complex [Fe(O)_(4)]^(2-) is when Delta =125 and P =250kJmo1^(-1) .

Crystal field splitting energey (CFSE) for the complex [Fe(O)_(4)]^(2-) is when Delta =125 and P =250kJmo1^(-1) .

Determine the crystal field stabilisation energy of a d^(6) complex having Delta_(0) = 25000cm^(-1) and P =1500cm^(-1) .

Determine the crystal field stabilisation energy of a d^(6) complex having Delta_(0) = 25000cm^(-1) and P =1500cm^(-1) .

Crystal field splitting energey (CFSE) for the complex [Cr(NH_(3)_(6)]^(2+) is when P =125 and Delta_(0)=250kJ mo1^(-1) .

CFSE for the complex ion [Mn(CN)_(6)]^(3-) is

Crystal field splitting energy (CFSE) for the complex [Cr(NH_(3))_(6)]^(2+) is when P =125 and Delta_(0) =250kjmol^(-1) .

Crystal field splitting energy (CFSE) for the complex [Cr(NH_(3))_(6)]^(2+) is when P =125 and Delta_(0) =250kjmol^(-1) .

When degenerate d-orbitals of an isolated atom/ion come under influence of magnetic field of ligands, the degeneray is lost. The two set t_(2g)(d_(xy),d_(yz),d_(xz)) and e_(g) (d_(x^(2))-d_(x^(2)-y^(2)) are either stabilized or destabilized depending upon the nature of magnetic field. it can be expressed diagrammatically as: Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for tetrahedral complexes, Delta is about 4/9 times to Delta_(0) (CFSE for octahedral complex). this energy lies in visible region and i.e., why electronic transition are responsible for colour. such transition are not possible with d^(0) and d^(10) configuration. Q. For an octahedral complex, which of the followin d-electron configuration will give maximum CFSE?

When degenerate d-orbitals of an isolated atom/ion come under influence of magnetic field of ligands, the degeneray is lost. The two set t_(2g)(d_(xy),d_(yz),d_(xz)) and e_(g) (d_(x^(2))-d_(x^(2)-y^(2)) are either stabilized or destabilized depending upon the nature of magnetic field. it can be expressed diagrammatically as: Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for tetrahedral complexes, Delta is about 4/9 times to Delta_(0) (CFSE for octahedral complex). this energy lies in visible region and i.e., why electronic transition are responsible for colour. such transition are not possible with d^(0) and d^(10) configuration. Q. For an octahedral complex, which of the followin d-electron configuration will give maximum CFSE?