If the crystal field splitting energy of a tetrahedral complex $\Delta_t$ of the type $[ML_4]^{n+}$ is $x \ eV$,what is the crystal field splitting energy with respect to an octahedral complex,$[ML_6]^{n+}$?

The electronic spectrum of $[Ti(H_2O)_6]^{3+}$ shows a single broad peak with a maximum at $20,300 \, cm^{-1}$. The crystal field stabilization energy $(CFSE)$ of the complex ion,in $kJ \, mol^{-1}$,is :

Given below are two statements $:$
Statement $(I) :$ In octahedral complexes,when $\Delta_{o} < P$ high spin complexes are formed. When $\Delta_{o} > P$ low spin complexes are formed.
Statement $(II) :$ In tetrahedral complexes because of $\Delta_{t} < P$,low spin complexes are rarely formed.
In the light of the above statements,choose the most appropriate answer from the options given below $:$

Which one of the following complexes will have $\Delta_0 = 0$ and $\mu = 5.96 \ B.M.?$

Which of the following order of $CFSE$ is incorrect?

The crystal field stabilisation energy $(CFSE)$ and the spin-only magnetic moment in Bohr Magneton $(BM)$ for the complex $K_3[Fe(CN)_6]$ are,respectively