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1. Facile Functionalization of Graphene to Tune Response of Printed Electrochemical Sensors to Neurotransmitters

   https://doi.org/10.1149/MA2023-01532651mtgabs  

   Kammarchedu, Vinay ; Butler, Derrick ; Khamsi, Pouya Soltan ; Ebrahimi, Aida ( August 2023 , ECS Meeting Abstracts)

   Neurotransmitters are small molecules involved in neuronal signaling and can also serve as stress biomarkers.¹Their abnormal levels have been also proposed to be indicative of several neurological diseases such as Alzheimer’s disease, Parkinson’s disease, Huntington disease, among others. Hence, measuring their levels is highly important for early diagnosis, therapy, and disease prognosis. In this work, we investigate facile functionalization methods to tune and enhance sensitivity of printed graphene sensors to neurotransmitters. Sensors based on direct laser scribing and screen-printed graphene ink are studied. These printing methods offer ease of prototyping and scalable fabrication at low cost.

   The effect of functionalization of laser induced graphene (LIG) by electrodeposition and solution-based deposition of TMDs (molybdenum disulfide²and tungsten disulfide) and metal nanoparticles is studied. For different processing methods, electrochemical characteristics (such as electrochemically active surface area: ECSA and heterogenous electron transfer rate: k⁰) are extracted and correlated to surface chemistry and defect density obtained respectively using X-ray photoelectron spectroscopy (XPS) and Raman spectroscopy. These functionalization methods are observed to directly impact the sensitivity and limit of detection (LOD) of the graphene sensors for the studied neurotransmitters. For example, as compared to bare LIG, it is observed that electrodeposition of MoS₂on LIG improves ECSA by 3 times and k⁰by 1.5 times.³Electrodeposition of MoS₂also significantly reduces LOD of serotonin and dopamine in saliva, enabling detection of their physiologically relevant concentrations (in pM-nM range). In addition, chemical treatment of LIG sensors is carried out in the form of acetic acid treatment. Acetic acid treatment has been shown previously to improve C-C bonds improving the conductivity of LIG sensors.⁴In our work, in particular, acetic acid treatment leads to larger improvement of LOD of norepinephrine compared to MoS₂electrodeposition.

   In addition, we investigate the effect of plasma treatment to tune the sensor response by modifying the defect density and chemistry. For example, we find that oxygen plasma treatment of screen-printed graphene ink greatly improves LOD of norepinephrine up to three orders of magnitude, which may be attributed to the increased defects and oxygen functional groups on the surface as evident by XPS measurements. Defects are known to play a key role in enhancing the sensitivity of 2D materials to surface interactions, and have been explored in tuning/enhancing the sensor sensitivity.⁵Building on our previous work,³we apply a custom machine learning-based data processing method to further improve that sensitivity and LOD, and also to automatically benchmark different molecule-material pairs.

   Future work includes expanding the plasma chemistry and conditions, studying the effect of precursor mixture in laser-induced solution-based functionalization, and understanding the interplay between molecule-material system. Work is also underway to improve the machine learning model by using nonlinear learning models such as neural networks to improve the sensor sensitivity, selectivity, and robustness.

   References

   A. J. Steckl, P. Ray, (2018), doi:10.1021/acssensors.8b00726.

   Y. Lei, D. Butler, M. C. Lucking, F. Zhang, T. Xia, K. Fujisawa, T. Granzier-Nakajima, R. Cruz-Silva, M. Endo, H. Terrones, M. Terrones, A. Ebrahimi,Sci. Adv.6, 4250–4257 (2020).

   V. Kammarchedu, D. Butler, A. Ebrahimi,Anal. Chim. Acta.1232, 340447 (2022).

   H. Yoon, J. Nah, H. Kim, S. Ko, M. Sharifuzzaman, S. C. Barman, X. Xuan, J. Kim, J. Y. Park,Sensors Actuators B Chem.311, 127866 (2020).

   T. Wu, A. Alharbi, R. Kiani, D. Shahrjerdi,Adv. Mater.31, 1–12 (2019).

    

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2. Cationic Charges Leading to an Inverse Free‐Energy Relationship for N−N Bond Formation by Mn VI Nitrides

   https://doi.org/10.1002/ange.201805832  

   Chantarojsiri, Teera ; Reath, Alexander H. ; Yang, Jenny Y. ( October 2018 , Angewandte Chemie)

   Mn^VN Schiff‐base complexes incorporating a Na⁺(1Na), K⁺(1K), Ba²⁺(1Ba), or Sr²⁺(1Sr) ion in the ligand framework are reported. The Mn^VI/Vreduction potentials for1Na,1K,1Ba, and1Srare 0.591, 0.616, 0.805, and 0.880 V vs. Fe(C₅H₅)₂^+/0, respectively, exhibiting significant positive shifts compared to a MnN Schiff‐base complex in the same primary coordination environment but with no associated alkali or alkaline earth metal ion (A, E_1/2=0.427 V vs. Fe(C₅H₅)₂^+/0). One‐electron oxidation of the Mn^VN complexes results in bimolecular coupling to form N₂with rates (k₂) at 20 °C of 2166, 684, 857, and 99.7, an 87 m⁻¹ s⁻¹forA,1Na,1K,1Ba, and1Srrespectively, following an inverse linear free energy relationship. Thus, increasing charge through proximal cations results in Mn^VIN complexes that are both more oxidizing and more stable to bimolecular coupling, a trend diametrically opposed to when complexes were modified by ligand substituents through inductive effects.

    

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3. Cationic Charges Leading to an Inverse Free‐Energy Relationship for N−N Bond Formation by Mn VI Nitrides

   https://doi.org/10.1002/anie.201805832  

   Chantarojsiri, Teera ; Reath, Alexander H. ; Yang, Jenny Y. ( October 2018 , Angewandte Chemie International Edition)

   Mn^VN Schiff‐base complexes incorporating a Na⁺(1Na), K⁺(1K), Ba²⁺(1Ba), or Sr²⁺(1Sr) ion in the ligand framework are reported. The Mn^VI/Vreduction potentials for1Na,1K,1Ba, and1Srare 0.591, 0.616, 0.805, and 0.880 V vs. Fe(C₅H₅)₂^+/0, respectively, exhibiting significant positive shifts compared to a MnN Schiff‐base complex in the same primary coordination environment but with no associated alkali or alkaline earth metal ion (A, E_1/2=0.427 V vs. Fe(C₅H₅)₂^+/0). One‐electron oxidation of the Mn^VN complexes results in bimolecular coupling to form N₂with rates (k₂) at 20 °C of 2166, 684, 857, and 99.7, an 87 m⁻¹ s⁻¹forA,1Na,1K,1Ba, and1Srrespectively, following an inverse linear free energy relationship. Thus, increasing charge through proximal cations results in Mn^VIN complexes that are both more oxidizing and more stable to bimolecular coupling, a trend diametrically opposed to when complexes were modified by ligand substituents through inductive effects.

    

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4. Sensitivity and Detection Limit of Spectroscopic‐Grade Perovskite CsPbBr 3 Crystal for Hard X‐Ray Detection

   https://doi.org/10.1002/adfm.202112925  

   He, Yihui ; Hadar, Ido ; De Siena, Michael C. ; Klepov, Vladislav V. ; Pan, Lei ; Chung, Duck Young ; Kanatzidis, Mercouri G. ( March 2022 , Advanced Functional Materials)

   Spectroscopic‐grade single crystal detectors can register the energies of individual X‐ray interactions enabling photon‐counting systems with superior resolution over traditional photoconductive X‐ray detection systems. Current technical challenges have limited the preparation of perovskite semiconductors for energy‐discrimination X‐ray photon‐counting detection. Here, this work reports the deployment of a spectroscopic‐grade CsPbBr₃Schottky detector under reverse bias for continuum hard X‐ray detection in both the photocurrent and spectroscopic schemes. High surface barriers of≈1 eV are formed by depositing solid bismuth and gold contacts. The spectroscopic response under a hard X‐ray source is assessed in resolving the characteristic X‐ray peak. The methodology in enhancing X‐ray sensitivity by controlling the X‐ray energies and flux, and voltage, is described. The X‐ray sensitivity varies between a few tens to over 8000 μC Gy_air⁻¹cm⁻². The detectable dose rate of the CsPbBr₃detectors is as low as 0.02 nGy_airs⁻¹in the energy discrimination configuration. Finally, the unbiased CsPbBr₃device forms a spontaneous contact potential difference of about 0.7 V enabling high quality of the CsPbBr₃single crystals to operate in “passive” self‐powered X‐ray detection mode and the X‐ray sensitivity is estimated as 14 μC Gy_air⁻¹cm⁻². The great potential of spectroscopic‐grade CsPbBr₃devices for X‐ray photon‐counting systems is anticipated in this work.

    

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5. s the Electrophilicity of the Metal Nitrene the Sole Predictor of Metal-Mediated Nitrene Transfer to Olefins? Secondary Contributing Factors as Revealed by a Library of High-Spin Co(II) Reagents

   https://doi.org/https://doi.org/10.1021/acs.organomet.1c00267  

   Anshika Kalra, Vivek Bagchi ( June 2021 , Organometallics)

   null (Ed.)

   Recent research has highlighted the key role played by the electron affinity of the active metal-nitrene/imido oxidant as the driving force in nitrene additions to olefins to afford valuable aziridines. The present work showcases a library of Co(II) reagents that, unlike the previously examined Mn(II) and Fe(II) analogues, demonstrate reactivity trends in olefin aziridinations that cannot be solely explained by the electron affinity criterion. A family of Co(II) catalysts (17 members) has been synthesized with the assistance of a trisphenylamido-amine scaffold decorated by various alkyl, aryl, and acyl groups attached to the equatorial amidos. Single-crystal X-ray diffraction analysis, cyclic voltammetry and EPR data reveal that the high-spin Co(II) sites (S = 3/2) feature a minimal [N3N] coordination and span a range of 1.4 V in redox potentials. Surprisingly, the Co(II)-mediated aziridination of styrene demonstrates reactivity patterns that deviate from those anticipated by the relevant electrophilicities of the putative metal nitrenes. The representative L4Co catalyst (−COCMe3 arm) is operating faster than the L8Co analogue (−COCF3 arm), in spite of diminished metal-nitrene electrophilicity. Mechanistic data (Hammett plots, KIE, stereocontrol studies) reveal that although both reagents follow a two-step reactivity path (turnover-limiting metal-nitrene addition to the Cb atom of styrene, followed by product-determining ring-closure), the L4Co catalyst is associated with lower energy barriers in both steps. DFT calculations indicate that the putative [L4Co]NTs and [L8Co]NTs species are electronically distinct, inasmuch as the former exhibits a single-electron oxidized ligand arm. In addition, DFT calculations suggest that including London dispersion corrections for L4Co (due to the polarizability of the tert-Bu substituent) can provide significant stabilization of the turnover-limiting transition state. This study highlights how small ligand modifications can generate stereoelectronic variants that in certain cases are even capable of overriding the preponderance of the metal-nitrene electrophilicity as a driving force. 

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