Global ETD Search

51	An Initial Exploration of Transition Metal Nitroprussides as Electrode Materials for Sodium-ion Batteries Enblom, Veronica January 2022 (has links) Na-ion batteries (NIBs) are expected to revolutionise the battery sector by promising an affordable technology while capitalising on sustainable development. To compete with Li-ion batteries, however, electrode materials with higher capacities need to be developed. Transition metal nitroprussides (TM-NPs), NaxM[Fe(CN)5NO]1-y ·zH2O, is a material class derived from one of the most popular positive electrode materials for NIBs, Prussian blue analogues (PBAs), where one of the cyano ligands have been replaced by an electroactive nitrosyl (NO) ligand. Thus, in theory TM-NPs should be able to reach higher capacities than PBAs and therefore be attractive candidates for high-capacity electrodes. However, if the nitrosyl is redox active in NIBs and how the cycling behaviour may be affected by the M cation is unknown. The focus in this thesis is therefore to explore the charge-discharge behaviour of four different TM-NPs (M=Fe, Ni, Mn, and Cu) in Na-ion half-cell batteries to gain an initial understanding of their electrochemical behaviour and to set up research questions to be pursued in the future. Based on our observations and previous studies, we propose that the nitrosyl is electrochemically active in all four TM-NPs, and that it contributes with a considerable amount of capacity, although with a large voltage hysteresis. It is further concluded that all M cations apart from Ni were redox active, but to varying degrees on charging and discharging. We argue that both the redox and the voltage hysteresis is caused by anisotropic charge transfer within the materials, and that it needs to be understood before commercialisation of TM-NPs can be realised. Though there are challenges to overcome, the many interesting attributes of TM-NPs, including anionic redox, anisotropic charge transfer and structural diversity, makes them promising as a new type of cheap and sustainable electrode material for NIBs. Sodium-ion batteries Transition metal nitroprussides Electrode materials Prussian blue analogues Cathode materials Nitrosyl redox Anisotropic charge transfer Hysteresis Sustainable batteries Materials Chemistry Materialkemi
52	Vacuum Compatible Solvated Thin Film Samples for XUV Spectroscopy: Studying Molecular Bistability in the Native Solvation Environment Johnson, Samuel Dwight 28 October 2022 (has links) No description available. Chemistry Inorganic Chemistry Physical Chemistry Physics spin crossover prussian blue analogue molecular bistability charge transfer induced spin transition thin film vacuum compatible solvent
53	Magneto-Transport and Optical Control of Magnetization in Organic Systems: From Polymers to Molecule-based Magnets Bozdag, Kadriye Deniz 30 September 2009 (has links) No description available. Physics Photoinduced magnetism room temperature magnet molecule-based magnet V-Cr Prussian Blue Analog polyaniline nanofiber network magnetoresistance temperature electric field morphology
54	Hydrogen peroxide sensing with prussian blue-based fiber-optic sensors Akbari Khorami, Hamed 03 October 2016 (has links) Hydrogen peroxide (H2O2) is extensively used in a broad range of industrial and medical applications, such as aseptic processing of food and pharmaceuticals, disinfection, water treatment plants, and decontamination of industrial effluents. H2O2 is believed to be responsible for chemical degradation of polymer membranes in Polymer-Electrolyte-Membrane (PEM) fuel cells. Therefore, a versatile H2O2 sensor that functions in different environments with different conditions is of practical importance in various fields. This dissertation presents the fabrication of a fiber-optic H2O2 sensing probe (optrode) and its H2O2 sensing behavior in different conditions. An H2O2 optrode is fabricated using chemical deposition of Prussian blue (PB) onto the tip of a multimode optical fiber. Sensing tests are performed in aqueous solutions at a constant pH and different concentrations of H2O2. Sensing features of the optrode (i.e. repeatability, durability, and reproducibility) are assessed by performing multiple sensing tests with several optrodes. The results show the prepared optrode is able to detect concentrations of H2O2 in aqueous solutions at a constant pH of 4 and the optrode features a repeatable and durable response at this condition. The functionality of optrodes at different pH values is further investigated by performing additional sensing experiments. These experiments are carried out in aqueous solutions with different concentrations of H2O2 at different pH values (i.e. pH 2-7). The sensor detects the presence of H2O2 at a range of pH values. Sensing behavior of optrodes toward detection and measurement of H2O2 concentrations is studied at the pH value corresponding to an operating PEM fuel cell (i.e. pH 2). The optrode is able to detect concentrations of H2O2 at this condition with a repeatable and durable response. The stability of PB films, prepared through different conditions, is investigated to address the stability of optrodes at elevated temperatures. PB films are first deposited onto the glass slides through three different chemical processes, and then at different synthesis temperatures. The PB films are left in Phosphate-Buffer-Solutions (PBS) with pH 2 and at elevated temperatures for a day. Finally, PB films are characterized using Fourier transform infrared spectroscopy (FTIR) to analyze their stability following PBS processing at operating temperatures and pH value corresponding to an operating PEM fuel cell (i.e. 80 °C and pH 2). The results of these experiments illustrate the PB films prepared through the single-source precursor (SSP) technique and at synthesis temperatures above 60 °C remain stable after the PBS processing. The proposed optrode shows reliable sensing behavior toward detection and measurement of H2O2 concentrations in aqueous solutions at different conditions. The prepared optrode has the potential for being developed and used in different industrial and medical fields, as well as an operating PEM fuel cell, to detect and measure H2O2 concentrations. / Graduate / 0794 / 0548 / 0485 / hakbarik@uvic.ca Fiber-optic sensors Chemical sensors Hydrogen peroxide sensor Chemical deposition Prussian blue Single source precursor Spectroscopic technique PEM fuel cells Optrode Spectroscopic detection pH-dependent response Hydrogen peroxide Optical fiber sensor PEMFC Degradation fuel cells Membrane degradation
55	Nanoestruturação de filmes finos para utilização em eletrodos enzimáticos / Nanostructuration of thin films for applying in enzyme based biosensors Gonçales, Vinícius Romero 12 December 2011 (has links) Os desafios atuais no desenvolvimento de biossensores abrangem diversos aspectos, tais como a necessidade de se aperfeiçoar a interface de contato entre o substrato e o material biológico, a eficiência de transdução do sinal químico em um sinal mensurável, o tempo de resposta, a compatibilidade dos biossensores com matrizes biológicas e a integração de diferentes elementos de reconhecimento biológico em um único dispositivo, visando a detecção de distintos analitos. Nesse contexto, o desenvolvimento da nanociência tem criado recursos bastante atraentes para otimizar os aspectos descritos acima. O presente trabalho apresenta, portanto, estudos realizados para a construção de mediadores nanoestruturados que possam operar de maneira mais eficiente que os correspondentes materiais maciços (sistemas não-nanoestruturados). Em uma das abordagens utilizadas, um mediador híbrido de hexacianoferrato de cobre/polipirrol (CuHCNFe/Ppy) teve suas propriedades eletroquímicas aliadas às propriedades morfológicas e eletrônicas de um feltro revestido com nanotubos de carbono do tipo \"cup-stacked\" (feltro/NTCCS) para o desenvolvimento de um sensor de H2O2. O feltro/NTCCS é uma malha hidrofílica condutora que permite uma dispersão bastante uniforme do mediador híbrido. Essa característica, aliada ao aumento da área eletroativa e à interação eletrônica existente entre o CuHCNFe/PPy e os nanotubos de carbono criaram uma plataforma favorável para a construção de um biossensor de glicose. Em uma segunda estratégia, esferas de poliestireno com diâmetros de 300, 460, 600 e 800 nm foram utilizadas como molde para a formação de filmes de CuHCNFe/PPy macroporosos. Os distintos mediadores foram aplicados na detecção de H2O2 com o intuito de se correlacionar a importância do tamanho do poro com o desempenho analítico obtido. Diferentemente do esperado, os mediadores maciços e porosos apresentaram desempenhos analíticos bastante similares, o que levou a uma consideração das propriedades termodinâmicas de superfícies curvas, da molhabilidade de materiais porosos e da influência da cinética eletroquímica na utilização de sistemas porosos. Tais plataformas também foram aplicadas com sucesso na construção de biossensores de glicose e de colina. Por fim, foi possível sintetizar mediadores nanoestruturados através da imobilização de camadas de azul da Prússia e de CuHCNFe dentro das cavidades de filmes de TiO2 mesoporosos (13, 20 e 40 nm de diâmetro). Os resultados obtidos demonstraram a possibilidade de se modular o desempenho dos sensores de H2O2 em função do diâmetro dos poros e da quantidade de mediador imobilizado. A união dos resultados analíticos obtidos com os dados de microscopia eletrônica de varredura possibilitou observar a importância do efeito de confinamento no desempenho dos mediadores. Além disso, dados espectroscópicos na região do visível foram fundamentais para relacionar a presença de defeitos estruturais com a reatividade do material. No fim, tais plataformas foram utilizadas para a formulação de biossensores de colina. / Nowadays, the challenges in the development of biosensors cover various aspects such as the need to improve the interface between the substrate and the biological material, the efficiency of the chemical signal transduction in a measurable one, the response time, the compatibility with biological matrices and the integration of different biological recognition elements in a single device, in order to perform detections of different analytes. In this context, the development of nanoscience has created very attractive features to optimize the aspects described above. Consequently, the present work studies the build up of nanostructured transducers that can operate more efficiently than the corresponding bulk materials (systems non-nanostructured). In one of the approaches used, a hybrid transducer consisting of copper hexacyanoferrate/polypyrrole (CuHCNFe/Ppy) had its electrochemical properties combined with the morphological and electronic properties of a felt decorated with cup-stacked type carbon nanotubes (felt/CSCNT) for development of a H2O2 sensor. Felt/CSCNT is a hydrophilic conductive mesh that allows a uniform dispersion of the hybrid transducer. This feature, coupled with the improvement of electroactive surface and with the electronic interaction among the CuHCNFe/Ppy and carbon nanotubes have created a favorable platform for the construction of a glucose biosensor. In a second strategy, polystyrene spheres with diameters of 300, 460, 600 and 800 nm were used as templates for the formation of macroporous CuHCNFe/Ppy films. The transducers were used to detect H2O2 in order to correlate the importance of pore size with the obtained analytical performance. Unlike expected, porous and bulk transducers presented very similar analytical performances, which led to a consideration of the thermodynamic properties of curved surfaces, the wettability of porous materials and the influence of electrochemical kinetics during the use of porous systems. Such platforms have also been successfully applied in the preparation of glucose and choline biosensors. Finally, it was possible to synthesize nanostructured transducers through the immobilization of Prussian blue layers and CuHCNFe inside the cavities of mesoporous TiO2 films (pore diameters of 13, 20 and 40 nm). The obtained results demonstrated the possibility of modulating the performance of H2O2 sensors according to the pore diameter and the amount of immobilized transducer. The union of the obtained analytical results with scanning electron microscopy data showed the importance of confinement effect on the transducers performances. In addition, spectroscopic data in the visible region were essential to correlate the presence of structural defects with the material reactivity. In the end, these platforms were used for the formulation of choline biosensors. Azul da Prússia Biossensor de glicose e colina Carbon nanotubes Glucose and choline biosensor Hybrid transducer Hydrogen peroxide sensor Materiais nanoestruturados Mediador híbrido Nanostructured materials Nanotubos de carbono Prussian blue Sensor de peróxido de hidrogênio Síntese assistida por molde Template assisted synthesis
56	Propriétés de commutation des analogues CoFe du bleu de Prusse : vers un contrôle de la position en énergie des états stable et métastable / Switching properties of CoFe Prussian blue analogues : towards a control of the position in terms of energy of the stable and metastable states Lejeune, Julien 26 June 2013 (has links) Les composés à commutation électronique constituent une large famille de systèmes particulièrement prometteuse, notamment pour le stockage de l’information à l’échelle moléculaire. Parmi ces composés, les analogues du bleu de Prusse cobalt-fer (ABP AxCoFe) sont des polymères inorganiques formés d’enchaînements Co-N≡C-Fe pouvant présenter deux états électroniques CoII(HS)-N≡C-FeIII(BS) et CoIII(BS)-N≡C-FeII(BS) (HS : haut spin ; BS : bas spin) aux propriétés structurales et électroniques bien distinctes. La transition électronique entre ces deux états peut être contrôlée de manière réversible par une grande variété de paramètres chimique (insertion de cations alcalins) et physiques (température, pression, irradiation). Ces propriétés de photo-commutation sont particulièrement intéressantes pour le développement de mémoires optiques à l’échelle moléculaire.Afin de comprendre les propriétés électroniques des ABP AxCoFe, nous nous sommes intéressés à l’interaction entre les centres métalliques via le pont cyanure dans l’enchaînement Co-N≡C-Fe, aussi bien sur un plan expérimental (mise en œuvre de techniques d’analyse reposant sur l’utilisation du rayonnement synchrotron) que théorique (modélisation ab initio de type post-Hartree-Fock). Nous avons également étudié la nature de l’interaction, démontrée expérimentalement, entre les cations alcalins et le réseau bimétallique formé par les enchaînements Co-N≡C-Fe. Finalement, la pertinence du modèle à deux états, habituellement utilisé pour rendre compte des propriétés électroniques des systèmes commutables, est discutée, avec la mise en évidence de multistabilités au sein des ABP AxCoFe. Ce travail propose ainsi une étude la plus complète possible des phénomènes électroniques rencontrés dans ces systèmes. / Electronically switchable compounds constitute a wide family of very promising systems, especially in the field of data storage at a molecular scale. Amongst these compounds, cobalt-iron Prussian blue analogues (AxCoFe PBAs) are inorganic polymers based on Co-N≡C-Fe linkages that may exhibit two CoII(HS)-N≡C-FeIII(LS) and CoIII(LS)-N≡C-FeII(LS) (HS: high spin; LS: low spin) electronic states with very different structural and electronic properties. Electronic transition in between these two states can be reversibly controlled by a large variety of both chemical (insertion of alkali cations) and physical (temperature, pressure, irradiation) parameters. These photo switching properties are extremely appealing for the development of optical memory devices at the molecular scale.In order to understand the electronic properties of AxCoFe PBAs, the interaction occurring between the metallic centres through the cyanide bridge in the Co-N≡C-Fe linkages was investigated both at an experimental (use of synchrotron-radiation-based analytic techniques) and a theoretical (post-Hartree-Fock ab initio modelling) levels. The nature of the experimentally-demonstrated interaction between the alkali cations and the bimetallic network, made of the Co-N≡C-Fe linkages, was also studied. Finally, the relevance of the two-state model, usually invoked to account for the electronic properties of switchable systems, is discussed, as multistabilities are evidenced in PBAs. This work therefore offers study of the electronic phenomena occurring in such systems as comprehensive as possible. Analogues du bleu de Prusse Commutation électronique Transition de spin Transfert de charge Spectroscopie infra-rouge Rayonnement synchrotron Calculs post-Hartree-Fock Prussian blue analogues Electronic switching Spin crossover Charge transfer Infra-red spectroscopy Synchrotron radiation Post-Hartree-Fock calculations
57	Composites "Oxydes nanostructurés-analogue du bleu de Prusse" : nouveau matériau pour le stockage de l'information / Composites "Nanostructured oxides of Prussian blue analogue" : new material for the information storage. Aouadi, Merwen 11 December 2012 (has links) Les analogues du bleu de Prusse sont intéressants pour le stockage de l’information car ils présentent des propriétés de photo-commutation. Afin d’intégrer et d’exploiter ces propriétés photomagnétiques dans d’éventuelles applications, il est nécessaire de faire une étape de mise en forme. Cette dernière consiste à contrôler la taille, la forme ainsi que l’arrangement tridimensionnel des nanoparticules. Une stratégie consiste à élaborer des oxydes de silice nanostructurée par le procédé sol-gel. Une méthode a consisté faire précipiter les analogues du bleu de Prusse photomagnétiques dans la nanoporosité. Ainsi, il a fallu obtenir un monolithe ayant une unique organisation et non un mélange de phases. Il a été possible d’optimiser la méthode pour obtenir un monolithe hexagonal ayant des ions cobalt. Cette méthode a pu être étendue à différentes organisations : lamellaire, cubique, hexagonale, vermiculaire. Un traitement thermique permettant d’éliminer le copolymère afin de former le nanoréacteur. Une étude a permis de montrer que l’organisation etait conservée après un traitement thermique. Les ions cobalt subissaient une thermo hydrolyse durant le traitement thermique.Il a été possible de mettre en place une méthode d’imprégnation permettant d’obtenir différents nanocomposites CoFe et de contrôler la stœchiométrie des particules d’ABP confinées.Cette méthode a permis d’élaborer des nanocomposites CoFe sans cations alcalin et des nanocomposites CoFe contenant deux cations rubidium par maille. Les propriétés magnétiques ont permis de montrer l’effet de la mise en forme. De plus cette étude a permis de montrer que les propriétés de commuation sont concervées mêmes sur des nanoparticules de 5 nm. / The Prussian blue analogues (CoFe PBA) have attracted growing interest owing to the tunability of their magnetic properties by external stimuli that make them good candidates for future optical memories or switching devices.This study need a processing step to elaborate a nanocomposite material with full control on the stoichiometry, the size, the shape and the organisation of PBA particles.Our strategie consit to precipitate photomagnetic Prussian blue analogue in the nanoporosite. Our main idea is to use mesoporous silica monoliths as template for the precipitation of the PBA in order to control the size and the shape of the nanoparticles. A silica monolith contaigning cobalt ions in the hexogonal structuraction have been obtained. The method have been extended to another structuration ( wormlike, cubic and lamallar). A termal traitement at 500°C in air have been optimised to remove the copolymer and to obtain the nanoreacteur. During the termal traitement the cobalt ion change the symmetry. A thermo-hydrolysis of the cobalt drives to the formation of monomer tetrahedron of cobalt.The precipitation of Prussian Blue Analogues is realized by impregnation with a solution of potassium hexacyanoferrate (III). The parameters of the impregnation have to be finely controlled in order to obtain nanocrystals of Co-Fe wihout alkalin cations and nanocrystrals of CoFe with two cation rubidium. A photomagnetic nanocrystrals have been obtained. Photomagnétisme Nanocomposites Silicate Analogue du bleu de Prusse Cation alcalin Procédés sol-gel Oxyde nanostructurée Monolithe mésoporeux ordonnée Photomagnetic Nanocomposites Mesoporous silica Prussian blue analogue Alkalin cation X-ray Spectroscopy Sol-gel chemistry Nanostructure oxide.
58	Nanoestruturação de filmes finos para utilização em eletrodos enzimáticos / Nanostructuration of thin films for applying in enzyme based biosensors Vinícius Romero Gonçales 12 December 2011 (has links) Os desafios atuais no desenvolvimento de biossensores abrangem diversos aspectos, tais como a necessidade de se aperfeiçoar a interface de contato entre o substrato e o material biológico, a eficiência de transdução do sinal químico em um sinal mensurável, o tempo de resposta, a compatibilidade dos biossensores com matrizes biológicas e a integração de diferentes elementos de reconhecimento biológico em um único dispositivo, visando a detecção de distintos analitos. Nesse contexto, o desenvolvimento da nanociência tem criado recursos bastante atraentes para otimizar os aspectos descritos acima. O presente trabalho apresenta, portanto, estudos realizados para a construção de mediadores nanoestruturados que possam operar de maneira mais eficiente que os correspondentes materiais maciços (sistemas não-nanoestruturados). Em uma das abordagens utilizadas, um mediador híbrido de hexacianoferrato de cobre/polipirrol (CuHCNFe/Ppy) teve suas propriedades eletroquímicas aliadas às propriedades morfológicas e eletrônicas de um feltro revestido com nanotubos de carbono do tipo \"cup-stacked\" (feltro/NTCCS) para o desenvolvimento de um sensor de H2O2. O feltro/NTCCS é uma malha hidrofílica condutora que permite uma dispersão bastante uniforme do mediador híbrido. Essa característica, aliada ao aumento da área eletroativa e à interação eletrônica existente entre o CuHCNFe/PPy e os nanotubos de carbono criaram uma plataforma favorável para a construção de um biossensor de glicose. Em uma segunda estratégia, esferas de poliestireno com diâmetros de 300, 460, 600 e 800 nm foram utilizadas como molde para a formação de filmes de CuHCNFe/PPy macroporosos. Os distintos mediadores foram aplicados na detecção de H2O2 com o intuito de se correlacionar a importância do tamanho do poro com o desempenho analítico obtido. Diferentemente do esperado, os mediadores maciços e porosos apresentaram desempenhos analíticos bastante similares, o que levou a uma consideração das propriedades termodinâmicas de superfícies curvas, da molhabilidade de materiais porosos e da influência da cinética eletroquímica na utilização de sistemas porosos. Tais plataformas também foram aplicadas com sucesso na construção de biossensores de glicose e de colina. Por fim, foi possível sintetizar mediadores nanoestruturados através da imobilização de camadas de azul da Prússia e de CuHCNFe dentro das cavidades de filmes de TiO2 mesoporosos (13, 20 e 40 nm de diâmetro). Os resultados obtidos demonstraram a possibilidade de se modular o desempenho dos sensores de H2O2 em função do diâmetro dos poros e da quantidade de mediador imobilizado. A união dos resultados analíticos obtidos com os dados de microscopia eletrônica de varredura possibilitou observar a importância do efeito de confinamento no desempenho dos mediadores. Além disso, dados espectroscópicos na região do visível foram fundamentais para relacionar a presença de defeitos estruturais com a reatividade do material. No fim, tais plataformas foram utilizadas para a formulação de biossensores de colina. / Nowadays, the challenges in the development of biosensors cover various aspects such as the need to improve the interface between the substrate and the biological material, the efficiency of the chemical signal transduction in a measurable one, the response time, the compatibility with biological matrices and the integration of different biological recognition elements in a single device, in order to perform detections of different analytes. In this context, the development of nanoscience has created very attractive features to optimize the aspects described above. Consequently, the present work studies the build up of nanostructured transducers that can operate more efficiently than the corresponding bulk materials (systems non-nanostructured). In one of the approaches used, a hybrid transducer consisting of copper hexacyanoferrate/polypyrrole (CuHCNFe/Ppy) had its electrochemical properties combined with the morphological and electronic properties of a felt decorated with cup-stacked type carbon nanotubes (felt/CSCNT) for development of a H2O2 sensor. Felt/CSCNT is a hydrophilic conductive mesh that allows a uniform dispersion of the hybrid transducer. This feature, coupled with the improvement of electroactive surface and with the electronic interaction among the CuHCNFe/Ppy and carbon nanotubes have created a favorable platform for the construction of a glucose biosensor. In a second strategy, polystyrene spheres with diameters of 300, 460, 600 and 800 nm were used as templates for the formation of macroporous CuHCNFe/Ppy films. The transducers were used to detect H2O2 in order to correlate the importance of pore size with the obtained analytical performance. Unlike expected, porous and bulk transducers presented very similar analytical performances, which led to a consideration of the thermodynamic properties of curved surfaces, the wettability of porous materials and the influence of electrochemical kinetics during the use of porous systems. Such platforms have also been successfully applied in the preparation of glucose and choline biosensors. Finally, it was possible to synthesize nanostructured transducers through the immobilization of Prussian blue layers and CuHCNFe inside the cavities of mesoporous TiO2 films (pore diameters of 13, 20 and 40 nm). The obtained results demonstrated the possibility of modulating the performance of H2O2 sensors according to the pore diameter and the amount of immobilized transducer. The union of the obtained analytical results with scanning electron microscopy data showed the importance of confinement effect on the transducers performances. In addition, spectroscopic data in the visible region were essential to correlate the presence of structural defects with the material reactivity. In the end, these platforms were used for the formulation of choline biosensors. Azul da Prússia Biossensor de glicose e colina Materiais nanoestruturados Mediador híbrido Nanotubos de carbono Sensor de peróxido de hidrogênio Síntese assistida por molde Carbon nanotubes Glucose and choline biosensor Hybrid transducer Hydrogen peroxide sensor Nanostructured materials Prussian blue Template assisted synthesis
59	Mechanistic Investigations of Metal-Metal Cooperativity in Dinickel Complexes and Iron/Cobalt Prussian Blue Analogues Stevens, Hendrik 13 May 2021 (has links) No description available. 540 Metal-Metal Cooperativity Nickel Hydride Complexes C-H Activation Low-Valent Metal Centers Preorganized Ligand Scaffold Iron/Cobalt Prussian Blue Analogues Charge-Transfer-Induced Spin Transition Transient Absorption Spectroscopy Chemie (PPN62138352X)
60	Vacancy modification of Prussian-blue nano-thin films for high energy-density microsupercapacitors with ultralow RC time constant He, Yafei, Zhang, Panpan, Wang, Faxing, Wang, Luxin, Su, Yuezeng, Zhang, Fan, Zhuang, Xiaodong, Feng, Xinliang 19 April 2021 (has links) In-plane micro-supercapacitors (MSCs), as promising power candidates for micro-devices, typically exhibit high power densities, large charge/discharge rates, and long cycling lifetimes. The high areal/volumetric capacitances, high energy/power densities, high rate capability, as well as flexibility are the main scientific pursue in recent years. Among diverse electrode materials for MSCs, coordination polymer frameworks are emerging due to the designable porous structure and tunable functionality. However, the unsatisfied electrochemical performance still hinders their practical applications. In this work, we demonstrate the first time an efficient in-situ growth approach to precisely modify the vacancy of Prussian-blue nano-thin films with pyridine by coordination reaction for high energy-density MSCs. Confirmed by the experimental results and density functional theory calculation, the vacancy modification within Prussian-blue network improved the film-forming property, hydrophilicity, and electrochemical activity of the thin films. The resultant MSCs based on pyridine-modified Prussian-blue exhibited an ultrahigh energy density of up to 12.1 mWh cm⁻³ and an ultra-low time constant (t₀) of 0.038 ms, which are the best values among the state-of-the-art in-plane MSCs. This work provides an attractive solution for structural engineering of promising active materials on molecule level toward high-performance micro-energy devices. info:eu-repo/classification/ddc/540 ddc:540 info:eu-repo/classification/ddc/660 ddc:660

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