Graphene Ballistic Rectifiers: Theory and Geometry Dependence

Joseph Brownless; Jiawei Zhang; Aimin Song

doi:10.1016/j.carbon.2020.06.058

Graphene Ballistic Rectifiers: Theory and Geometry Dependence

Joseph Brownless, Jiawei Zhang, Aimin Song

Shandong University

Research output: Contribution to journal › Article › peer-review

Abstract

The graphene ballistic rectifier uses the ultra-high carrier mobility of graphene to rectify ballistic carriers in an asymmetric nanostructure, and has been previously shown to operate beyond 650 GHz. Unlike conventional diodes and transistors, it does not require a bandgap. Building on the previously developed extended Büttiker-Landauer formula for semiconductors, we derive an analytical theory suitable for coexistence of electrons and holes in semi-metal graphene. Four ballistic rectifier designs are fabricated and compared. The developed theory fits their characteristics well, with derived parameters showing good agreement with device geometries. We also predict achievable responsivities of at least 50,800 V/W and noise-equivalent powers of 0.51 pW/Hz1/2 using these designs, far better than has so far been achieved. Importantly, this theory predicts increased responsivities with a large difference in carrier mobilities. Using the theory presented here, other graphene based ballistic nanodevices may be designed and optimized.

Original language	English
Pages (from-to)	201
Number of pages	208
Journal	Carbon
Volume	168
DOIs	https://doi.org/10.1016/j.carbon.2020.06.058
Publication status	Published - 12 Jul 2020

Keywords

graphene
ballistic transport
Büttiker-Landauer formula
rectifier

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CDT in Science and Applications of Graphene and Related Nanomaterial
Grigorieva, I. (PI), Burnett, H. (PGR student), Cusworth, E. (PGR student), Deaconu, D.-A. (PGR student), Dumitriu-Iovanescu, A.-D. (PGR student), Kang, Y.-W. (PGR student), Little, J. (PGR student), Rees, E. (PGR student), Selles, F. (PGR student), Shaker, M. (PGR student), Soong, Y.-C. (PGR student), Swindell, J. (PGR student), Tainton, G. (PGR student), Wood, H. (PGR student), Astles, T. (PGR student), Carl, A. (PGR student), Chen, G. (PGR student), Richard De Latour, H. (PGR student), Dowinton, O. (PGR student), Haskell, S. (PGR student), Hills, K. (PGR student), Hoole, C. (PGR student), Huang, Y. (PGR student), Kalsi, T. (PGR student), Powell, L. (PGR student), Quiligotti, K. (PGR student), Rimmer, J. (PGR student), Smith, L. (PGR student), Thornley, W. (PGR student), Yang, J. (PGR student), Young, W. (PGR student), Zhao, M. (PGR student), Al Busaidi, R. (PGR student), Al Ruqeishi, E. (PGR student), Chadha, A. (PGR student), Chen, M. (PGR student), Dennis, G. (PGR student), Dunn, E. (PGR student), Gamblen, E. (PGR student), Gao, Y. (PGR student), Georgantas, Y. (PGR student), Jiang, Z. (PGR student), Karakasidi, A. (PGR student), Mcellistrim, A. (PGR student), Meehan, M. (PGR student), Okwelogu, E. (PGR student), Taylor, M. (PGR student), Wang, W. (PGR student), Xin, B. (PGR student), Castle, C. (PGR student), Clout, P. (PGR student), Dean, S. D. (PGR student), Fordham, A. (PGR student), Griffin, E. (PGR student), Hardwick, T. (PGR student), Hawkins-Pottier, G. (PGR student), Jones, A. (PGR student), Lewthwaite, K. (PGR student), Monteil, S. (PGR student), Moulsdale, C. (PGR student), Mullan, C. (PGR student), Orts Mercadillo, V. (PGR student), Sanderson, D. (PGR student), Skliueva, I. (PGR student), Skuse, C. (PGR student), Steiner, P. (PGR student), Winstanley, B. (PGR student), Barry, D. (PGR student), Brooks, D. (PGR student), Cai, J. (PGR student), Chen, Y. (PGR student), Chen, C. (PGR student), Draude, A. (PGR student), Emmerson, C. (PGR student), Gavriliuc, V. (PGR student), Greaves, M. (PGR student), Higgins, E. (PGR student), Mcmaster, R. (PGR student), Mcnair, R. (PGR student), O'Brien, C. (PGR student), Peasey, A. (PGR student), Pinter, G. (PGR student), Shao, S. (PGR student), Thomas, D. (PGR student), Thomas, D. (PGR student), Tsim, L. T. B. (PGR student), Wengraf, J. (PGR student), Weston, A. (PGR student), Yu, T. (PGR student), De Libero, H. (PGR student), Chan, K. C. (PGR student), Tan, Y. T. (PGR student) & Thomson, T. (CoI)
1/04/14 → 31/10/25
Project: Other
Nano-rectennas for heat-to-electricity conversion. Graphene
Song, A. (PI) & Hill, E. (CoI)
1/04/16 → 7/08/19
Project: Research

Cite this

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title = "Graphene Ballistic Rectifiers: Theory and Geometry Dependence",

abstract = "The graphene ballistic rectifier uses the ultra-high carrier mobility of graphene to rectify ballistic carriers in an asymmetric nanostructure, and has been previously shown to operate beyond 650 GHz. Unlike conventional diodes and transistors, it does not require a bandgap. Building on the previously developed extended B{\"u}ttiker-Landauer formula for semiconductors, we derive an analytical theory suitable for coexistence of electrons and holes in semi-metal graphene. Four ballistic rectifier designs are fabricated and compared. The developed theory fits their characteristics well, with derived parameters showing good agreement with device geometries. We also predict achievable responsivities of at least 50,800 V/W and noise-equivalent powers of 0.51 pW/Hz1/2 using these designs, far better than has so far been achieved. Importantly, this theory predicts increased responsivities with a large difference in carrier mobilities. Using the theory presented here, other graphene based ballistic nanodevices may be designed and optimized.",

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AU - Zhang, Jiawei

AU - Song, Aimin

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AB - The graphene ballistic rectifier uses the ultra-high carrier mobility of graphene to rectify ballistic carriers in an asymmetric nanostructure, and has been previously shown to operate beyond 650 GHz. Unlike conventional diodes and transistors, it does not require a bandgap. Building on the previously developed extended Büttiker-Landauer formula for semiconductors, we derive an analytical theory suitable for coexistence of electrons and holes in semi-metal graphene. Four ballistic rectifier designs are fabricated and compared. The developed theory fits their characteristics well, with derived parameters showing good agreement with device geometries. We also predict achievable responsivities of at least 50,800 V/W and noise-equivalent powers of 0.51 pW/Hz1/2 using these designs, far better than has so far been achieved. Importantly, this theory predicts increased responsivities with a large difference in carrier mobilities. Using the theory presented here, other graphene based ballistic nanodevices may be designed and optimized.

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KW - Büttiker-Landauer formula

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DO - 10.1016/j.carbon.2020.06.058

M3 - Article

SN - 0008-6223

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JO - Carbon

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ER -

Graphene Ballistic Rectifiers: Theory and Geometry Dependence

Abstract

Keywords

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CDT in Science and Applications of Graphene and Related Nanomaterial

Nano-rectennas for heat-to-electricity conversion. Graphene

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