Your search keyword '"Barbosa, Martin Schwellberger"' showing total 10 results

1. Metal oxide ion-gated transistors: A perspective on in operando characterizations and emerging Li-ion-based applications

Author

da Silva Neres, Lariel Chagas, Camargo, Luan Pereira, Azari, Ramin Karimi, Garza, José Ramón Herrera, Soavi, Francesca, Barbosa, Martin Schwellberger, and Santato, Clara

Published

2023

2. Optimized Drop-Casted Polyaniline Thin Films for High-Sensitivity Electrochemical and Optical pH Sensors.

Author

Mücke, Bruna Eduarda Darolt, Rossignatti, Beatriz Cotting, Abegão, Luis Miguel Gomes, Barbosa, Martin Schwellberger, and Mello, Hugo José Nogueira Pedroza Dias

Subjects

CHEMICAL properties, CONDUCTING polymers, CHEMICAL detectors, SUBSTRATES (Materials science), ELECTROCHEMICAL sensors

Abstract

Conducting polymers used in chemical sensors are attractive because of their ability to confer reversible properties controlled by the doping/de-doping process. Polyaniline (PANI) is one of the most prominent materials used due to its ease of synthesis, tailored properties, and higher stability. Here, PANI thin films deposited by the drop-casting method on fluorine-doped tin oxide (FTO) substrates were used in electrochemical and optical sensors for pH measurement. The response of the devices was correlated with the deposition parameters; namely, the volume of deposition solution dropped on the substrate and the concentration of the solution, which was determined by the weight ratio of polymer to solvent. The characterisation of the samples aimed to determine the structure–property relationship of the films and showed that the chemical properties, oxidation states, and protonation level are similar for all samples, as concluded from the cyclic voltammetry and UV–VIS spectroscopic analysis. The sensing performance of the PANI film is correlated with its relative physical properties, thickness, and surface roughness. The highest electrochemical sensitivity obtained was 127.3 ± 6.2 mV/pH, twice the Nernst limit—the highest pH sensitivity reported to our knowledge—from the thicker and rougher sample. The highest optical sensitivity, 0.45 ± 0.05 1/pH, was obtained from a less rough sample, which is desirable as it reduces light scattering and sample oxidation. The results presented demonstrate the importance of understanding the structure–property relationship of materials for optimised sensors and their potential applications where high-sensitivity pH measurement is required. [ABSTRACT FROM AUTHOR]

Published

2024

3. A study of the doping process in Li4Ti5O12 and TiO2 battery electrode materials studied in the ion-gated transistor configuration

Author

Garza, José Ramón Herrera, primary, Camargo, Luan Pereira, additional, Azari, Ramin Karimi, additional, Neres, Lariel Chagas da Silva, additional, Khaleel, Shahid, additional, Barbosa, Martin Schwellberger, additional, Soavi, Francesca, additional, and Santato, Clara, additional

Published

2024

4. WebCiência como estratégia de articulação entre comunicação científica e extensão universitária

Author

SGOBBI, Lívia Flório, primary, SEVERINO, Vanessa Gisele Pasqualotto, additional, BARBOSA, Martin Schwellberger, additional, CLEMENTE, Alan Dumont, additional, PAIVA, João Vitor Fernandes, additional, and FERRI, Pedro Henrique, additional

Published

2023

5. A study of the doping process in Li4Ti5O12 and TiO2 battery electrode materials studied in the ion-gated transistor configuration.

Author

Garza, José Ramón Herrera, Camargo, Luan Pereira, Azari, Ramin Karimi, Neres, Lariel Chagas da Silva, Khaleel, Shahid, Barbosa, Martin Schwellberger, Soavi, Francesca, and Santato, Clara

Abstract

Understanding how the electronic conductivity of metal oxides used as electrode materials in Li-ion batteries (LIBs) evolves as a function of the degree of lithiation/delithiation is relevant to try to prolong the battery lifetime, which affects, among others, the sustainability of LIBs. We propose the use of ion-gated transistors (IGTs) employed as transistor channel material films of Li4Ti5O12 (LTO) and TiO2 interfaced to the ionic liquid 1-ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ([EMIM][TFSI]) including the salt LiTFSI, to study the evolution of the doping mechanism, charge carrier density and mobility with the advancement of lithiation/delithiation in the films. The process of lithiation/delithiation is controlled by the electrical bias applied at the gate electrode, made of carbon paper coated with high surface area activated carbon. The sweeping rate of the gate bias affects the kinetics of Li intercalation/deintercalation and, consequently, the electronic doping of the transistor channel. We discuss how different doping mechanisms, namely electrostatic, "purely" electrochemical, or electrochemical possibly associated with structural changes in the transistor channel are possible for the metal oxide films. We consider such a discussion relevant to contribute to the optimal use of the electrode materials in LIBs. [ABSTRACT FROM AUTHOR]

Published

2024

6. Thin Films of Polyaniline-Based Nanocomposites with CeO2 and WO3 Metal Oxides Applied to the Impedimetric and Capacitive Transducer Stages in Chemical Sensors

Author

Rossignatti, Beatriz Cotting, primary, Vieira, Amanda Portes, additional, Barbosa, Martin Schwellberger, additional, Abegão, Luís Miguel Gomes, additional, and Mello, Hugo José Nogueira Pedroza Dias, additional

Published

2023

7. Thin Films of Polyaniline-Based Nanocomposites with CeO 2 and WO 3 Metal Oxides Applied to the Impedimetric and Capacitive Transducer Stages in Chemical Sensors.

Author

Rossignatti, Beatriz Cotting, Vieira, Amanda Portes, Barbosa, Martin Schwellberger, Abegão, Luís Miguel Gomes, and Mello, Hugo José Nogueira Pedroza Dias

Subjects

CHEMICAL detectors, CERIUM oxides, METALLIC oxides, THIN films, POLYMERIC nanocomposites, TUNGSTEN trioxide, NANOCOMPOSITE materials

Abstract

There is a recognized need for the development of cost-effective, stable, fast, and optimized novel materials for technological applications. Substantial research has been undertaken on the role of polymeric nanocomposites in sensing applications. However, the use of PANI-based nanocomposites in impedimetric and capacitive electrochemical sensors has yet to be understood. The present study aimed to explore the relationship between the sensitivity and linearity of electrochemical pH sensors and the composition of nanocomposites. Thin films of PANI/CeO2 and PANI/WO3 were deposited via spin coating for characterization and application during the electrochemical impedance and capacitance spectroscopy (EIS and ECS) transduction stages. The findings showed that the optimized performance of the devices was extended not only to the sensitivity but also to the linearity. An increase of 213% in the ECS sensitivity of the PANI/CeO2 compared to the metal oxide and an increase of 64% in the ECS linearity of the PANI/WO3 compared to the polymeric sensitivity were reported. This study identified the structure–property relationship of nanocomposite thin films of PANI with metal oxides for use in electrochemical sensors. The developed materials could be applied in devices to be used in different fields, such as food, environment, and biomedical monitoring. [ABSTRACT FROM AUTHOR]

Published

2023

8. Metal oxide ion-gated transistors: A perspective on in operandocharacterizations and emerging Li-ion-based applications

Author

da Silva Neres, Lariel Chagas, Camargo, Luan Pereira, Azari, Ramin Karimi, Garza, José Ramón Herrera, Soavi, Francesca, Barbosa, Martin Schwellberger, and Santato, Clara

Abstract

Graphical abstract: Schematic representations of ion-gated transistors (IGT) making use of a metal oxide as semiconductor channel

Published

2023

9. Study of performance and operation mechanisms on electrolyte-gated transistors based on tungsten oxide

Author

Barbosa, Martin Schwellberger, Universidade Estadual Paulista (Unesp), and Orlandi, Marcelo Ornaghi [UNESP]

Subjects

Transistor de contato eletrolítico, Óxido de tungstênio, Electrolyte-gated transistor, Hydrogen sensor, Eletroquímica, Electrochemistry, Tungsten oxide, Sensor de hidrogênio

Abstract

Submitted by Martin Schwellberger Barbosa (martin.s.barbosa@unesp.br) on 2019-04-25T19:02:30Z No. of bitstreams: 1 tese_martin_barbosa_definitiva.pdf: 5142601 bytes, checksum: fb47da0649ecb89f423fa8e1872afbe4 (MD5) Approved for entry into archive by Ana Carolina Gonçalves Bet null (abet@iq.unesp.br) on 2019-04-29T23:44:58Z (GMT) No. of bitstreams: 1 barbosa_ms_dr_araiq_par.pdf: 1026707 bytes, checksum: e3317c5b221bd8a3694fb33a0361fe1d (MD5) Made available in DSpace on 2019-04-29T23:44:58Z (GMT). No. of bitstreams: 1 barbosa_ms_dr_araiq_par.pdf: 1026707 bytes, checksum: e3317c5b221bd8a3694fb33a0361fe1d (MD5) Previous issue date: 2019-04-15 Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) Neste trabalho estudou-se sistemas de materiais derivados de trióxido de tungstênio (WO3) com diferentes eletrólitos para aplicações em transistores de filme fino com interface eletrolítica (EG-TFTs). Os materiais apresentaram diversas fases cristalinas (hexagonal, monoclínica, amorfa) e diferentes morfologias (granular, nanofibras, nanoplacas, nanopartículas e filmes lisos). Os principais eletrólitos utilizados foram líquidos iônicos e géis iônicos, contendo o cátion imidazolium. A motivação deste trabalho foi contribuir para o desenvolvimento do campo da iontrônica, ou seja, dispositivos em que a propriedade de um semicondutor é controlada por meio de fenômenos eletroquímicos. O uso de diferentes morfologias foi uma estratégia para controlar o desempenho dos dispositivos por meio das suas propriedades intrínsecas. Os materiais foram sintetizados por rotas químicas úmidas (sol-gel e hidrotermal) e de evaporação (RF sputtering). Caracterizações incluíram microscopia eletrônica, difração de raios X, espectroscopia de fotoelétrons, espectrometria de retroespalhamento Rutherford e área superficial (BET). Um estudo sistemático de operação de dispositivos transistors foi realizado utilizando os materiais granulares, nanofibras e nanoplacas com dois géis iônicos ([EMIM][TFSI]SOS e [EMIM][TFSI]SMS). Resultados de voltametria cíclica indicaram mecanismos eletroquímicos de dopagem com redução das espécies de W6+ com intercalação de prótons gerados a partir de resquícios de água. Além disso foi atribuído um mecanismo de dopagem química direta, com evolução eletroquímica de H2. Esses processos tiveram influência na modulação da condutividade do canal durante a operação dos dispositivos observando-se correlação entre os potenciais em que ocorriam aumentos de condutividade e os potenciais dos picos associados à redução. As diferentes morfologias apresentaram diferentes padrões de oxidoredução eletroquímica, que foram atribuídos ao arranjo iônico, e diferentes níveis de modulação, correspondentes à diferença na condução elétrica entre as partículas. Materiais com morfologia de nanoplacas tiveram maior desempenho de modulação de corrente e mobilidade de portadores, atingindo valores típicos de dispositivos de arquitetura de contato eletrolítico de alta eficiência. Os transistors foram também caracterizados em atmosferas com composição variável contendo H2, O2 e N2. Os objetivos foram elucidar os mecanismos de dopagem química e propor uma aplicação desses sistemas como sensores de gases. Observou-se que, principalmente principalmente com eletrodos de Pt, ocorreu uma dopagem irreversível dos filmes de WO3 com H2 por intermédio da interface eletrolítica, resultando na modulação da condutividade do semicondutor. A reversibilidade dessa dopagem ocorreu na presença de O2. Por fim, os mecanismos eletrostáticos dos transistors foram estudados por meio de perfis força-distância por microscopia de força atômica inoperando em EG-TFTs utilizando o liquido iônico [EMIM][TFSI]. Esses resultados indicaram que a camada iônica era altamente organizada mesmo que a superfície do WO3 fosse composta por nanopartículas. A espessura da primeira camada correspondeu a aproximadamente a dimensão de um cátion [EMIM]+. Além disso, essa camada foi deslocada para uma região mais próxima da superfície com a aplicação de campo elétrico, principalmente nas regiões centrais dos grãos. Os resultados obtidos neste trabalho reforçam a potencialidade da interface WO3 com líquidos iônicos para aplicações iontrônicas destacando como os mecanismos de dopagem podem ser usados de maneira estratégica para obter dispositivos com melhor desempenho. This work was focused in tungsten oxide materials interfaced with multiple electrolytes for applications in electrolyte gated thin-film transistors (EG-TFTs). The materials presented different crystalline phases (hexagonal, monoclinic, amorphous) and different morphologies (granular, nanofibers, nanoplates and smooth films). The electrolytes considered included ion gels and ionic liquids using the imidazolium cation.The main motivation for this study was the interest for the developments in the field of iontronics, with devices that control the proprieties of semiconductors through electrochemical phenomena. The approach of using different materials was aimed to improve the devices using the materials intrinsic proprieties. The materials were synthetized using wet-chemical routes (sol-gel, hydrothermal) and evaporation (RF sputtering). Multiple characterizations techniques were used including scanning electron microscopy, X-ray diffraction, X-ray photoelectron spectroscopy, Rutherford backscattering spectrometry and surface area analysis (BET). A systematic study was performed using the granular, nanofiber and nanoplate materials interfaced with [EMIM][TFSI]SOS and [EMIM][TFSI]SMS ion gels. Cyclic voltammetry characterization indicated electrochemical doping mechanisms with the reduction of W6+ species with intercalation of protons from water in the electrolyte phase. A secondary direct chemical reduction mechanism intermediated by H2 electrochemical evolution was also observed. Both phenomena were attributed to the WO3 conductivity modulation, as increases in the value of the conductivity were correlated with the voltages where reduction peaks were observed. The materials of different morphologies presented different electrochemical peaks patterns that were attributed to the ionic arrangements and different modulation levels that were attributed to the different current conduction between particles. The materials with nanoplate morphology exhibited the best on/off ratio and electronic mobility, with figures-ofmerit reaching values typical of efficient electrolyte gated devices. The transistors were characterized under different atmospheric conditions containing H2, N2 and O2. This was performed in order to understand the direct chemical reduction mechanism and to test the devices for potential hydrogen sensor applications. It was observed that the films went through irreversible doping processes in the presence of H2 that were facilitated by the electrochemical bias and Pt electrodes. The reversibility of the doping processes was observed in the presence of O2. Lastly, the electrostatic mechanisms were studied by atomic force microscopy in-operando, using force distance profiling, in EG-TFT devices using the ionic liquid [EMIM][TFSI]. Results indicated that the ion layering is well organized even on the relatively rough film composed of WO3 nanoparticles. The thickness of the first ion layer was attributed to the distance of a single [EMIM]+ cation. It was observed that this layer could be shifted to a position closer to the surface with electrochemical bias, especially for measurements in the top of the grains. Overall the results in this work reinforce the potential applications of WO3 materials interfaced with ionic liquids and ion gels for iontronic applications and highlights how doping mechanisms can be used strategically for the optimization of the devices. FAPESP 2014/27079-9 FAPESP 2016/09033-7

Published

2019

10. Caracterização de estruturas de óxido de estanho modificado como sensores de gases

Author

Barbosa, Martin Schwellberger [UNESP], Universidade Estadual Paulista (Unesp), Orlandi, Marcelo Ornaghi [UNESP], and Varela, José Arana [UNESP]

Subjects

Nanotecnologia, Nanopartículas, Nanoparticles, Catalise, Detectores, Gases - Absorção e adsorção

Abstract

Made available in DSpace on 2015-07-13T12:10:21Z (GMT). No. of bitstreams: 0 Previous issue date: 2015-02-27. Added 1 bitstream(s) on 2015-07-13T12:25:22Z : No. of bitstreams: 1 000825496_20160314.pdf: 89444 bytes, checksum: a7d4704dc3c9f4ec144ba91ce5b947b0 (MD5) Bitstreams deleted on 2016-03-14T11:16:22Z: 000825496_20160314.pdf,. Added 1 bitstream(s) on 2016-03-14T11:17:04Z : No. of bitstreams: 1 000825496.pdf: 10357853 bytes, checksum: c8f8295e8f37b2fae30a0285b242c45d (MD5) Sensores de gases são tecnologias baseadas em materiais que apresentam mudança em alguma propriedade física mensurável que varia com a presença de um gás analito, de forma que a variação na propriedade pode ser relacionada a presença e concentração do gás analisado. A busca por materiais capazes de possibilitar a construção de sensores mais eficientes, assim como o estudo da natureza dessas interações foi a principal motivação desse trabalho. O trabalho consistiu em realizar uma modificação superficial em estruturas de monóxido de estanho com duas morfologias distintas, por meio da deposição de nanopartículas de metais nobres (Pt, Pd, Ag) na sua superfície (decoração superficial), e estudar o efeito catalítico proporcionado por esse tipo de modificação. Os materiais de monóxido de estanho foram sintetizados por meio da redução carbotérmica em atmosfera inerte e os materiais com morfologias distintas foram separados por meio de decantação. Para a decoração, utilizou-se o método químico redutivo self-assembly em que as estruturas foram adicionadas a dispersões de nanopartículas dos metais de interesse, e submetidas a um programa de aquecimento. As dispersões de nanopartículas metálicas foram preparadas pelo processo de redução poliol, em reações de redução a partir de sais, com Etilenoglicol e PVP. As análises por SEM e TEM mostraram que as partículas se depositaram sobre a superfície das estruturas das nanoestruturas, de forma dispersa. A caracterização elétrica simultânea das estruturas puras e modificadas em atmosfera de ar sintético e com H2, NO2 e CO permitiu o estudo destas como sensores de gases. Observou-se variações na resistividade das estruturas modificadas e puras assim como diferenças na sensibilidade para esses gases indicando que os metais atuaram como catalisadores para a interação com os gases redutores (CO e H2) e como... Gas Sensors are technology based on materials that have a measurable physical propriety that changes in the presence of a specific gas. The search for materials that will allow the design of efficient gas sensors, and allow the understanding of those interactions were the main motivation behind this study. The project consisted in the functionalization of the surface of tin monoxide based materials with noble metals nanoparticles (Pt, Pd and Ag) and study the effect caused by this kind of surface modification. The tin monoxide materials were synthetized by carbothermal reduction, in inert atmosphere conditions. The surface modification was achieved by a wet chemical rout, by adding metallic nanoparticles dispersions to the oxides and submitting the mixture to a thermal treatment. The metallic nanoparticles dispersions were synthetized by the poliol reduction process, through chemical reduction reactions using the correspondents' salts, ethylene glycol and PVP as precursors. SEM and TEM analysis of the modified structures indicate that the nanoparticles were deposited over the oxides surface, with good dispersion. Electrical characterization on both pure and modified structures in synthetic air and in the presence of multiple gases (NO2, H2 and CO) allowed the characterization of the samples as gas sensors. There were differences in the electrical characteristics of the different samples and their sensitivities were altered by the surface modification, indicating that the nanoparticles were acting as catalysts in the interaction of the oxide with reducing gases (H2 and CO) and as deactivators in the interaction with NO2, suggesting that chemical and electrical sensitization are happening. Electrochemical Impedance Spectroscopy was used to further investigate those processes, so that a model for the effects caused by the modifiers could be proposed.

Published

2015