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1. Understanding Reaction Mechanisms of Nicotinamide Adenine Dinucleotide (NADH) with Lithium Cobalt Oxide and Other Metal Oxide Nanomaterials

   https://doi.org/10.1039/D3EN00351E  

   Kruszynski Earl, Catherine E.; Henke, Austin H.; Laudadio, Elizabeth D; Hamers, Robert J. (January 2023, Environmental Science: Nano)

   High-valent metal oxides such as LiCoO2 and related materials are of increasing environmental concern due to the large-scale use in lithium-ion batteries and potential for metal ion release into aqueous systems. A key aspect of the environmental chemistry of these materials is the potential role redox chemistry plays in their transformations as well as their influence on the surrounding environment (i.e., biomolecules, organisms etc.). In recent work, we showed that LiCoO2(a common lithium-ion battery cathode material) oxidizes nicotinamide adenine dinucleotide (NADH), an essential molecule for electron transport, and enhances Co release from LiCoO2. In the present work, we investigated the mechanism of interaction by examining the role of the ribose, phosphate, adenosine, and the nicotinamide components of NADH in the transformation of LiCoO2 nanoparticles. To build an understanding of the interaction mechanism, we used fluorescence spectroscopy to measure the changes in redox state and inductively coupled plasma-mass spectrometry (ICP-MS) to measure the changes in dissolved Co. Our results reveal the importance of surface binding, via the phosphate functionality, in initiating the redox transformation of both the LiCoO2 and the NADH. Observations from X-ray photoelectron spectroscopy (XPS) data show that molecules containing phosphate were bound to the surface of the nanoparticles and those without that functionality were not. We further established the generality of the results with LiCoO2 by examining other high-valent transition metal oxides. This surface binding effect has implications for understanding how other phosphorylated species can be transformed directly in the presence of high-valent metal oxide nanomaterials. 

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2. Dynamic aqueous transformations of lithium cobalt oxide nanoparticle induce distinct oxidative stress responses of B. subtilis

   https://doi.org/10.1039/D0EN01151G  

   Gari, Metti K.; Lemke, Paul; Lu, Kelly H.; Laudadio, Elizabeth D.; Henke, Austin H.; Green, Curtis M.; Pho, Thomas; Hoang, Khoi Nguyen; Murphy, Catherine J.; Hamers, Robert J.; et al (January 2021, Environmental Science: Nano)

   null (Ed.)

   Lithium cobalt oxide (LiCoO 2 ), an example of nanoscale transition metal oxide and a widely commercialized cathode material in lithium ion batteries, has been shown to induce oxidative stress and generate intracellular reactive oxygen species (ROS) in model organisms. In this study, we aimed to understand the time-dependent roles of abiotic ROS generation and Co ions released in aqueous medium by LiCoO 2 NPs, and examined the induced biological responses in model bacterium, B. subtilis upon exposure. We found that the redox-active LiCoO 2 NPs produced abiotic ROS primarily through H 2 O 2 generation when freshly suspended. Subsequently, the freshly-suspended LiCoO 2 NPs induced additional DNA breakage, and changes in expression of oxidative stress genes in B. subtilis that could not be accounted for by the released Co ions alone. Notably, in 48 hour old LiCoO 2 suspensions, H 2 O 2 generation subsided while higher concentrations of Co ions were released. The biological responses in DNA damage and gene expression to the aged LiCoO 2 NPs recapitulated those induced by the released Co ions. Our results demonstrated oxidative stress mechanisms for bacteria exposed to LiCoO 2 NPs were mediated by the generation of distinct biotic and abiotic ROS species, which depended on the aqueous transformation state of the NPs. This study revealed the interdependent and dynamic nature of NP transformation and their biological consequences where the state of NPs resulted in distinct NP-specific mechanisms of oxidative injury. Our work highlights the need to capture the dynamic transformation of NPs that may activate the multiple routes of oxidative stress responses in cells. 

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3. Structural basis for differing electrocatalytic water oxidation by the cubic, layered and spinel forms of lithium cobalt oxides

   https://doi.org/10.1039/c5ee02195b  

   Gardner, Graeme; Al-Sharab, Jafar; Danilovic, Nemanja; Go, Yong Bok; Ayers, Katherine; Greenblatt, Martha; Charles Dismukes, G. (January 2016, Energy & Environmental Science)

   The two polymorphs of lithium cobalt oxide, LiCoO 2 , present an opportunity to contrast the structural requirements for reversible charge storage (battery function) vs. catalysis of water oxidation/oxygen evolution (OER; 2H 2 O → O 2 + 4H + + 4e − ). Previously, we reported high OER electrocatalytic activity from nanocrystals of the cubic phase vs. poor activity from the layered phase – the archetypal lithium-ion battery cathode. Here we apply transmission electron microscopy, electron diffraction, voltammetry and elemental analysis under OER electrolysis conditions to show that labile Li + ions partially deintercalate from layered LiCoO 2 , initiating structural reorganization to the cubic spinel LiCo 2 O 4 , in parallel with formation of a more active catalytic phase. Comparison of cubic LiCoO 2 (50 nm) to iridium (5 nm) nanoparticles for OER catalysis (commercial benchmark for membrane-based systems) in basic and neutral electrolyte reveals excellent performance in terms of Tafel slope (48 mV dec −1 ), overpotential ( η = ∼420 mV@10 mA cm −2 at pH = 14), faradaic yield (100%) and OER stability (no loss in 14 hours). The inherent OER activity of cubic LiCoO 2 and spinel LiCo 2 O 4 is attributed to the presence of [Co 4 O 4 ] n+ cubane structural units, which provide lower oxidation potential to Co 4+ and lower inter-cubane hole mobility. By contrast, the layered phase, which lacks cubane units, exhibits extensive intra-planar hole delocalization which entropically hinders the four electron/hole concerted OER reaction. An essential distinguishing trait of a truly relevant catalyst is efficient continuous operation in a real electrolyzer stack. Initial trials of cubic LiCoO 2 in a solid electrolyte alkaline membrane electrolyzer indicate continuous operation for 1000 hours (without failure) at current densities up to 400 mA cm −2 and overpotential lower than proven PGM (platinum group metal) catalysts. 

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4. Bifunctional electrocatalysis for CO ₂ reduction via surface capping-dependent metal–oxide interactions

   https://doi.org/10.1039/C9CC02934F  

   Wu, Yueshen; Yuan, Xiaolei; Tao, Zixu; Wang, Hailiang (July 2019, Chemical Communications)

   Multi-component materials are a new trend in catalyst development for electrochemical CO 2 reduction. Understanding and managing the chemical interactions within a complex catalyst structure may unlock new or improved reactivity, but is scientifically challenging. We report the first example of capping ligand-dependent metal–oxide interactions in Au/SnO 2 structures for electrocatalytic CO 2 reduction. Cetyltrimethylammonium bromide capping on the Au nanoparticles enables bifunctional CO 2 reduction where CO is produced at more positive potentials and HCOO − at more negative potentials. With citrate capping or no capping, the Au–SnO 2 interactions steer the selectivity toward H 2 evolution at all potentials. Using electrochemical CO oxidation as a probe reaction, we further confirm that the metal–oxide interactions are strongly influenced by the capping ligand. 

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5. Controlling intramolecular and intermolecular electronic coupling of radical ligands in a series of cobaltoviologen complexes

   https://doi.org/10.26434/chemrxiv-2023-gcwqn  

   Kessler, Brice_J O; Mansoor, Iram F; Wozniak, Derek I; Emge, Thomas J; Lipke, Mark C (April 2023, ChemRxiv)

   Controlling electronic coupling between two or more redox sites is of interest for tuning the electronic properties of molecules and materials. While classic mixed-valence (MV) systems are highly tunable, e.g., via the modular organic bridges connecting the redox sites, metal-bridged MV systems are difficult to control because the electronics of the metal cannot usually be altered independently of redox-active moieties embedded in its ligands. Herein, we overcome this limitation by varying the donor strengths of ancillary ligands in a series of cobalt complexes without directly perturbing the electronics of viologen-like redox sites bridged by the cobalt ions. The cobaltoviologens [1X-Co]n+ feature four 4-X-pyridyl donor groups (X = CO2Me, Cl, H, Me, OMe, NMe2) that provide gradual tuning of the electronics of the bridging CoII centers, while a related complex [2-Co]n+ with NHC donors supports exclusively CoIII states even upon reduction of the viologen ligands. Electrochemistry and IVCT band analysis reveal that the MV states of these complexes have electronic structures ranging from fully localized ([2-Co]4+; Robin-Day Class I) to fully delocalized ([1CO2Me-Co]3+; Class III) descriptions, demonstrating unprecedented control over electronic coupling without changing the identity of the redox sites or bridging metal. Additionally, single-crystal XRD characterization of the homovalent complexes [1H-Co]2+ and [1H-Zn]2+ revealed radical-pairing interactions between the viologen ligands of adjacent complexes, representing a type of through-space electronic coupling commonly observed for organic viologen radicals but never before seen in metalloviologens. The extended solid-state packing of these complexes produces 3D networks of radical π-stacking interactions that impart unexpected mechanical flexibility to these crystals. 

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