Filtros : "Haigh, Sarah J" Limpar

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  • Source: ACS Catalysis. Unidades: IQ, ESALQ

    Subjects: NANOPARTÍCULAS, OURO, HIDROGÊNIO

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    • ABNT

      RODRIGUES, Maria Paula de Souza et al. Gold–rhodium nanoflowers for the plasmon-enhanced hydrogen evolution Reaction under visible light. ACS Catalysis, v. 11, n. 21, p. 13543−13555, 2021Tradução . . Disponível em: https://doi.org/10.1021/acscatal.1c02938. Acesso em: 06 nov. 2024.
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      Rodrigues, M. P. de S., Dourado, A. H. B., Cutolo, L. de O., Parreira, L. S., Alves, T. V., Slater, T. J. A., et al. (2021). Gold–rhodium nanoflowers for the plasmon-enhanced hydrogen evolution Reaction under visible light. ACS Catalysis, 11( 21), 13543−13555. doi:10.1021/acscatal.1c02938
    • NLM

      Rodrigues MP de S, Dourado AHB, Cutolo L de O, Parreira LS, Alves TV, Slater TJA, Haigh SJ, Camargo PHC de, Torresi SIC de. Gold–rhodium nanoflowers for the plasmon-enhanced hydrogen evolution Reaction under visible light [Internet]. ACS Catalysis. 2021 ; 11( 21): 13543−13555.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1021/acscatal.1c02938
    • Vancouver

      Rodrigues MP de S, Dourado AHB, Cutolo L de O, Parreira LS, Alves TV, Slater TJA, Haigh SJ, Camargo PHC de, Torresi SIC de. Gold–rhodium nanoflowers for the plasmon-enhanced hydrogen evolution Reaction under visible light [Internet]. ACS Catalysis. 2021 ; 11( 21): 13543−13555.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1021/acscatal.1c02938
  • Source: Nanoscale. Unidade: IQ

    Subjects: CATALISADORES, ENERGIA SOLAR

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      FREITAS, Isabel C. de et al. Design-controlled synthesis of IrO2 sub-monolayers on Au nanoflowers: marrying plasmonic and electrocatalytic properties. Nanoscale, v. 12, p. 12281–12291 art. 12281 : + Supplementary Materials ( S1-S23), 2020Tradução . . Disponível em: https://doi.org/10.1039/d0nr01875a. Acesso em: 06 nov. 2024.
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      Freitas, I. C. de, Parreira, L. S., Barbosa, E. C. M., Novaes, B. A., Mou, T., Alves, T. V., et al. (2020). Design-controlled synthesis of IrO2 sub-monolayers on Au nanoflowers: marrying plasmonic and electrocatalytic properties. Nanoscale, 12, 12281–12291 art. 12281 : + Supplementary Materials ( S1-S23). doi:10.1039/d0nr01875a
    • NLM

      Freitas IC de, Parreira LS, Barbosa ECM, Novaes BA, Mou T, Alves TV, Quiroz J, Wang Y-C, Slater TJ, Thomas A, Wang B, Haigh SJ, Camargo PHC de. Design-controlled synthesis of IrO2 sub-monolayers on Au nanoflowers: marrying plasmonic and electrocatalytic properties [Internet]. Nanoscale. 2020 ; 12 12281–12291 art. 12281 : + Supplementary Materials ( S1-S23).[citado 2024 nov. 06 ] Available from: https://doi.org/10.1039/d0nr01875a
    • Vancouver

      Freitas IC de, Parreira LS, Barbosa ECM, Novaes BA, Mou T, Alves TV, Quiroz J, Wang Y-C, Slater TJ, Thomas A, Wang B, Haigh SJ, Camargo PHC de. Design-controlled synthesis of IrO2 sub-monolayers on Au nanoflowers: marrying plasmonic and electrocatalytic properties [Internet]. Nanoscale. 2020 ; 12 12281–12291 art. 12281 : + Supplementary Materials ( S1-S23).[citado 2024 nov. 06 ] Available from: https://doi.org/10.1039/d0nr01875a
  • Source: Nano Letters. Unidade: IQ

    Subjects: HIDROGENAÇÃO, PLATINA

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      QUIROZ, Jhon et al. Controlling reaction selectivity over hybrid plasmonic nanocatalysts. Nano Letters, v. 18, p. 7289-7297, 2018Tradução . . Disponível em: https://doi.org/10.1021/acs.nanolett.8b03499. Acesso em: 06 nov. 2024.
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      Quiroz, J., Barbosa, E. C. M., Araújo, T. P., Fiorio, J. L., Wang, Y. -C., Zou, Y. -C., et al. (2018). Controlling reaction selectivity over hybrid plasmonic nanocatalysts. Nano Letters, 18, 7289-7297. doi:10.1021/acs.nanolett.8b03499
    • NLM

      Quiroz J, Barbosa ECM, Araújo TP, Fiorio JL, Wang Y-C, Zou Y-C, Mou T, Alves TV, Oliveira DC de, Wang B, Haigh SJ, Rossi LM, Camargo PHC de. Controlling reaction selectivity over hybrid plasmonic nanocatalysts [Internet]. Nano Letters. 2018 ; 18 7289-7297.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1021/acs.nanolett.8b03499
    • Vancouver

      Quiroz J, Barbosa ECM, Araújo TP, Fiorio JL, Wang Y-C, Zou Y-C, Mou T, Alves TV, Oliveira DC de, Wang B, Haigh SJ, Rossi LM, Camargo PHC de. Controlling reaction selectivity over hybrid plasmonic nanocatalysts [Internet]. Nano Letters. 2018 ; 18 7289-7297.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1021/acs.nanolett.8b03499
  • Source: Chemical Communications. Unidade: IQ

    Subjects: NANOTECNOLOGIA, MATERIAIS NANOESTRUTURADOS, CATÁLISE

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      SILVA, Anderson G. M. da et al. Galvanic replacement reaction: recent developments for engineering metal nanostructures towards catalytic applications. Chemical Communications, v. 53, p. 7135-7148, 2017Tradução . . Disponível em: https://doi.org/10.1039/c7cc02352a. Acesso em: 06 nov. 2024.
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      Silva, A. G. M. da, Rodrigues, T. S., Haigh, S. J., & Camargo, P. H. C. de. (2017). Galvanic replacement reaction: recent developments for engineering metal nanostructures towards catalytic applications. Chemical Communications, 53, 7135-7148. doi:10.1039/c7cc02352a
    • NLM

      Silva AGM da, Rodrigues TS, Haigh SJ, Camargo PHC de. Galvanic replacement reaction: recent developments for engineering metal nanostructures towards catalytic applications [Internet]. Chemical Communications. 2017 ; 53 7135-7148.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1039/c7cc02352a
    • Vancouver

      Silva AGM da, Rodrigues TS, Haigh SJ, Camargo PHC de. Galvanic replacement reaction: recent developments for engineering metal nanostructures towards catalytic applications [Internet]. Chemical Communications. 2017 ; 53 7135-7148.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1039/c7cc02352a
  • Source: Ultramicroscopy. Unidade: IQ

    Subjects: ESPECTROSCOPIA DE RAIO X, NANOPARTÍCULAS

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      SLATER, Thomas J. A et al. STEM-EDX tomography of bimetallic nanoparticles: a methodological investigation. Ultramicroscopy, v. 162, p. 61-73, 2016Tradução . . Disponível em: https://doi.org/10.1016/j.ultramic.2015.10.007. Acesso em: 06 nov. 2024.
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      Slater, T. J. A., Janssen, A., Camargo, P. H. C. de, Burke, M. G., Zaluzec, N. J., & Haigh, S. J. (2016). STEM-EDX tomography of bimetallic nanoparticles: a methodological investigation. Ultramicroscopy, 162, 61-73. doi:10.1016/j.ultramic.2015.10.007
    • NLM

      Slater TJA, Janssen A, Camargo PHC de, Burke MG, Zaluzec NJ, Haigh SJ. STEM-EDX tomography of bimetallic nanoparticles: a methodological investigation [Internet]. Ultramicroscopy. 2016 ; 162 61-73.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1016/j.ultramic.2015.10.007
    • Vancouver

      Slater TJA, Janssen A, Camargo PHC de, Burke MG, Zaluzec NJ, Haigh SJ. STEM-EDX tomography of bimetallic nanoparticles: a methodological investigation [Internet]. Ultramicroscopy. 2016 ; 162 61-73.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1016/j.ultramic.2015.10.007
  • Source: ChemBanoMat. Unidade: IQ

    Subjects: NANOPARTÍCULAS, MATERIAIS NANOESTRUTURADOS

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      YAMADA, Liliam Kaori et al. Bimetallic Au@Pd-Au tadpole-shaped asymmetric nanostructures by a combination of precursor reduction and ostwald ripening. ChemBanoMat, v. 2, n. 6, p. 509-514, 2016Tradução . . Disponível em: https://doi.org/10.1002/cnma.2 01600049. Acesso em: 06 nov. 2024.
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      Yamada, L. K., Silva, A. G. M. da, Rodrigues, T. S., Haigh, S. J., & Camargo, P. H. C. de. (2016). Bimetallic Au@Pd-Au tadpole-shaped asymmetric nanostructures by a combination of precursor reduction and ostwald ripening. ChemBanoMat, 2( 6), 509-514. doi:10.1002/cnma.2 01600049
    • NLM

      Yamada LK, Silva AGM da, Rodrigues TS, Haigh SJ, Camargo PHC de. Bimetallic Au@Pd-Au tadpole-shaped asymmetric nanostructures by a combination of precursor reduction and ostwald ripening [Internet]. ChemBanoMat. 2016 ; 2( 6): 509-514.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1002/cnma.2 01600049
    • Vancouver

      Yamada LK, Silva AGM da, Rodrigues TS, Haigh SJ, Camargo PHC de. Bimetallic Au@Pd-Au tadpole-shaped asymmetric nanostructures by a combination of precursor reduction and ostwald ripening [Internet]. ChemBanoMat. 2016 ; 2( 6): 509-514.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1002/cnma.2 01600049
  • Source: Chemistry-A European Journal. Unidade: IQ

    Subjects: NANOPARTÍCULAS, NANOTECNOLOGIA

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      SILVA, Anderson Gabriel Marques da et al. Surface segregated 'AG''AU' tadpole-shaped nanoparticles synthesized via a single step combined galvanic and citrate reduction reaction. Chemistry-A European Journal, v. 21, n. 35, p. 12314-12320, 2015Tradução . . Disponível em: https://doi.org/10.1002/chem.201501704. Acesso em: 06 nov. 2024.
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      Silva, A. G. M. da, Lewis, E. A., Rodrigues, T. S., Slater, T. J. A., Alves, R. S., Haigh, S. J., & Camargo, P. H. C. de. (2015). Surface segregated 'AG''AU' tadpole-shaped nanoparticles synthesized via a single step combined galvanic and citrate reduction reaction. Chemistry-A European Journal, 21( 35), 12314-12320. doi:10.1002/chem.201501704
    • NLM

      Silva AGM da, Lewis EA, Rodrigues TS, Slater TJA, Alves RS, Haigh SJ, Camargo PHC de. Surface segregated 'AG''AU' tadpole-shaped nanoparticles synthesized via a single step combined galvanic and citrate reduction reaction [Internet]. Chemistry-A European Journal. 2015 ; 21( 35): 12314-12320.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1002/chem.201501704
    • Vancouver

      Silva AGM da, Lewis EA, Rodrigues TS, Slater TJA, Alves RS, Haigh SJ, Camargo PHC de. Surface segregated 'AG''AU' tadpole-shaped nanoparticles synthesized via a single step combined galvanic and citrate reduction reaction [Internet]. Chemistry-A European Journal. 2015 ; 21( 35): 12314-12320.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1002/chem.201501704
  • Source: ACS Applied Materials & Interfaces. Unidade: IQ

    Subjects: OURO, CATÁLISE, PRATA, OXIDAÇÃO

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      SILVA, Anderson G. M. da et al. Controlling size, morphology, and surface composition of AgAu nanodendrites in 15 s for improved environmental catalysis under low metal loadings. ACS Applied Materials & Interfaces, v. 7, n. 46, p. 25624-25632, 2015Tradução . . Disponível em: https://doi.org/10.1021/acsami.5b08725. Acesso em: 06 nov. 2024.
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      Silva, A. G. M. da, Rodrigues, T. S., Slater, T. J. A., Lewis, E. A., Alves, R. S., Fajardo, H. V., et al. (2015). Controlling size, morphology, and surface composition of AgAu nanodendrites in 15 s for improved environmental catalysis under low metal loadings. ACS Applied Materials & Interfaces, 7( 46), 25624-25632. doi:10.1021/acsami.5b08725
    • NLM

      Silva AGM da, Rodrigues TS, Slater TJA, Lewis EA, Alves RS, Fajardo HV, Balzer R, Silva AHM da, Freitas IC de, Oliveira DC, Assaf JM, Probst LFD, Haigh SJ, Camargo PHC de. Controlling size, morphology, and surface composition of AgAu nanodendrites in 15 s for improved environmental catalysis under low metal loadings [Internet]. ACS Applied Materials & Interfaces. 2015 ; 7( 46): 25624-25632.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1021/acsami.5b08725
    • Vancouver

      Silva AGM da, Rodrigues TS, Slater TJA, Lewis EA, Alves RS, Fajardo HV, Balzer R, Silva AHM da, Freitas IC de, Oliveira DC, Assaf JM, Probst LFD, Haigh SJ, Camargo PHC de. Controlling size, morphology, and surface composition of AgAu nanodendrites in 15 s for improved environmental catalysis under low metal loadings [Internet]. ACS Applied Materials & Interfaces. 2015 ; 7( 46): 25624-25632.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1021/acsami.5b08725
  • Source: European Journal of Inorganic Chemistry. Unidade: IQ

    Subjects: NANOPARTÍCULAS, PALÁDIO, ELETROCATÁLISE

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      CARDOSO, Mariana B. T et al. A facile strategy to support palladium nanoparticles on carbon nanotubes, employing polyvinylpyrrolidone as a surface modifier. European Journal of Inorganic Chemistry, v. 2014, n. 9, p. 1439-1445, 2014Tradução . . Disponível em: https://doi.org/10.1002/ejic.201301585. Acesso em: 06 nov. 2024.
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      Cardoso, M. B. T., Lewis, E., Castro, P. S., Dantas, L. M. F., Oliveira, C. C. S. de, Bertotti, M., et al. (2014). A facile strategy to support palladium nanoparticles on carbon nanotubes, employing polyvinylpyrrolidone as a surface modifier. European Journal of Inorganic Chemistry, 2014( 9), 1439-1445. doi:10.1002/ejic.201301585
    • NLM

      Cardoso MBT, Lewis E, Castro PS, Dantas LMF, Oliveira CCS de, Bertotti M, Haigh SJ, Camargo PHC de. A facile strategy to support palladium nanoparticles on carbon nanotubes, employing polyvinylpyrrolidone as a surface modifier [Internet]. European Journal of Inorganic Chemistry. 2014 ; 2014( 9): 1439-1445.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1002/ejic.201301585
    • Vancouver

      Cardoso MBT, Lewis E, Castro PS, Dantas LMF, Oliveira CCS de, Bertotti M, Haigh SJ, Camargo PHC de. A facile strategy to support palladium nanoparticles on carbon nanotubes, employing polyvinylpyrrolidone as a surface modifier [Internet]. European Journal of Inorganic Chemistry. 2014 ; 2014( 9): 1439-1445.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1002/ejic.201301585
  • Source: Nano Letters. Unidade: IQ

    Subjects: NANOPARTÍCULAS, ESPECTROSCOPIA

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      SLATER, Thomas J. A et al. Correlating catalytic activity of Ag−Au nanoparticles with 3D compositional variations. Nano Letters, v. 14, n. 4, p. 1921-1926, 2014Tradução . . Disponível em: https://doi.org/10.1021/nl4047448. Acesso em: 06 nov. 2024.
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      Slater, T. J. A., Macedo, A., Schroeder, S. L. M., Burke, M. G., O'Brien, P., Camargo, P. H. C. de, & Haigh, S. J. (2014). Correlating catalytic activity of Ag−Au nanoparticles with 3D compositional variations. Nano Letters, 14( 4), 1921-1926. doi:10.1021/nl4047448
    • NLM

      Slater TJA, Macedo A, Schroeder SLM, Burke MG, O'Brien P, Camargo PHC de, Haigh SJ. Correlating catalytic activity of Ag−Au nanoparticles with 3D compositional variations [Internet]. Nano Letters. 2014 ; 14( 4): 1921-1926.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1021/nl4047448
    • Vancouver

      Slater TJA, Macedo A, Schroeder SLM, Burke MG, O'Brien P, Camargo PHC de, Haigh SJ. Correlating catalytic activity of Ag−Au nanoparticles with 3D compositional variations [Internet]. Nano Letters. 2014 ; 14( 4): 1921-1926.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1021/nl4047448
  • Source: Nanoscale. Unidade: IQ

    Subjects: NANOPARTÍCULAS, NANOTECNOLOGIA

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      LEWIS, E. A et al. Real-time imaging and elemental mapping of AgAu nanoparticle transformations. Nanoscale, v. 6, n. 22, p. 13598-13605, 2014Tradução . . Disponível em: https://doi.org/10.1039/c4nr04837g. Acesso em: 06 nov. 2024.
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      Lewis, E. A., Slater, T. J. A., Prestat, E., Macedo, A., O'Brien, P. O., Camargo, P. H. C. de, & Haigh, S. J. (2014). Real-time imaging and elemental mapping of AgAu nanoparticle transformations. Nanoscale, 6( 22), 13598-13605. doi:10.1039/c4nr04837g
    • NLM

      Lewis EA, Slater TJA, Prestat E, Macedo A, O'Brien PO, Camargo PHC de, Haigh SJ. Real-time imaging and elemental mapping of AgAu nanoparticle transformations [Internet]. Nanoscale. 2014 ; 6( 22): 13598-13605.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1039/c4nr04837g
    • Vancouver

      Lewis EA, Slater TJA, Prestat E, Macedo A, O'Brien PO, Camargo PHC de, Haigh SJ. Real-time imaging and elemental mapping of AgAu nanoparticle transformations [Internet]. Nanoscale. 2014 ; 6( 22): 13598-13605.[citado 2024 nov. 06 ] Available from: https://doi.org/10.1039/c4nr04837g

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