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1. The Prototypical Transition Metal Carbenes, (CO) ₅ Cr=CH ₂ , (CO) ₄ Fe=CH ₂ , (CO) ₃ Ni=CH ₂ , (CO) ₅ Mo=CH ₂ , (CO) ₄ Ru=CH ₂ , (CO) ₃ Pd=CH ₂ , (CO) ₅ W=CH ₂ , (CO) ₄ Os=CH ₂ , and (CO) ₃ Pt=CH ₂ : Challenge to Experiment

   https://doi.org/10.1021/acs.jpca.8b05394  

   Weidman, Jared D.; Estep, Marissa L.; Schaefer, Henry F. (July 2018, The Journal of Physical Chemistry A)
2. Single crystal neutron and magnetic measurements of Rb ₂ Mn ₃ (VO ₄ ) ₂ CO ₃ and K ₂ Co ₃ (VO ₄ ) ₂ CO ₃ with mixed honeycomb and triangular magnetic lattices

   https://doi.org/10.1039/C9DT03389K  

   Smith Pellizzeri, Tiffany M.; Sanjeewa, Liurukara D.; Pellizzeri, Steven; McMillen, Colin D.; Garlea, V. Ovidiu; Ye, Feng; Sefat, Athena S.; Kolis, Joseph W. (April 2020, Dalton Transactions)

   null (Ed.)

   Two new alkali vanadate carbonates with divalent transition metals have been synthesized as large single crystals via a high-temperature (600 °C) hydrothermal technique. Compound I , Rb 2 Mn 3 (VO 4 ) 2 CO 3 , crystallizes in the trigonal crystal system in the space group P 3̄1 c , and compound II , K 2 Co 3 (VO 4 ) 2 CO 3 , crystallizes in the hexagonal space group P 6 3 / m . Both structures contain honeycomb layers and triangular lattices made from edge-sharing MO 6 octahedra and MO 5 trigonal bipyramids, respectively. The honeycomb and triangular layers are connected along the c -axis through tetrahedral [VO 4 ] groups. The MO 5 units are connected with each other by carbonate groups in the ab -plane by forming a triangular magnetic lattice. The difference in space groups between I and II was also investigated with Density Functional Theory (DFT) calculations. Single crystal magnetic characterization of I indicates three magnetic transitions at 77 K, 2.3 K, and 1.5 K. The corresponding magnetic structures for each magnetic transition of I were determined using single crystal neutron diffraction. At 77 K the compound orders in the MnO 6 -honeycomb layer in a Néel-type antiferromagnetic orientation while the MnO 5 triangular lattice ordered below 2.3 K in a colinear ‘up–up–down’ fashion, followed by a planar ‘Y’ type magnetic structure. K 2 Co 3 (VO 4 ) 2 CO 3 ( II ) exhibits a canted antiferromagnetic ordering below T N = 8 K. The Curie–Weiss fit (200–350 K) gives a Curie–Weiss temperature of −42 K suggesting a dominant antiferromagnetic coupling in the Co 2+ magnetic sublattices. 

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3. CO ₂ Reduction Pathways on MnBr(N-C)(CO) ₃ Electrocatalysts

   https://doi.org/10.1021/acs.organomet.7b00743  

   Vandezande, Jonathon E.; Schaefer, Henry F. (January 2018, Organometallics)
4. Effect of “X” Ligands on the Photocatalytic Reduction of CO ₂ to CO with Re(pyridylNHC-CF ₃ )(CO) ₃ X Complexes: Effect of “X” Ligands on the Photocatalytic Reduction of CO ₂ to CO with Re(pyridylNHC-CF ₃ )(CO) ₃ X Complexes

   https://doi.org/10.1002/ejic.202000283  

   Shirley, Hunter; Sexton, Thomas More; Liyanage, Nalaka P.; Palmer, C. Zachary; McNamara, Louis E.; Hammer, Nathan I.; Tschumper, Gregory S.; Delcamp, Jared H. (May 2020, European Journal of Inorganic Chemistry)
5. Magnetochiral tunneling in paramagnetic Co _1/3 NbS ₂

   https://doi.org/10.1073/pnas.2318443121  

   Lim, Seongjoon; Singh, Sobhit; Huang, Fei-Ting; Pan, Shangke; Wang, Kefeng; Kim, Jaewook; Kim, Jinwoong; Vanderbilt, David; Cheong, Sang-Wook (March 2024, Proceedings of the National Academy of Sciences)

   Electric currents have the intriguing ability to induce magnetization in nonmagnetic crystals with sufficiently low crystallographic symmetry. Some associated phenomena include the non-linear anomalous Hall effect in polar crystals and the nonreciprocal directional dichroism in chiral crystals when magnetic fields are applied. In this work, we demonstrate that the same underlying physics is also manifested in the electronic tunneling process between the surface of a nonmagnetic chiral material and a magnetized scanning probe. In the paramagnetic but chiral metallic compound Co_1/3NbS₂, the magnetization induced by the tunneling current is shown to become detectable by its coupling to the magnetization of the tip itself. This results in a contrast across different chiral domains, achieving atomic-scale spatial resolution of structural chirality. To support the proposed mechanism, we used first-principles theory to compute the chirality-dependent current-induced magnetization and Berry curvature in the bulk of the material. Our demonstration of this magnetochiral tunneling effect opens up an avenue for investigating atomic-scale variations in the local crystallographic symmetry and electronic structure across the structural domain boundaries of low-symmetry nonmagnetic crystals. 

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