Coordination Compounds MCQs With Answers – Part 4 (Class 12 Chemistry)
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Coordination Compounds MCQs with Answers – Part 4 (Class 12 Chemistry)

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311. Study the high-spin tetrahedral electron counts.
RowConfigurationProposed number of unpaired electrons
P\(d^4\)\(4\)
Q\(d^5\)\(5\)
R\(d^6\)\(4\)
S\(d^8\)\(0\)
The inconsistent row is:
ⓐ. S
ⓑ. P
ⓒ. Q
ⓓ. R
312. Assertion: A tetrahedral \(d^8\) complex can be paramagnetic even though a square-planar \(d^8\) complex may be diamagnetic. Reason: The tetrahedral \(\mathrm{sp^3}\) description does not require the pairing needed to make an inner \(d\) orbital vacant for square-planar \(\mathrm{dsp^2}\) hybridisation.
ⓐ. Both Assertion and Reason are true, but Reason does not explain Assertion
ⓑ. Assertion is true, but Reason is false
ⓒ. Both Assertion and Reason are true, and Reason explains Assertion
ⓓ. Assertion is false, but Reason is true
313. A four-coordinate complex is known to be tetrahedral and high spin. Which property is least consistent with this information?
ⓐ. \(\mathrm{sp^3}\) hybridisation
ⓑ. All electrons paired in a \(d^8\) arrangement
ⓒ. No compulsory pairing of inner \(d\) electrons
ⓓ. Four equivalent ligand directions
314. A four-coordinate \(d^8\) complex is experimentally diamagnetic. Another complex of the same metal ion is paramagnetic with two unpaired electrons. The most consistent geometries of the two complexes are respectively:
ⓐ. square planar and tetrahedral
ⓑ. tetrahedral and square planar
ⓒ. octahedral and linear
ⓓ. tetrahedral and octahedral
315. A six-coordinate \(d^6\) metal ion forms a complex in which all six \(d\) electrons are paired in three inner \(d\) orbitals. The predicted hybridisation and magnetic behaviour are:
ⓐ. \(\mathrm{sp^3d^2}\) and paramagnetic
ⓑ. \(\mathrm{sp^3}\) and diamagnetic
ⓒ. \(\mathrm{dsp^2}\) and paramagnetic
ⓓ. \(\mathrm{d^2sp^3}\) and diamagnetic
316. A student states that every complex containing \(\mathrm{NH_3}\) must be an inner-orbital complex. The best correction is:
ⓐ. \(\mathrm{NH_3}\) is never a ligand
ⓑ. the outcome depends on the metal, oxidation state, d-electron count, coordination number, and geometry
ⓒ. all ammine complexes are tetrahedral
ⓓ. \(\mathrm{NH_3}\) always acts as a weak-field anionic ligand
317. A weak-field ligand often leads to an octahedral outer-orbital complex because:
ⓐ. weak-field ligands always reduce the coordination number to \(4\)
ⓑ. two vacant \((n-1)d\) orbitals are automatically present for every metal ion
ⓒ. weak-field ligands force all inner \(d\) electrons to pair
ⓓ. without two vacant inner \(d\) orbitals, outer \(nd\) orbitals are used
318. The usual valence bond reasoning for a strong-field octahedral complex follows the sequence:
ⓐ. Strong field \(\rightarrow\) pairing \(\rightarrow\) vacant inner \(d\) orbitals \(\rightarrow\) \(\mathrm{d^2sp^3}\)
ⓑ. Strong ligand influence \(\rightarrow\) loss of all \(d\) electrons \(\rightarrow\) \(\mathrm{sp^3}\) hybridisation
ⓒ. Strong ligand influence \(\rightarrow\) maximum unpaired electrons \(\rightarrow\) \(\mathrm{sp^3d^2}\) hybridisation
ⓓ. Strong ligand influence \(\rightarrow\) coordination number \(2\) \(\rightarrow\) linear geometry
319. Study the ligand-effect descriptions.
RowConditionLikely consequence in a suitable octahedral complex
PStrong-field ligandPairing may increase
QWeak-field ligandMore unpaired electrons may remain
RTwo vacant inner \(d\) orbitals available\(\mathrm{d^2sp^3}\) may form
SInner \(d\) electrons remain maximally unpairedDiamagnetism is guaranteed
The inconsistent row is:
ⓐ. P
ⓑ. Q
ⓒ. S
ⓓ. R
320. In \(\mathrm{[Co(CN)_6]^{3-}}\), the oxidation state and \(d\)-electron configuration of cobalt are respectively:
ⓐ. \(+2\) and \(d^7\)
ⓑ. \(+3\) and \(d^6\)
ⓒ. \(+3\) and \(d^4\)
ⓓ. \(0\) and \(d^9\)
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