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Chemistry-

General

Easy

Question

S₁ : Generally square planar complexes show geometrical isomerism but do not exhibit optical isomerism because they do not possess planer of symmetry.
S₂ : $capital delta subscript t end subscript equals fraction numerator 4 over denominator 9 end fraction capital delta subscript 0 end subscript$
S₃ : In octahedral complexes each electron entering the t_2g orbitals stabilizes the complex ion by 0.4 $capital delta subscript 0 end subscript$ and each electron entering the e.gorbital destabilizes the complex by an amount of 0.6 Δ₀.

F T T
F F T
T F T
T T F

The correct answer is: F T T

Related Questions to study

All the following complex show decreases in their weights when placed in a magnetic balance then the group of complexes having tetrahedral geometry is :
i) Ni(CO)₄
ii) K[AgF₄ ]
iii) Na₂ [Zn(CN)₄ ]
iv) K₂ [PtCl₄ ]
v) [RhCl(PPh₃)₃ ]

All the following complex show decreases in their weights when placed in a magnetic balance then the group of complexes having tetrahedral geometry is :
i) Ni(CO)₄
ii) K[AgF₄ ]
iii) Na₂ [Zn(CN)₄ ]
iv) K₂ [PtCl₄ ]
v) [RhCl(PPh₃)₃ ]

chemistry-General

$N i C l subscript 2 end subscript stack stack ⟶ with K C N on top with H C N below$ complex A
$N i C l subscript 2 end subscript stack stack ⟶ with K C l on top with text excess end text below$ complex B
A & B complexes have the co-ordination number 4.
The IUPAC name of complexes ‘A’ & ‘B’ are respectively :

$N i C l subscript 2 end subscript stack stack ⟶ with K C N on top with H C N below$ complex A
$N i C l subscript 2 end subscript stack stack ⟶ with K C l on top with text excess end text below$ complex B
A & B complexes have the co-ordination number 4.
The IUPAC name of complexes ‘A’ & ‘B’ are respectively :

chemistry-General

On treatment of 100 mL 0.1 M Solution of CoCl3.6H2Owith excess AgNO₃, $1.2 cross times 1022$ ions are precipitated The complex is :

On treatment of 100 mL 0.1 M Solution of CoCl3.6H2Owith excess AgNO₃, $1.2 cross times 1022$ ions are precipitated The complex is :

chemistry-General

parallel

How many EDTA (ethylenediaminetetraacetic acid) molecules are required to make an octahedral complex with a Ca2+ ion ?

How many EDTA (ethylenediaminetetraacetic acid) molecules are required to make an octahedral complex with a Ca2+ ion ?

chemistry-General

In Fe(CO)₅, the Fe – C bond possesses :

In Fe(CO)₅, the Fe – C bond possesses :

chemistry-General

When degenerate d-orbitals of an iSol. ated atom/ion come under influence of magnetic field of ligands, the degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:
Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colour Such transitions are not possible with d0 and d10 configuration.
Crystal field stabilization energy for [ $open square brackets C o F subscript 6 end subscript close square brackets to the power of 3 minus end exponent$ in terms of parameter Dq is – $left parenthesis capital delta equals 10 D q right parenthesis$

When degenerate d-orbitals of an iSol. ated atom/ion come under influence of magnetic field of ligands, the degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:
Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colour Such transitions are not possible with d0 and d10 configuration.
Crystal field stabilization energy for [ $open square brackets C o F subscript 6 end subscript close square brackets to the power of 3 minus end exponent$ in terms of parameter Dq is – $left parenthesis capital delta equals 10 D q right parenthesis$

chemistry-General

parallel

When degenerate d-orbitals of an iSolated atom/ion come under influence of magnetic field of ligands, the degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:
Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colour Such transitions are not possible with d0 and d10 configuration.
$T i subscript left parenthesis a q right parenthesis end subscript superscript 3 plus end superscript$ is purple while $T i subscript left parenthesis a q right parenthesis end subscript superscript 3 plus end superscript$ is colourless because –

When degenerate d-orbitals of an iSolated atom/ion come under influence of magnetic field of ligands, the degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:
Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colour Such transitions are not possible with d0 and d10 configuration.
$T i subscript left parenthesis a q right parenthesis end subscript superscript 3 plus end superscript$ is purple while $T i subscript left parenthesis a q right parenthesis end subscript superscript 3 plus end superscript$ is colourless because –

chemistry-General

When degenerate d-orbitals of an iSolated atom/ion come under influence of magnetic field of ligands, the degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:
Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colour Such transitions are not possible with d⁰ and d¹⁰ configuration.
For an octahedral complex, which of the following 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 degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:
Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colour Such transitions are not possible with d⁰ and d¹⁰ configuration.
For an octahedral complex, which of the following d-electron configuration will give maximum CFSE?

chemistry-General

When degenerate d-orbitals of an iSolated atom/ion come under influence of magnetic field of ligands, the degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:
Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colour Such transitions are not possible with d⁰ and d¹⁰ configuration.
The d-orbitals, which are stabilised in an octahedral magnetic field, are –

When degenerate d-orbitals of an iSolated atom/ion come under influence of magnetic field of ligands, the degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:
Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colour Such transitions are not possible with d⁰ and d¹⁰ configuration.
The d-orbitals, which are stabilised in an octahedral magnetic field, are –

chemistry-General

parallel

hen degenerate d-orbitals of an iSolated atom/ion come under influence of magnetic field of ligands, the degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:

Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colourSuch transitions are not possible with d⁰ and d¹⁰ configuration.
The CFSE for $open square brackets C o C l subscript 6 end subscript close square brackets to the power of 4 minus end exponent$ complex is 18000 cm^–1The $capital delta$ for $open square brackets C o C l subscript 4 end subscript close square brackets to the power of 2 minus end exponent$ will be –

hen degenerate d-orbitals of an iSolated atom/ion come under influence of magnetic field of ligands, the degeneracy is lost The two set $t subscript 2 g end subscript open parentheses d subscript x y end subscript comma d subscript y z end subscript comma d subscript x z end subscript close parentheses$ and $open parentheses d subscript z to the power of 2 end exponent end subscript comma d subscript x to the power of 2 end exponent minus y to the power of 2 end exponent end subscript close parentheses$ are either stabilized or destrabilized depending upon the nature of magnetic fieldIt can be expressed diagrammatically as:

Value of CFSE depends upon nature of ligand and a spectrochemical series has been made experimentally, for $capital delta$ is about 4/9 times to $capital delta subscript 0 end subscript$ tetrahedral complexes, (CFSE for octahedral complex)This energy lies in visible region and i.e., why electronic transition are responsible for colourSuch transitions are not possible with d⁰ and d¹⁰ configuration.
The CFSE for $open square brackets C o C l subscript 6 end subscript close square brackets to the power of 4 minus end exponent$ complex is 18000 cm^–1The $capital delta$ for $open square brackets C o C l subscript 4 end subscript close square brackets to the power of 2 minus end exponent$ will be –

chemistry-General

Double salts are addition compounds which lose their identity in aqueous Solution whereas complexes which are also addition compounds do not lose their identity in aqueous Solution. The coordination compounds show isomerism and find applications in photography, qualitative analysis, metallurgy, water purification and in the treatment of various diseases.
Which of the following statements is incorrect ?

Double salts are addition compounds which lose their identity in aqueous Solution whereas complexes which are also addition compounds do not lose their identity in aqueous Solution. The coordination compounds show isomerism and find applications in photography, qualitative analysis, metallurgy, water purification and in the treatment of various diseases.
Which of the following statements is incorrect ?

chemistry-General

Statement-I : EAN of Fe in ferrocene is 36
Statement-II : 6 $straight pi$ e ^– are co-ordinated by each cyclo pentadien ring with central metal ion.

Statement-I : EAN of Fe in ferrocene is 36
Statement-II : 6 $straight pi$ e ^– are co-ordinated by each cyclo pentadien ring with central metal ion.

chemistry-General

parallel

Which of the following ions are optically active?
I)
II)
III)
IV)

Which of the following ions are optically active?
I)
II)
III)
IV)

chemistry-General

Of the following configurations, the optical isomers are :
I)
II)
III)
IV)

Of the following configurations, the optical isomers are :
I)
II)
III)
IV)

chemistry-General

The complexes given below show : and

The complexes given below show : and

chemistry-General

parallel

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