Explain stereoisomerism in coordination compounds.
(N/A) Stereoisomerism arises in compounds that have the same chemical formula and chemical bonds but differ in their spatial arrangement of atoms or groups.
Geometric Isomerism:
For square planar complexes of the type $[ML_4]$: This type of isomerism arises due to different possible arrangements of ligands in heteroleptic complexes.
In complexes with coordination number $4$,square planar complexes with the formula $[MX_2L_2]$ exhibit two isomers: the $cis$ isomer,where two $X$ ligands are adjacent to each other,and the $trans$ isomer,where they are opposite to each other.
Other square planar complexes of the type $[MABXL]$ can also show three isomers (two $cis$ and one $trans$). This type of isomerism is not possible in tetrahedral geometry.
For octahedral complexes of the type $[ML_6]$: In complexes with the formula $[MX_2L_4]$,the two $X$ ligands can be oriented in either $cis$ or $trans$ positions relative to each other.
This type of isomerism also arises in complexes with the formula $[MX_2(L-L)_2]$ when bidentate ligands $(L-L)$ (e.g.,$en = NH_2CH_2CH_2NH_2$) are present.
Another type of geometric isomerism arises in octahedral complexes of the type $[Ma_3b_3]$,such as $[Co(NH_3)_3(NO_2)_3]$. If the three donor atoms of the same ligands occupy adjacent corners of an octahedral face,we obtain the facial $(fac)$ isomer.
Geometric Isomerism:
For square planar complexes of the type $[ML_4]$: This type of isomerism arises due to different possible arrangements of ligands in heteroleptic complexes.
In complexes with coordination number $4$,square planar complexes with the formula $[MX_2L_2]$ exhibit two isomers: the $cis$ isomer,where two $X$ ligands are adjacent to each other,and the $trans$ isomer,where they are opposite to each other.
Other square planar complexes of the type $[MABXL]$ can also show three isomers (two $cis$ and one $trans$). This type of isomerism is not possible in tetrahedral geometry.
For octahedral complexes of the type $[ML_6]$: In complexes with the formula $[MX_2L_4]$,the two $X$ ligands can be oriented in either $cis$ or $trans$ positions relative to each other.
This type of isomerism also arises in complexes with the formula $[MX_2(L-L)_2]$ when bidentate ligands $(L-L)$ (e.g.,$en = NH_2CH_2CH_2NH_2$) are present.
Another type of geometric isomerism arises in octahedral complexes of the type $[Ma_3b_3]$,such as $[Co(NH_3)_3(NO_2)_3]$. If the three donor atoms of the same ligands occupy adjacent corners of an octahedral face,we obtain the facial $(fac)$ isomer.
Explore More
Similar Questions
Amongst $Ni(CO)_4$,$[Ni(CN)_4]^{2-}$ and $[NiCl_4]^{2-}$,which of the following statements is correct regarding their magnetic properties?
DifficultIIT 1991
View SolutionWhich of the following coordination compounds exhibit both optical and geometrical isomerism?
$a$. $[Co(en)_2Cl_2]Br$
$b$. $[Pt(NH_3)_2Cl_2Br_2]$
$c$. $[Co(en)_3]Cl_3$
$d$. $[Pt(NH_3)_4Cl_2]$
$e$. $[Pt(NH_3)_2Cl_2]$
$a$. $[Co(en)_2Cl_2]Br$
$b$. $[Pt(NH_3)_2Cl_2Br_2]$
$c$. $[Co(en)_3]Cl_3$
$d$. $[Pt(NH_3)_4Cl_2]$
$e$. $[Pt(NH_3)_2Cl_2]$
Difficult
View SolutionFor which of the following configurations is the spin-only magnetic moment value $2.84 \ BM$?
Difficult
View SolutionWhich of the following will be able to show geometrical isomerism?
What will be the value of $x$ in $Fe^{x+}$,if the magnetic moment,$\mu=\sqrt{24} \ BM$?
Vedclass Products
For Students
Vedclass Test Series
Mock tests in real JEE/NEET style with performance analysis. 5-day free trial.
Start Free TrialFor Teachers
Exam Paper Generator
Generate Set A/B/C/D exam papers from 7.5L+ questions in 2 minutes. 3 chapters free.
Try FreeFor Institutes
Online Exam Module
Live online exams with unlimited students, 360° analytics & white-label branding.
See Demo