Investigation of Electronic Transport in Organic Electroluminescent Device Composed by Alq<sub>3</sub> Molecules

Sampaio-Silva, Alessandre; Aleixo, Vicente Ferrer Pureza; Corrêa, S. M.; Nero, Jordan Del

doi:10.1166/jctn.2014.3476

Cited by 4 publications

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“…Nesse sentido, baseado nos trabalhos pioneiros sobre transporte eletrônico em junções moleculares simples de Aviram-Ratner [14,15], Reed et al [16], Metzger et al [17][18][19] e Nitzan-Ratner [20], assim bem como nos artigos publicados por nosso grupo de pesquisa [21][22][23][24][25][26][27][28][29][30] nessa área, decidimos investigar as propriedades de transporte eletrônico e Transition-Voltage Spectroscopy (TVS) de junções moleculares compostas por Nanofitas ZigueZague de Grafeno (NZZG) e Phagrapheno (NZZPG), ver Fig.1a-b, usando Teoria do Funcional Densidade (DFT) para optimizar a geometria das moléculas e Teoria de Hückel Estendido/Função de Green de Não Equilíbrio (EHT/NEGF) para o cálculo do transporte eletrônico da junção [31,32]. A TVS é interpretada baseda em Huisman et al [33], por meio do modelo de transporte molecular coerente pois o transporte eletrônico ocorre por níveis moleculares ocupados discretos que é descrito pela Transmitância em função da Energia em regiões onde é localizada a Vmin [24][25][26].…”

Section: Introductionunclassified

Junções Moleculares De Nanofitas De Grafeno E Phagrapheno: Um Estudo via DFT E Eht/Negf.

Nisioka¹,

Felipe²,

Côrrea³

et al. 2017

Anais Do Congresso Anual Da ABM

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Resumo Nesse trabalho é proposto uma investigação das propriedades eletrônicas de junções moleculares de Nanofitas ZigueZague de Grafeno (NZZG) e Phagrafeno (NZZPG) por meio da Teoria: 1-DFT/B3LYP/6-311G(d,p) para otimizar a geometria das moléculas; 2-DFT/LDA.PZ/DZP sobre a célula unitária da rede cristalina para obter as propriedades eletrônicas; 3-Teoria de Hückel Estendido/Função de Green de Não Equilíbrio (THE/FGNE) através da fórmula de Landauer-Buttiker para a região central acoplada entre 2 eletrodos. Nossos resultados exibem: (i) comportamento condutor e singularidades de Van-Hove; (ii) uma região não linear com característica de um dispositivo usual TEC para NZZG; (iii) duas regiões não lineares (RDNs) mostrando característica de um diodo túnel com 2 janelas de operação para NZZPG. Essas regiões não lineares de voltagem coincidem com os Vmin nas curvas Fowler-Nordheim (FN) e Lauritsen-Millikan (LM).

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Section: Introductionunclassified

Junções Moleculares De Nanofitas De Grafeno E Phagrapheno: Um Estudo via DFT E Eht/Negf.

Nisioka¹,

Felipe²,

Côrrea³

et al. 2017

Anais Do Congresso Anual Da ABM

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“…Studies about the final state of the process are published in many papers, some published even in this journal. [19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35] But now we focus on the complicated dynamic transitions that lead to the final outcome. Therefore, since the standard theoretical models which describe the dynamics in nanostructures are sophisticated and ambiguous, in the present paper a new topic will be developed using the standard Scale Relativity Theory (SRT) [57][58][59][60][61][62][63][64] with arbitrary constant fractal dimension.…”

Section: Introductionmentioning

confidence: 99%

Theoretical Approach of Differentiable–Non-Differentiable Scale Transition in Nanostructures

Agop¹,

Botez²

2015

j comput theor nanosci

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Topological insulator-metal transition and molecular electronics device based on zigzag phagraphene nanoribbon

Silva

Corrêa

Santos

et al. 2018

Journal of Applied Physics

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In this work, we investigate the electronic transport properties of a graphene allotrope composed of 5–6-7 carbon aromatic rings called phagraphene and compare with the results of the transition-voltage spectroscopy (TVS) and propose the behavior at low voltage characteristic of a topological insulator. Phagraphene properties were compared to those of graphene in a zigzag nanoribbon configuration, zigzag graphene vs zigzag phagraphene nanoribbon (zzGNR and zzPGNR). The molecular geometry and the electronic properties were calculated by density functional theory (DFT) without spin, and the electronic transport and TVS were obtained by means of DFT combined with non-equilibrium Green´s function when we couple the optimized geometry of zzGNR and zzPGNR to the leads (left and right), forming the molecular junction that will be subjected to the action of an external bias voltage (Ve) to generate the molecular device. The results exhibit (i) a metal-insulator transition when Ve is increased until Ve = 1.4 V which corresponds to the nonlinear region (resonance), showing the field effect transistor behaviour for zzGNR junctions; and (ii) two nonlinear regions (two negative differential resistances), showing a resonant tunnel diode behaviour with two operation windows (Ve = 0.5 V and Ve = 1.7 V) for the zzPGNR junction. In addition, the zzPGNR junction exhibits topological insulator characteristics upon introducing topological defects such as pentagons and heptagons in the hexagonal lattice of graphene, and when Ve = 1.7 V, there occurs a topological insulator-metal transition that can be seen in the behaviour of the density of states, transmittance, and frontier molecular orbitals with Ve.

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Investigation of Electronic Transport in Organic Electroluminescent Device Composed by Alq₃ Molecules

Cited by 4 publications

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Junções Moleculares De Nanofitas De Grafeno E Phagrapheno: Um Estudo via DFT E Eht/Negf.

Junções Moleculares De Nanofitas De Grafeno E Phagrapheno: Um Estudo via DFT E Eht/Negf.

Theoretical Approach of Differentiable–Non-Differentiable Scale Transition in Nanostructures

Topological insulator-metal transition and molecular electronics device based on zigzag phagraphene nanoribbon

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Investigation of Electronic Transport in Organic Electroluminescent Device Composed by Alq3 Molecules

Cited by 4 publications

References 0 publications

Junções Moleculares De Nanofitas De Grafeno E Phagrapheno: Um Estudo via DFT E Eht/Negf.

Junções Moleculares De Nanofitas De Grafeno E Phagrapheno: Um Estudo via DFT E Eht/Negf.

Theoretical Approach of Differentiable–Non-Differentiable Scale Transition in Nanostructures

Topological insulator-metal transition and molecular electronics device based on zigzag phagraphene nanoribbon

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Investigation of Electronic Transport in Organic Electroluminescent Device Composed by Alq₃ Molecules