(A) In coordination chemistry,the hybridization of the central metal atom determines the geometry of the complex.For a complex involving $dsp^2$ hybri

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(A) In coordination chemistry,the hybridization of the central metal atom determines the geometry of the complex.For a complex involving $dsp^2$ hybridization,one $d$-orbital,one $s$-orbital,and two $p$-orbitals are involved.This specific combination of orbitals results in a square planar geometry,where the four ligands are arranged at the corners of a square around the central metal ion.

Class 12 Chemistry Coordination Compounds Hybridisation and Geometry

Easy

$A$ complex involving $dsp^2$ hybridization has:

A
$A$ square planar geometry
B
$A$ tetrahedral geometry
C
An octahedral geometry
D
Trigonal planar geometry

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Class 12 Questions

Class 12

Chemistry Questions

Chapter

Coordination Compounds

Subtopic

Hybridisation and Geometry

The hybridization of the central atom in $NH_3, [PtCl_4]^{2-}, PCl_5$,and $BCl_3$ respectively is:

Difficult

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Match the following:
List-$I$ (Hybridisation) List-$II$ (Compound/ion)
$A. sp^3d$ $I. [PtCl_4]^{2-}$
$B. sp^3d^2$ $II. SF_6$
$C. dsp^2$ $III. BCl_3$
$D. dsp^3$ $IV. PCl_5$
$V. ClF_3$

The correct match is:

List-$I$ (Hybridisation)	List-$II$ (Compound/ion)
$A. sp^3d$	$I. [PtCl_4]^{2-}$
$B. sp^3d^2$	$II. SF_6$
$C. dsp^2$	$III. BCl_3$
$D. dsp^3$	$IV. PCl_5$
	$V. ClF_3$

MediumTS EAMCET 2018

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Which of the following complexes does not involve inner orbital hybridization?

Difficult

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Using valence bond theory,explain the following in relation to the complexes given below: $[Mn(CN)_{6}]^{3-}, [Co(NH_{3})_{6}]^{3+}, [Cr(H_{2}O)_{6}]^{3+}, [FeCl_{6}]^{4-}$
$(i)$ Type of hybridisation.
$(ii)$ Inner or outer orbital complex.
$(iii)$ Magnetic behaviour.
$(iv)$ Spin only magnetic moment value.

Medium

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Match the following hybridization in Column $I$ with the corresponding coordination complexes in Column $II$.
$A. sp^3$ $(i). [Co(NH_3)_6]^{3+}$
$B. dsp^2$ $(ii). [Ni(CO)_4]$
$C. sp^3d^2$ $(iii). [Pt(NH_3)_2Cl_2]$
$D. d^2sp^3$ $(iv). [CoF_6]^{3-}$
$(v). [Fe(CO)_5]$

MediumAP EAMCET 2014

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$A. sp^3$	$(i). [Co(NH_3)_6]^{3+}$
$B. dsp^2$	$(ii). [Ni(CO)_4]$
$C. sp^3d^2$	$(iii). [Pt(NH_3)_2Cl_2]$
$D. d^2sp^3$	$(iv). [CoF_6]^{3-}$
	$(v). [Fe(CO)_5]$

$A$ complex involving $dsp^2$ hybridization has:

Similar Questions

The hybridization of the central atom in $NH_3, [PtCl_4]^{2-}, PCl_5$,and $BCl_3$ respectively is:

Match the following:List-$I$ (Hybridisation)List-$II$ (Compound/ion)$A. sp^3d$$I. [PtCl_4]^{2-}$$B. sp^3d^2$$II. SF_6$$C. dsp^2$$III. BCl_3$$D. dsp^3$$IV. PCl_5$$V. ClF_3$The correct match is:

Which of the following complexes does not involve inner orbital hybridization?

Match the following hybridization in Column $I$ with the corresponding coordination complexes in Column $II$.$A. sp^3$$(i). [Co(NH_3)_6]^{3+}$$B. dsp^2$$(ii). [Ni(CO)_4]$$C. sp^3d^2$$(iii). [Pt(NH_3)_2Cl_2]$$D. d^2sp^3$$(iv). [CoF_6]^{3-}$$(v). [Fe(CO)_5]$

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Match the following:
List-$I$ (Hybridisation) List-$II$ (Compound/ion)
$A. sp^3d$ $I. [PtCl_4]^{2-}$
$B. sp^3d^2$ $II. SF_6$
$C. dsp^2$ $III. BCl_3$
$D. dsp^3$ $IV. PCl_5$
$V. ClF_3$

The correct match is:

Match the following hybridization in Column $I$ with the corresponding coordination complexes in Column $II$.
$A. sp^3$ $(i). [Co(NH_3)_6]^{3+}$
$B. dsp^2$ $(ii). [Ni(CO)_4]$
$C. sp^3d^2$ $(iii). [Pt(NH_3)_2Cl_2]$
$D. d^2sp^3$ $(iv). [CoF_6]^{3-}$
$(v). [Fe(CO)_5]$