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Artigo de periodico
High transconductance on thiophene-based vertical organic electrochemical transistors (2025)
Luginieski, Marcos ; Barbosa, Henrique Frulani de Paula ; Kumar, Ankush ; Schander, Andreas ; Faria, Gregório Couto ; Lüssem, Björn
Source: Advanced Materials Technologies. Unidade: IFSC
Subjects: ELETROQUÍMICA ORGÂNICA, TRANSISTORES
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ABNT
LUGINIESKI, Marcos et al. High transconductance on thiophene-based vertical organic electrochemical transistors. Advanced Materials Technologies, v. 10, n. 24, p. e01083-1-e01083-9 + supporting information, 2025Tradução . . Disponível em: https://doi.org/10.1002/admt.202501083. Acesso em: 23 jan. 2026.
APA
Luginieski, M., Barbosa, H. F. de P., Kumar, A., Schander, A., Faria, G. C., & Lüssem, B. (2025). High transconductance on thiophene-based vertical organic electrochemical transistors. Advanced Materials Technologies, 10( 24), e01083-1-e01083-9 + supporting information. doi:10.1002/admt.202501083
NLM
Luginieski M, Barbosa HF de P, Kumar A, Schander A, Faria GC, Lüssem B. High transconductance on thiophene-based vertical organic electrochemical transistors [Internet]. Advanced Materials Technologies. 2025 ; 10( 24): e01083-1-e01083-9 + supporting information.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.202501083
Vancouver
Luginieski M, Barbosa HF de P, Kumar A, Schander A, Faria GC, Lüssem B. High transconductance on thiophene-based vertical organic electrochemical transistors [Internet]. Advanced Materials Technologies. 2025 ; 10( 24): e01083-1-e01083-9 + supporting information.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.202501083
Artigo de periodico
Remote luminescent temperature sensing using 3D-Printed Eu(III)-doped micropolymers at the tip of an optical fiber (2025)
Baltieri, Ricardo Santos ; Reupert, Aaron ; Manzani, Danilo ; Wondraczek, Lothar
Source: Advanced Materials Technologies. Unidade: IQSC
Subjects: IMPRESSÃO 3-D, FIBRAS ÓPTICAS, LUMINESCÊNCIA, LANTANÍDIOS, POLIMERIZAÇÃO
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ABNT
BALTIERI, Ricardo Santos et al. Remote luminescent temperature sensing using 3D-Printed Eu(III)-doped micropolymers at the tip of an optical fiber. Advanced Materials Technologies, p. 2401877 (1 of 8), 2025Tradução . . Disponível em: https://doi.org/10.1002/admt.202401877. Acesso em: 23 jan. 2026.
APA
Baltieri, R. S., Reupert, A., Manzani, D., & Wondraczek, L. (2025). Remote luminescent temperature sensing using 3D-Printed Eu(III)-doped micropolymers at the tip of an optical fiber. Advanced Materials Technologies, 2401877 (1 of 8). doi:10.1002/admt.202401877
NLM
Baltieri RS, Reupert A, Manzani D, Wondraczek L. Remote luminescent temperature sensing using 3D-Printed Eu(III)-doped micropolymers at the tip of an optical fiber [Internet]. Advanced Materials Technologies. 2025 ; 2401877 (1 of 8).[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.202401877
Vancouver
Baltieri RS, Reupert A, Manzani D, Wondraczek L. Remote luminescent temperature sensing using 3D-Printed Eu(III)-doped micropolymers at the tip of an optical fiber [Internet]. Advanced Materials Technologies. 2025 ; 2401877 (1 of 8).[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.202401877
Artigo de periodico
Tunable mass transport and enhanced electrochemical performance of CO2 laser engraved electrodes (2025)
Farias, Davi Marques de ; Meloni, Gabriel Negrão ; Paixão, Thiago Regis Longo Cesar da
Source: Advanced Materials Technologies. Unidade: IQ
Subjects: TRANSPORTE DE MASSA, ELETROQUÍMICA, ELETRODO
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ABNT
FARIAS, Davi Marques de e MELONI, Gabriel Negrão e PAIXÃO, Thiago Regis Longo Cesar da. Tunable mass transport and enhanced electrochemical performance of CO2 laser engraved electrodes. Advanced Materials Technologies, p. 1-10, 2025Tradução . . Disponível em: https://dx.doi.org/10.1002/admt.202501374. Acesso em: 23 jan. 2026.
APA
Farias, D. M. de, Meloni, G. N., & Paixão, T. R. L. C. da. (2025). Tunable mass transport and enhanced electrochemical performance of CO2 laser engraved electrodes. Advanced Materials Technologies, 1-10. doi:10.1002/admt.202501374
NLM
Farias DM de, Meloni GN, Paixão TRLC da. Tunable mass transport and enhanced electrochemical performance of CO2 laser engraved electrodes [Internet]. Advanced Materials Technologies. 2025 ; 1-10.[citado 2026 jan. 23 ] Available from: https://dx.doi.org/10.1002/admt.202501374
Vancouver
Farias DM de, Meloni GN, Paixão TRLC da. Tunable mass transport and enhanced electrochemical performance of CO2 laser engraved electrodes [Internet]. Advanced Materials Technologies. 2025 ; 1-10.[citado 2026 jan. 23 ] Available from: https://dx.doi.org/10.1002/admt.202501374
Artigo de periodico
Self-gelling quinone-based wearable microbattery (2024)
Bertaglia, Thiago ; Kerr, Emily F ; Sedenho, Graziela Cristina ; Wong, Andrew A. ; Colombo, Rafael N. P ; Macedo, Lucyano Jefferson Alves de ; Iost, Rodrigo Michelin ; Faria, Luana Cristina Italiano ; Lima, Filipe C. D. A. ; Teobaldo, Gabriel B. M. ; Oliveira, Cristiano Luis Pinto de ; Aziz, Michael J ; Gordon, Roy G ; Crespilho, Frank Nelson
Source: Advanced Materials Technologies. Unidades: IF, IQSC
Subjects: BIOENGENHARIA, ELETROQUÍMICA, MATERIAIS, GEL (FORMAS FARMACÊUTICAS)
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ABNT
BERTAGLIA, Thiago et al. Self-gelling quinone-based wearable microbattery. Advanced Materials Technologies, p. 2400623, 2024Tradução . . Disponível em: https://doi.org/10.1002/admt.202400623. Acesso em: 23 jan. 2026.
APA
Bertaglia, T., Kerr, E. F., Sedenho, G. C., Wong, A. A., Colombo, R. N. P., Macedo, L. J. A. de, et al. (2024). Self-gelling quinone-based wearable microbattery. Advanced Materials Technologies, 2400623. doi:10.1002/admt.202400623
NLM
Bertaglia T, Kerr EF, Sedenho GC, Wong AA, Colombo RNP, Macedo LJA de, Iost RM, Faria LCI, Lima FCDA, Teobaldo GBM, Oliveira CLP de, Aziz MJ, Gordon RG, Crespilho FN. Self-gelling quinone-based wearable microbattery [Internet]. Advanced Materials Technologies. 2024 ;2400623.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.202400623
Vancouver
Bertaglia T, Kerr EF, Sedenho GC, Wong AA, Colombo RNP, Macedo LJA de, Iost RM, Faria LCI, Lima FCDA, Teobaldo GBM, Oliveira CLP de, Aziz MJ, Gordon RG, Crespilho FN. Self-gelling quinone-based wearable microbattery [Internet]. Advanced Materials Technologies. 2024 ;2400623.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.202400623
Artigo de periodico
Controlling the inkjet printing process for electrochemical (Bio)sensors (2023)
Pradela Filho, Lauro Antonio ; Gongoni, Juliana Luz Melo ; Arantes, Iana Vitoria Spadini ; Farias, Davi Marques de ; Paixão, Thiago Regis Longo Cesar da
Source: Advanced Materials Technologies. Unidade: IQ
Subjects: IMPRESSÃO, SENSORES QUÍMICOS, ELETROQUÍMICA
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ABNT
PRADELA FILHO, Lauro Antonio et al. Controlling the inkjet printing process for electrochemical (Bio)sensors. Advanced Materials Technologies, v. 2023, p. 1-9 art. 2201729, 2023Tradução . . Disponível em: https://doi.org/10.1002/admt.202201729. Acesso em: 23 jan. 2026.
APA
Pradela Filho, L. A., Gongoni, J. L. M., Arantes, I. V. S., Farias, D. M. de, & Paixão, T. R. L. C. da. (2023). Controlling the inkjet printing process for electrochemical (Bio)sensors. Advanced Materials Technologies, 2023, 1-9 art. 2201729. doi:10.1002/admt.202201729
NLM
Pradela Filho LA, Gongoni JLM, Arantes IVS, Farias DM de, Paixão TRLC da. Controlling the inkjet printing process for electrochemical (Bio)sensors [Internet]. Advanced Materials Technologies. 2023 ; 2023 1-9 art. 2201729.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.202201729
Vancouver
Pradela Filho LA, Gongoni JLM, Arantes IVS, Farias DM de, Paixão TRLC da. Controlling the inkjet printing process for electrochemical (Bio)sensors [Internet]. Advanced Materials Technologies. 2023 ; 2023 1-9 art. 2201729.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.202201729
Artigo de periodico
Stretchable Sensors for Nanomolar Glucose Detection (2020)
Imamura, Amanda Hikari; Zakashansky, Julia; Cho, Kenny; Lin, Lancy; Carrilho, Emanuel ; Khine, Michelle
Source: Advanced Materials Technologies. Unidade: IQSC
Assunto: ELETRODO
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ABNT
IMAMURA, Amanda Hikari et al. Stretchable Sensors for Nanomolar Glucose Detection. Advanced Materials Technologies, p. 1-6, 2020Tradução . . Disponível em: https://doi.org/10.1002/admt.201900843. Acesso em: 23 jan. 2026.
APA
Imamura, A. H., Zakashansky, J., Cho, K., Lin, L., Carrilho, E., & Khine, M. (2020). Stretchable Sensors for Nanomolar Glucose Detection. Advanced Materials Technologies, 1-6. doi:10.1002/admt.201900843
NLM
Imamura AH, Zakashansky J, Cho K, Lin L, Carrilho E, Khine M. Stretchable Sensors for Nanomolar Glucose Detection [Internet]. Advanced Materials Technologies. 2020 ;1-6.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.201900843
Vancouver
Imamura AH, Zakashansky J, Cho K, Lin L, Carrilho E, Khine M. Stretchable Sensors for Nanomolar Glucose Detection [Internet]. Advanced Materials Technologies. 2020 ;1-6.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.201900843
Artigo de periodico
Organic transistors incorporating lipid monolayers for drug interaction studies (2020)
Cavassin, Priscila; Pappa, Anna-Maria; Pitsalidis, Charalampos; Barbosa, Henrique Frulani de Paula ; Colucci, Renan; Saez, Janire; Tuchman, Yaakov; Salleo, Alberto; Faria, Gregório Couto ; Owens, Róisín M.
Source: Advanced Materials Technologies. Unidades: IFSC, EESC
Subjects: ANESTÉSICOS, LIDOCAÍNA, TRANSISTORES, MEMBRANAS (BIOLOGIA)
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ABNT
CAVASSIN, Priscila et al. Organic transistors incorporating lipid monolayers for drug interaction studies. Advanced Materials Technologies, v. 5, n. 3, p. 1900680-1-1900680-5, 2020Tradução . . Disponível em: https://doi.org/10.1002/admt.201900680. Acesso em: 23 jan. 2026.
APA
Cavassin, P., Pappa, A. -M., Pitsalidis, C., Barbosa, H. F. de P., Colucci, R., Saez, J., et al. (2020). Organic transistors incorporating lipid monolayers for drug interaction studies. Advanced Materials Technologies, 5( 3), 1900680-1-1900680-5. doi:10.1002/admt.201900680
NLM
Cavassin P, Pappa A-M, Pitsalidis C, Barbosa HF de P, Colucci R, Saez J, Tuchman Y, Salleo A, Faria GC, Owens RM. Organic transistors incorporating lipid monolayers for drug interaction studies [Internet]. Advanced Materials Technologies. 2020 ; 5( 3): 1900680-1-1900680-5.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.201900680
Vancouver
Cavassin P, Pappa A-M, Pitsalidis C, Barbosa HF de P, Colucci R, Saez J, Tuchman Y, Salleo A, Faria GC, Owens RM. Organic transistors incorporating lipid monolayers for drug interaction studies [Internet]. Advanced Materials Technologies. 2020 ; 5( 3): 1900680-1-1900680-5.[citado 2026 jan. 23 ] Available from: https://doi.org/10.1002/admt.201900680

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