Coordinatively Unsaturated Nickel Nitroxyl Complex: Structure, Physicochemical Properties, and Reactivity toward Dioxygen
Abstract
:1. Introduction
2. Results and Discussion
2.1. Synthesis of Ni–NO Complex
2.2. Structure of Ni-NO Complex
2.3. Characterizations of Ni-NO Complex
2.4. Dioxygen Reactivity of Ni-NO Complex
2.5. Structure of Ni-NO2 Complex
2.6. Characterizations of Ni-NO2 Complex
2.7. Theoretical Considerations
2.7.1. Density Functional Theory (DFT) Calculations for [Ni(NO)(I)(L1″)]
2.7.2. DFT Calculations for [Ni(κ2-O2N)(L1″)2]+
3. Materials and Methods
3.1. Material and General Techniques
3.2. Instrumentation
3.3. Theoretical Calculations
3.4. Preparation of Ligand and Complexes
3.4.1. [Ni(NO)(I)]n
3.4.2. [Ni(NO)(I)(L1″)]
3.4.3. [Ni(κ2-O2N)(L1″)2](I3)
3.5. X-ray Crystal Structure Determination
4. Conclusions
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Sample Availability
References
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Complexes a | Ligand Type | d (Ni–N)/Å b | d (N–O)/ Å b | ∠ (Ni–N–O)/ ° b | ν(N–O)/ cm−1 b | {MNO}n | Ref. |
---|---|---|---|---|---|---|---|
[Ni(NO)(I)(L1″)] | (NO)N2I | 1.6467 (16) | 1.136 (3) | 176.68 (19) | 1777 (KBr) | {NiNO}10 | tw c |
[Ni(NO)(L3)] | (NO)N3 | 1.651 (6) | 1.160 (10) | 179.1 (7) | 1780 (KBr) | {NiNO}10 | [22] |
[Ni(NO)(L0f)] | (NO)N3 | 1.6361 (16) | 1.160 (2) | 172.42 (17) | 1823 (KBr) | {NiNO}10 | [27] |
[Ni(NO)(L0)] | (NO)N3 | 1.619 (6), 1.617 (6) | 1.170 (7), 1.158 (7) | 178.5 (6), 175.3 (7) | 1786 (KBr) | na d | [28] |
{NiNO}10 | [29] | ||||||
[Ni(NO)(iPr3tacn)](PF6) | (NO)N3 | 1.677 (4) 1.646 (3) | 1.123 (5) 1.162 (4) | 180.0 170.9 (2) | 1770 (ATR) | {NiNO}10 | [30] |
[Ni(NO)(Tmp-tol)] | (NO)S3 | 1.665 (3) | 1.131 (4) | 173.9 (4) | 1752 (KBr) | {NiNO}10 | [31] |
[Ni(NO)(TseMes)] | (NO)Se3 | 1.633 (4) | 1.156 (5) | 180.0 | 1763, 1752 (KBr) | na d | [28] |
[Ni(NO){HB(tBuIm)3}] | (NO)C3 | 1.620 (5) | 1.184 (7) | 178.5 (4) | 1703 (toluene) | {NiNO}10 | [32] |
[Ni(NO){PhB(CyCH2Im)3}] | (NO)C3 | 1.633 (9)–1.668 (1) | 1.174 (1)–1.197 (1) | 172.7 (1)–177.8 (1) | 1693 (THF) | {NiNO}10 | [33] |
[Ni(NO){HB(MeBz)3}] | (NO)C3 | 1.643 (2)–1.646 (2) | 1.183 (3)–1.191 (3) | 169.3 (2)–174.8 (2) | 1714 (THF) | {NiNO}10 | [33] |
[Ni(NO){HB(p-tBuPhTz)3}] | (NO)C3 | 1.640 (2) | 1.163 (3) | 176.3 (3) | 1746 (THF) | {NiNO}10 | [33] |
Method a | d (Ni–N) /Å | d (N–O) /Å | ∠ (Ni–N–O) /° | ν(N–O) /cm−1 | ν(Ni–NO) /cm−1 | δ(Ni–N–O) /cm−1 | SD b (Ni) | SD b (NO) |
---|---|---|---|---|---|---|---|---|
Exp. | 1.647 | 1.135 | 176.7 | 1777 | 572 | 410 | ||
BP86 (CS) | 1.646 | 1.172 | 165.1 | 1799 | 618 | 410 | 0 | 0 |
B3LYP (CS) | 1.630 | 1.156 | 163.8 | 1883 | 651 | 412 | 0 | 0 |
B3LYP (BS) | 1.720 | 1.169 | 167.1 | 1820 | 439 | 356 | 1.05 | −1.19 |
Method | d (Ni–O1) /Å | d (Ni–O2) /Å | d (N1–O1) /Å | d (N1–O2) /Å | ∠ (O1–N1–O2) /° | νas(O–N–O) /cm−1 |
---|---|---|---|---|---|---|
Exp. | 2.088 | 2.120 | 1.256 | 1.267 | 111.5 | 1201 |
BP86 | 2.178 | 2.107 | 1.268 | 1.274 | 111.8 | 1166 |
Complex | [Ni(NO)(I)(L1″)](thf) | [Ni(κ2-NO2)(L1″)2](I3) |
---|---|---|
CCDC number | 2285305 | 2285306 |
Empirical formula | C23H40IN5NiO2 | C38H64I3N9NiO2 |
Formula weight | 604.21 | 1118.40 |
Crystal system | Triclinic | Monoclinic |
Space group | P (#2) | P21/n (#14) |
a/Å | 9.02661 (11) | 9.3444 (2) |
b/Å | 9.61413 (11) | 17.2498 (3) |
c/Å | 16.4456 (2) | 30.0610 (5) |
α/° | 77.6870 (10) | 90 |
β/° | 89.2370 (10) | 86.7699 (17) |
γ/° | 87.2540 (10) | 90 |
V/Å3 | 1392.76 (3) | 4837.81 (16) |
Z | 2 | 4 |
Dcalc/g cm−3 | 1.441 | 1.535 |
μ(MoKα)/cm−1 | 18.318 | 23.555 |
2θ range, ° | 6–55 | 6–55 |
Reflections collected | 45,524 | 115,535 |
Unique reflections | 6385 | 10,976 |
Rint | 0.0335 | 0.0280 |
Number of variables | 289 | 478 |
Refls./Para. ratio | 22.09 | 22.96 |
Residuals: R1 (I > 2 σ (I)) a | 0.0233 | 0.0747 |
Residuals: R (All refl.) | 0.0247 | 0.0843 |
Residuals: wR2 (All refl.) a | 0.0653 | 0.1898 |
Goodness of fit ind. | 1.064 | 1.103 |
Max/min peak, /e Å−3 | 0.76/−0.30 | 2.46/−1.05 |
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Fujisawa, K.; Kataoka, T.; Terashima, K.; Kurihara, H.; de Santis Gonçalves, F.; Lehnert, N. Coordinatively Unsaturated Nickel Nitroxyl Complex: Structure, Physicochemical Properties, and Reactivity toward Dioxygen. Molecules 2023, 28, 6206. https://doi.org/10.3390/molecules28176206
Fujisawa K, Kataoka T, Terashima K, Kurihara H, de Santis Gonçalves F, Lehnert N. Coordinatively Unsaturated Nickel Nitroxyl Complex: Structure, Physicochemical Properties, and Reactivity toward Dioxygen. Molecules. 2023; 28(17):6206. https://doi.org/10.3390/molecules28176206
Chicago/Turabian StyleFujisawa, Kiyoshi, Taisei Kataoka, Kohei Terashima, Haruka Kurihara, Felipe de Santis Gonçalves, and Nicolai Lehnert. 2023. "Coordinatively Unsaturated Nickel Nitroxyl Complex: Structure, Physicochemical Properties, and Reactivity toward Dioxygen" Molecules 28, no. 17: 6206. https://doi.org/10.3390/molecules28176206
APA StyleFujisawa, K., Kataoka, T., Terashima, K., Kurihara, H., de Santis Gonçalves, F., & Lehnert, N. (2023). Coordinatively Unsaturated Nickel Nitroxyl Complex: Structure, Physicochemical Properties, and Reactivity toward Dioxygen. Molecules, 28(17), 6206. https://doi.org/10.3390/molecules28176206