Bandgap engineering of two-dimensional semiconductor materials

A. Chaves; J. G. Azadani; Hussain Alsalman; D. R. da Costa; R. Frisenda; A. J. Chaves; Seung Hyun Song; Y. D. Kim; Daowei He; Jiadong Zhou; A. Castellanos-Gomez; F. M. Peeters; Zheng Liu; C. L. Hinkle; Sang Hyun Oh; Peide D. Ye; Steven J. Koester; Young Hee Lee; Ph Avouris; Xinran Wang; Tony Low

doi:10.1038/s41699-020-00162-4

Bandgap engineering of two-dimensional semiconductor materials

A. Chaves^*
, J. G. Azadani
, Hussain Alsalman
, D. R. da Costa
, R. Frisenda
, A. J. Chaves
, Seung Hyun Song
, Y. D. Kim
, Daowei He
, Jiadong Zhou
, A. Castellanos-Gomez
, F. M. Peeters
, Zheng Liu
, C. L. Hinkle
, Sang Hyun Oh
, Peide D. Ye
, Steven J. Koester
, Young Hee Lee
, Ph Avouris
, Xinran Wang

Tony Low^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

1137 Scopus citations

Abstract

Semiconductors are the basis of many vital technologies such as electronics, computing, communications, optoelectronics, and sensing. Modern semiconductor technology can trace its origins to the invention of the point contact transistor in 1947. This demonstration paved the way for the development of discrete and integrated semiconductor devices and circuits that has helped to build a modern society where semiconductors are ubiquitous components of everyday life. A key property that determines the semiconductor electrical and optical properties is the bandgap. Beyond graphene, recently discovered two-dimensional (2D) materials possess semiconducting bandgaps ranging from the terahertz and mid-infrared in bilayer graphene and black phosphorus, visible in transition metal dichalcogenides, to the ultraviolet in hexagonal boron nitride. In particular, these 2D materials were demonstrated to exhibit highly tunable bandgaps, achieved via the control of layers number, heterostructuring, strain engineering, chemical doping, alloying, intercalation, substrate engineering, as well as an external electric field. We provide a review of the basic physical principles of these various techniques on the engineering of quasi-particle and optical bandgaps, their bandgap tunability, potentials and limitations in practical realization in future 2D device technologies.

Original language	English
Article number	29
Journal	npj 2D Materials and Applications
Volume	4
Issue number	1
DOIs	https://doi.org/10.1038/s41699-020-00162-4
State	Published - 1 Dec 2020
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2020, The Author(s).

ASJC Scopus subject areas

General Chemistry
General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

Access to Document

10.1038/s41699-020-00162-4

Cite this

Chaves, A., Azadani, J. G., Alsalman, H., da Costa, D. R., Frisenda, R., Chaves, A. J., Song, S. H., Kim, Y. D., He, D., Zhou, J., Castellanos-Gomez, A., Peeters, F. M., Liu, Z., Hinkle, C. L., Oh, S. H., Ye, P. D., Koester, S. J., Lee, Y. H., Avouris, P., ... Low, T. (2020). Bandgap engineering of two-dimensional semiconductor materials. npj 2D Materials and Applications, 4(1), Article 29. https://doi.org/10.1038/s41699-020-00162-4

@article{6dc857d1afaa45b2a32fade0d5eba781,

title = "Bandgap engineering of two-dimensional semiconductor materials",

abstract = "Semiconductors are the basis of many vital technologies such as electronics, computing, communications, optoelectronics, and sensing. Modern semiconductor technology can trace its origins to the invention of the point contact transistor in 1947. This demonstration paved the way for the development of discrete and integrated semiconductor devices and circuits that has helped to build a modern society where semiconductors are ubiquitous components of everyday life. A key property that determines the semiconductor electrical and optical properties is the bandgap. Beyond graphene, recently discovered two-dimensional (2D) materials possess semiconducting bandgaps ranging from the terahertz and mid-infrared in bilayer graphene and black phosphorus, visible in transition metal dichalcogenides, to the ultraviolet in hexagonal boron nitride. In particular, these 2D materials were demonstrated to exhibit highly tunable bandgaps, achieved via the control of layers number, heterostructuring, strain engineering, chemical doping, alloying, intercalation, substrate engineering, as well as an external electric field. We provide a review of the basic physical principles of these various techniques on the engineering of quasi-particle and optical bandgaps, their bandgap tunability, potentials and limitations in practical realization in future 2D device technologies.",

author = "A. Chaves and Azadani, \{J. G.\} and Hussain Alsalman and \{da Costa\}, \{D. R.\} and R. Frisenda and Chaves, \{A. J.\} and Song, \{Seung Hyun\} and Kim, \{Y. D.\} and Daowei He and Jiadong Zhou and A. Castellanos-Gomez and Peeters, \{F. M.\} and Zheng Liu and Hinkle, \{C. L.\} and Oh, \{Sang Hyun\} and Ye, \{Peide D.\} and Koester, \{Steven J.\} and Lee, \{Young Hee\} and Ph Avouris and Xinran Wang and Tony Low",

note = "Publisher Copyright: {\textcopyright} 2020, The Author(s).",

year = "2020",

month = dec,

day = "1",

doi = "10.1038/s41699-020-00162-4",

language = "English",

volume = "4",

journal = "npj 2D Materials and Applications",

issn = "2397-7132",

publisher = "Nature Publishing Group",

number = "1",

}

Chaves, A, Azadani, JG, Alsalman, H, da Costa, DR, Frisenda, R, Chaves, AJ, Song, SH, Kim, YD, He, D, Zhou, J, Castellanos-Gomez, A, Peeters, FM, Liu, Z, Hinkle, CL, Oh, SH, Ye, PD, Koester, SJ, Lee, YH, Avouris, P, Wang, X & Low, T 2020, 'Bandgap engineering of two-dimensional semiconductor materials', npj 2D Materials and Applications, vol. 4, no. 1, 29. https://doi.org/10.1038/s41699-020-00162-4

TY - JOUR

T1 - Bandgap engineering of two-dimensional semiconductor materials

AU - Chaves, A.

AU - Azadani, J. G.

AU - Alsalman, Hussain

AU - da Costa, D. R.

AU - Frisenda, R.

AU - Chaves, A. J.

AU - Song, Seung Hyun

AU - Kim, Y. D.

AU - He, Daowei

AU - Zhou, Jiadong

AU - Castellanos-Gomez, A.

AU - Peeters, F. M.

AU - Liu, Zheng

AU - Hinkle, C. L.

AU - Oh, Sang Hyun

AU - Ye, Peide D.

AU - Koester, Steven J.

AU - Lee, Young Hee

AU - Avouris, Ph

AU - Wang, Xinran

AU - Low, Tony

PY - 2020/12/1

Y1 - 2020/12/1

N2 - Semiconductors are the basis of many vital technologies such as electronics, computing, communications, optoelectronics, and sensing. Modern semiconductor technology can trace its origins to the invention of the point contact transistor in 1947. This demonstration paved the way for the development of discrete and integrated semiconductor devices and circuits that has helped to build a modern society where semiconductors are ubiquitous components of everyday life. A key property that determines the semiconductor electrical and optical properties is the bandgap. Beyond graphene, recently discovered two-dimensional (2D) materials possess semiconducting bandgaps ranging from the terahertz and mid-infrared in bilayer graphene and black phosphorus, visible in transition metal dichalcogenides, to the ultraviolet in hexagonal boron nitride. In particular, these 2D materials were demonstrated to exhibit highly tunable bandgaps, achieved via the control of layers number, heterostructuring, strain engineering, chemical doping, alloying, intercalation, substrate engineering, as well as an external electric field. We provide a review of the basic physical principles of these various techniques on the engineering of quasi-particle and optical bandgaps, their bandgap tunability, potentials and limitations in practical realization in future 2D device technologies.

AB - Semiconductors are the basis of many vital technologies such as electronics, computing, communications, optoelectronics, and sensing. Modern semiconductor technology can trace its origins to the invention of the point contact transistor in 1947. This demonstration paved the way for the development of discrete and integrated semiconductor devices and circuits that has helped to build a modern society where semiconductors are ubiquitous components of everyday life. A key property that determines the semiconductor electrical and optical properties is the bandgap. Beyond graphene, recently discovered two-dimensional (2D) materials possess semiconducting bandgaps ranging from the terahertz and mid-infrared in bilayer graphene and black phosphorus, visible in transition metal dichalcogenides, to the ultraviolet in hexagonal boron nitride. In particular, these 2D materials were demonstrated to exhibit highly tunable bandgaps, achieved via the control of layers number, heterostructuring, strain engineering, chemical doping, alloying, intercalation, substrate engineering, as well as an external electric field. We provide a review of the basic physical principles of these various techniques on the engineering of quasi-particle and optical bandgaps, their bandgap tunability, potentials and limitations in practical realization in future 2D device technologies.

UR - https://www.scopus.com/pages/publications/85089775517

U2 - 10.1038/s41699-020-00162-4

DO - 10.1038/s41699-020-00162-4

M3 - Review article

AN - SCOPUS:85089775517

SN - 2397-7132

VL - 4

JO - npj 2D Materials and Applications

JF - npj 2D Materials and Applications

IS - 1

M1 - 29

ER -

Bandgap engineering of two-dimensional semiconductor materials

Abstract

Bibliographical note

ASJC Scopus subject areas

Access to Document

Fingerprint

Cite this