Crystal field stabilization energy of high spin complex cation having `d_5` configuration in an octahedral field is

Crystal field stabilization energy for high spin d^4 octahedral complex is

High spin complex of d^6 configuration in an octahedral field will have the CFSE equal to

Crystal field stabilization energy for high spin d^(4) octahedral complex is ________

The values of the crystal field stabilization energies for a high spin d^6 metal ion in octahedral and tetrahedral fields, respectively, are :

Crystal field stabalisation energy for complex [Co(CN)_(6)]^(-3) will be :-

Statement-1: [Co^(II)(NH)_(3))_(6)]^(2+) is not readily oxidized to [Co^(III)(NH_(3))_(6)]^(3+) when air is bubbled through it. Statement-2: Crystal field stabilization energy of Co(+III) with a d^(6) configuration is higher then for Co(+III) with a d^(7) arrangement.

The complex ion having minimum magnitude of triangle_circ (CFSE) in octahedral field is

Low spin complex of d^6 -cation in an octahedral field will have the following energy:

Low spin complex of d^6 -cation in an octahedral field will have the following energy:

Using CFT depict the electronic configuration of the rhodium ion (Rh^(2+)) in an octahedral field for which the crystal field splitting Delta_(0) is greater than the pairing eneryg P (b) Calculate the crystal field stabilisation energy for this configuration (in terms of Delta andP) .