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A metal complex with a formula mathrmMCell_4cdot3mathrmNH_3 is involved in mathfraksp^3mathfrakd^2 hybridisation. It upon reaction with excess of mathrmAgNO_3 solution gives 'x' moles of AgCl. Consider 'x' is equal to the number of lone pairs of electron present in central atom of mathrmBrF_5 . Then the number of geometrical isomers exhibited by the complex is

Numerical Answer Type:
Enter a numerical value Answer: 1.9 to 2.1 +4 marks

Solution & Explanation

### Core Logic 1. Determine the value of x: - The central Bromine atom in BrF_5 has 7 valence electrons. It forms 5 single bonds with fluorine, leaving 2 remaining electrons. - Therefore, the number of lone pairs on Br in BrF_5 is exactly 1 implies x = 1. 2. Formulate the coordination sphere formula: - Since x = 1, the complex yields 1 mole of AgCl precipitate upon reaction with excess AgNO_3, meaning exactly 1 chloride ion sits outside the coordination sphere as an counter-ion. - Rearranging the formula components around an octahedral coordination number of 6 gives the complex configuration: [M(NH_3)_3Cl_3]Cl ### Step 1: Isomer Analysis
Facial and meridional isomers representation for Q48
Facial and meridional isomers representation for Q48
An octahedral complex of the type [Ma_3b_3] exhibits exactly **2 geometrical isomers**: - **Facial (fac)** isomer - **Meridional (mer)** isomer ### Pattern Recognition For [Ma_3b_3] octahedral coordination types, don't waste time looking for optical active configurations. It splits cleanly into exactly two classical geometric forms: facial (all three identical ligands adjacent on a face) and meridional (ligands trace a meridian plane). ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 12 Chemistry: Coordination Compounds Class 11 Chemistry: Chemical Bonding and Molecular Structure

Reference Study Guides

More Coordination Compounds Previous-Year Questions

Q27 2025 Crystal Field Stabilization Energy
The d-orbital electronic configuration of the complex among [mathrmCo(en)_3]^3+, [mathrmCoF_6]^3-, [mathrmMn(H_2O)_6]^2+ and [mathrmZn(H_2O)_6]^2+ that has the highest CFSE is:
  • A. mathrmt_2mathrmg^6mathrme_mathrmg^0
  • B. mathrmt_2mathrmg^6mathrme_mathrmg^4
  • C. mathrmt_2mathrmg^3mathrme_mathrmg^2
  • D. mathrmt_2mathrmg^4mathrme_mathrmg^2

Solution

### Related Formula textCFSE = left( -0.4 n_mathrmt_2mathrmg + 0.6 n_mathrme_mathrmg right) Delta_mathrmo + n_mathrmp P ### Core Logic Crystal Field Stabilization Energy (CFSE) is maximized (becomes most negative) when electrons populate lower-energy mathrmt_2g orbitals and stay out of higher-energy mathrme_g orbitals. This is favored by strong-field ligands (SFL) that induce large Delta_o splitting, leading to low-spin configurations. ### Step 1: Analyze Ligand Strength and Configuration Let us check each of the given complexes: 1. [mathrmCo(en)_3]^3+: Here mathrmCo^3+ has a 3mathrmd^6 configuration. Since ethylenediamine (mathrmen) is a strong-field ligand, it causes pairing of all 6 electrons in the mathrmt_2g subshell. The configuration is mathrmt_2mathrmg^6mathrme_mathrmg^0.
d-orbital splitting diagram for low-spin Co3+ complex with t2g6 configuration
d-orbital splitting diagram for low-spin Co3+ complex with t2g6 configuration
2. [mathrmCoF_6]^3-: mathrmCo^3+ is 3mathrmd^6. Since mathrmF^- is a weak-field ligand (WFL), no pairing occurs. The configuration is mathrmt_2mathrmg^4mathrme_mathrmg^2. 3. [mathrmMn(H_2O)_6]^2+: mathrmMn^2+ is 3mathrmd^5. Since mathrmH_2O is a weak-field ligand, the configuration is high-spin: mathrmt_2mathrmg^3mathrme_mathrmg^2. 4. [mathrmZn(H_2O)_6]^2+: mathrmZn^2+ is 3mathrmd^10. The d-subshell is fully filled, yielding mathrmt_2mathrmg^6mathrme_mathrmg^4. ### Step 2: Compare CFSE Values Calculating CFSE (neglecting pairing energy term for simplicity): - For [mathrmCo(en)_3]^3+: textCFSE = 6 times (-0.4 Delta_o) = -2.4 Delta_o - For [mathrmCoF_6]^3-: textCFSE = [4(-0.4) + 2(0.6)] Delta_o = -0.4 Delta_o - For [mathrmMn(H_2O)_6]^2+: textCFSE = [3(-0.4) + 2(0.6)] Delta_o = 0 - For [mathrmZn(H_2O)_6]^2+: textCFSE = [6(-0.4) + 4(0.6)] Delta_o = 0 Hence, [mathrmCo(en)_3]^3+ has the highest crystal field stabilization energy, corresponding to the d-orbital electronic configuration mathrmt_2mathrmg^6mathrme_mathrmg^0. ### Pattern Recognition For octahedral complexes of mathrmd^6 metals, a low-spin configuration (mathrmt_2mathrmg^6mathrme_mathrmg^0) achieves the theoretical maximum orbital stabilization since the mathrme_g levels are completely empty and mathrmt_2g is fully filled. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 12 Chemistry: Coordination Compounds
Q33 2025 Valence Bond Theory and Magnetic Properties
The type of hybridization and the magnetic property of [mathrmMnCl_6]^3- are:
  • A. mathrmd^2mathrmsp^3text, paramagnetic with four unpaired electrons
  • B. mathrmsp^3mathrmd^2text, paramagnetic with four unpaired electrons
  • C. mathrmd^2mathrmsp^3text, paramagnetic with two unpaired electrons
  • D. mathrmsp^3mathrmd^2text, paramagnetic with two unpaired electrons

Solution

### Related Formula mu_textspin-only = sqrtn(n+2)~mathrmB.M. ### Core Logic Let's find the oxidation state of Manganese in the complex [mathrmMnCl_6]^3-: x + 6(-1) = -3 implies x = +3 Thus, manganese is in the +3 oxidation state: mathrmMn^3+ = [mathrmAr]3mathrmd^4. ### Step 1: Determine Ligand Splitting and Orbitals mathrmCl^- is a weak-field ligand (WFL). Consequently, crystal field splitting is small (Delta_o < P), and no pairing of the 3mathrmd electrons occurs. The distribution of the 4 electrons in the 3mathrmd orbitals remains high-spin: textUnpaired electrons (n) = 4 Because the inner 3mathrmd orbitals are not empty (since they contain 4 singly occupied orbitals), the complex must utilize the outer 4mathrmd orbitals for hybridization. ### Step 2: Assign Hybridization The vacant outer orbitals used for bonding are one 4mathrms, three 4mathrmp, and two 4mathrmd orbitals, which hybridize to form six **mathrmsp^3d^2** hybrid orbitals. Since there are four unpaired electrons, the complex is **paramagnetic** with four unpaired electrons. ### Pattern Recognition Whenever WFL (like halides mathrmCl^-, mathrmF^-) are present with octahedral transition metal complexes with mathrmd^4 to mathrmd^7 configuration, they always yield high-spin, outer orbital complexes with mathrmsp^3d^2 hybridization. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 12 Chemistry: Coordination Compounds
Q50 2025 Magnetic Properties and Enthalpy of Atomisation
The spin-only magnetic moment value of mathbfM^mathrmn+ ion formed among Ni, Zn Mn and Cu that has the least enthalpy of atomisation is (in nearest integer) Here mathrmn is equal to the number of diamagnetic complexes among mathrmK_2mathrm[NiCl_4], mathrm[Zn(H_2O)_6]Cl_2, mathrmK_3[mathrmMn(mathrmCN)_6] and [mathrmCu(mathrmPPh_3)_3mathrmI]
Numerical Answer. Answer: 0 to 0

Solution

### Related Formula mu = sqrtn_textunpaired(n_textunpaired+2)~mathrmB.M. ### Core Logic This question requires three distinct sequential conceptual steps: 1. Determine the count n of diamagnetic complexes. 2. Identify which of the metal ions (Ni, Zn, Mn, Cu) has the lowest enthalpy of atomisation. 3. Compute the spin-only magnetic moment of that metal in its +n state. ### Step 1: Count Diamagnetic Complexes to find n - mathrmK_2[NiCl_4]: mathrmNi^2+ = 3mathrmd^8. Weak field chloride ligand leads to 2 unpaired electrons implies **Paramagnetic**. - mathrm[Zn(H_2O)_6]Cl_2: mathrmZn^2+ = 3mathrmd^10. Completely filled subshell implies **Diamagnetic**. - mathrmK_3[Mn(CN)_6]: mathrmMn^3+ = 3mathrmd^4. Strong field cyanide ligand gives low-spin state with 2 unpaired electrons implies **Paramagnetic**. - mathrm[Cu(PPh_3)_3I]: mathrmCu^+ = 3mathrmd^10. Completely filled subshell implies **Diamagnetic**. Thus, there are exactly 2 diamagnetic complexes: **n = 2**. ### Step 2: Identify Metal with Lowest Enthalpy of Atomisation Among the transition metals of the 3d series (Ni, Zn, Mn, Cu), **Zinc (Zn)** has the lowest enthalpy of atomisation (126~mathrmkJ~mol^-1). This is because Zinc has a fully occupied d-subshell (3mathrmd^104mathrms^2) and lacks any unpaired d-electrons to participate in metallic bonding. ### Step 3: Calculate Spin-only Magnetic Moment of M^n+ With M = textZinc and n = 2, the ion is mathrmZn^2+. Electronic configuration of mathrmZn^2+ is [mathrmAr]3mathrmd^10, which contains zero unpaired electrons (n_textunpaired = 0). Therefore, the spin-only magnetic moment is: mu = 0~mathrmB.M. ### Pattern Recognition Zinc is always a unique outlier in the d-block. Because it has a completely filled d^10 shell in both its atomic and +2 oxidation states, it exhibits no d-orbital metallic bonding (leading to lowest melting point, boiling point, and atomisation enthalpy in the 3d series) and is always diamagnetic. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 12 Chemistry: Coordination Compounds Class 12 Chemistry: d- and f-Block Elements
Q 2025 Crystal Field Electronic Configuration
A transition metal (M) among Mn, Cr, Co and Fe has the highest standard electrode potential (mathrmM^3+ / mathrmM^2+). It forms a metal complex of the type [mathrmM(mathrmCN)_6]^4-. The number of electrons present in the mathbfe_mathrmg orbital of the complex is
Numerical Answer. Answer: 1 to 1

Solution

### Related Formula Crystal Field Splitting configuration rule for strong field ligands: Delta_0 > P implies textElectrons fill mathrmt_2g text completely before entering mathrme_g ### Core Logic Let's isolate properties step-by-step: 1. Among the given first-row elements (mathrmMn, Cr, Co, Fe), Cobalt (mathrmCo) possesses the highest standard electrode potential value for the 3+/2+ couple: E^circ(mathrmCo^3+/Co^2+) = +1.81mathrm~V 2. The oxidation state configuration within complex [mathrmCo(mathrmCN)_6]^4- is mathrmCo^2+, which has a mathrmd^7 valence configuration. 3. Cyanide (mathrmCN^-) acts as a strong field ligand, forcing maximum electron pairing within the lower energy levels. ### Step 1: Subshell Filling Matrix Distribute 7 electrons across the split crystal field levels: * First 6 electrons fill the lower mathrmt_2g levels completely, forming paired tracks. * The 7th electron has no choice but to step up to the higher level. This structural splitting is visualized below:
d7 high field crystal field splitting diagram for Q46
d7 high field crystal field splitting diagram for Q46
Therefore, the number of electrons present in the mathrme_g orbital block is exactly 1. ### Pattern Recognition Always double check the specific oxidation state value: [mathrmCo(mathrmCN)_6]^4- gives mathrmCo^2+ (mathrmd^7), whereas [mathrmCo(mathrmCN)_6]^3- would be mathrmCo^3+ (mathrmd^6), which has zero electrons in its mathrme_g level. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 12 Chemistry: Coordination Compounds Class 12 Chemistry: d- and f-Block Elements
Q40 2025 Crystal Field Theory
Given below are two statements : Statement (I): In octahedral complexes, when Delta_0 < P high spin complexes are formed. When Delta_0 > P low spin complexes are formed. Statement (II) : In tetrahedral complexes because of Delta_mathrmt < mathrmP, low spin complexes are rarely formed. In the light of the above statements, choose the most appropriate answer from the options given below:
  • A. (1)\ textStatement I is correct but Statement II is incorrect.
  • B. (2)\ textBoth Statement I and Statement II are incorrect
  • C. (3)\ textStatement I is incorrect but Statement II is correct
  • D. (4)\ textBoth Statement I and Statement II are correct

Solution

### Related Formula Crystal field splitting values relation for matching configuration choices: Delta_mathrmt = frac49Delta_0 ### Core Logic Let's verify both rules based on Crystal Field Theory principles: * **Statement I**: In octahedral configurations, if pairing penalty energy P exceeds field split magnitude Delta_0, electrons prefer moving to upper sub-shells, creating high-spin states. Conversely, if Delta_0 > P, forced pairing occurs, creating low-spin complexes. (Statement I is accurate). * **Statement II**: Because tetrahedral configurations separate by an extremely narrow gap magnitude Delta_mathrmt (about half of octahedral field splits), the value almost never exceeds standard pairing energy P. Electrons consistently choose higher sub-levels rather than pairing up, meaning low-spin arrangements are extremely rare. (Statement II is accurate). ### Step 1: Verdict Therefore, both Statement I and Statement II are correct. ### Pattern Recognition Tetrahedral configurations are systematically assumed to be high-spin unless special structural properties dictate otherwise, due to the Delta_mathrmt < P constraint. ### Evaluation Rubric / Model Answer null ### Chapter Mix Class 12 Chemistry: Coordination Compounds

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