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1. Ion-pairs of structurally related polyoxotantalate clusters and divalent metal cations

   https://doi.org/10.1080/00958972.2020.1830073  

   Chen, Jiahui; Ma, Yachun; Zhang, Dongdi; Yang, Yuqing; Bera, Mrinal K.; Luo, Jiancheng; Raee, Ehsan; Liu, Tianbo (October 2020, Journal of Coordination Chemistry)

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2. Investigation of ion-electrode interactions of linear polyimides and alkali metal ions for next generation alternative-ion batteries

   https://doi.org/10.1039/D2SC02939A  

   Gannett, Cara N.; Kim, Jaehwan; Tirtariyadi, Dave; Milner, Phillip J.; Abruña, Héctor D. (August 2022, Chemical Science)

   Organic electrode materials offer unique opportunities to utilize ion-electrode interactions to develop diverse, versatile, and high-performing secondary batteries, particularly for applications requiring high power densities. However, a lack of well-defined structure–property relationships for redox-active organic materials restricts the advancement of the field. Herein, we investigate a family of diimide-based polymer materials with several charge-compensating ions (Li + , Na + , K + ) in order to systematically probe how redox-active moiety, ion, and polymer flexibility dictate their thermodynamic and kinetic properties. When favorable ion-electrode interactions are employed ( e.g. , soft K + anions with soft perylenediimide dianions), the resulting batteries demonstrate increased working potentials and improved cycling stabilities. Further, for all polymers examined herein, we demonstrate that K + accesses the highest percentage of redox-active groups due to its small solvation shell/energy. Through crown ether experiments, cyclic voltammetry, and activation energy measurements, we provide insights into the charge compensation mechanisms of three different polymer structures and rationalize these findings in terms of the differing degrees of improvements observed when cycling with K + . Critically, we find that the most flexible polymer enables access to the highest fraction of active sites due to the small activation energy barrier during charge/discharge. These results suggest that improved capacities may be accessible by employing more flexible structures. Overall, our in-depth structure–activity investigation demonstrates how variables such as polymer structure and cation can be used to optimize battery performance and enable the realization of novel battery chemistries. 

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3. Effect of metal ion solubility on the oxidative assembly of metal sulfide quantum dots

   https://doi.org/10.1063/1.5128932  

   Silva, Karunamuni L.; Silmi, Leenah; Brock, Stephanie L. (December 2019, The Journal of Chemical Physics)
4. Evidence of H/D Exchange within Metal-Adducted Carbohydrates after Ion/Ion-Dissociation Reactions

   https://doi.org/10.1021/jacs.3c05793  

   Gass, Darren T.; Cordes, Michael S.; Alberti, Sebastian N.; Kim, H. Jamie; Gallagher, Elyssia S. (November 2023, Journal of the American Chemical Society)

   Tandem mass spectrometry (MS/MS) using fragmentation has become one of the most effective methods for gaining sequence and structural information of biomolecules. Ion/ion reactions are competitive reactions where either proton transfer (PT) or electron transfer (ET) can occur from interactions between multiply charged cations and singly charged anions. Utilizing ion/ion reactions with fluoranthene has offered a unique method of fragment formation for structural elucidation of biomolecules. Fluoranthene is considered an ideal anion reagent because it selectively causes electron transfer dissociation (ETD) and minimizes PT when interacting with peptides. However, limited investigations have sought to understand how fluoranthene – the primary, commercially available anion reagent – interacts with other biomolecules. Here, we apply deuterium labeling to investigate ion/ion reaction mechanisms between fluoranthene and divalent, metal-adducted carbohydrates (Ca2+, Mg2+, Co2+, and Ni2+). Deuterium labeling of carbohydrates allowed us to observe evidence of hydrogen/deuterium exchange (HDX) occurring after ion/ion dissociation reactions. The extent of deuterium loss is dependent on several factors, including the physical properties of the metal ion and the fragment structure. Based on the deuterium labeling data, we have proposed ETD, PTD, and intermolecular PT – also described as HDX - mechanisms. This research provides a fundamental perspective of ion/ion and ion/molecule reaction mechanisms and illustrates properties that impact ion/ion and ion/molecule reactions for carbohydrates. Together, this could improve the capability to distinguish complex and heterogenous biomolecules, such as carbohydrates. 

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5. Understanding Ion-Beam Damage to Air-Sensitive Lithium Metal With Cryogenic Electron and Ion Microscopy

   https://doi.org/10.1093/micmic/ozad074  

   Koh, Hyeongjun; Detsi, Eric; Stach, Eric A (July 2023, Microscopy and Microanalysis)

   Abstract It is essential to understand the nanoscale structure and chemistry of energy storage materials due to their profound impact on battery performance. However, it is often challenging to characterize them at high resolution, as they are often fundamentally altered by sample preparation methods. Here, we use the cryogenic lift-out technique in a plasma-focused ion beam (PFIB)/scanning electron microscope (SEM) to prepare air-sensitive lithium metal to understand ion-beam damage during sample preparation. Through the use of cryogenic transmission electron microscopy, we find that lithium was not damaged by ion-beam milling although lithium oxide shells form in the PFIB/SEM chamber, as evidenced by diffraction information from cryogenic lift-out lithium lamellae prepared at two different thicknesses (130 and 225 nm). Cryogenic energy loss spectroscopy further confirms that lithium was oxidized during the process of sample preparation. The Ellingham diagram suggests that lithium can react with trace oxygen gas in the FIB/SEM chamber at cryogenic temperatures, and we show that liquid oxygen does not contribute to the oxidation of lithium process. Our results suggest the importance of understanding how cryogenic lift-out sample preparation has an impact on the high-resolution characterization of reactive battery materials. 

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