Graphene/Organic Semiconductor Heterojunction Phototransistors with Broadband and Bi‐directional Photoresponse

Abstract: has been a challenge. [5,6] To enhance the absorption and photoresponse of graphene devices, researchers provide a series of strategies to interface graphene with light-absorbing semiconductors. [7][8][9][10][11][12][13][14][15][16] Early experimental studies on hybrid devices mainly focus on using one semiconductor layer, including colloidal quantum dots, [7,8] perov skites, [9] organic polymers, [10] single crystals, [16] 2D materials, [17] silicon, and other traditional materials. [11] More recently, improv… Show more

“…In particular, the most advanced infrared (IR) photodetector at optical communication waveband (1300–1650 nm) is of great significance, because it has a wide range of applications in the fields of military, information communication, and imaging . At present, two dimensional (2D) materials, due to their externally tunable bandgap and bound photoelectric properties, such as graphene, 2D transition metal dihalides (TMDs), and black phosphorus (BP), are becoming new stars in the field of telecommunications optical detection . However, the application of zero bandgap graphene is severely limited due to its low light absorption efficiency.…”

Ultrahigh Stability 3D TI Bi₂Se₃/MoO₃ Thin Film Heterojunction Infrared Photodetector at Optical Communication Waveband

“…In particular, the most advanced infrared (IR) photodetector at optical communication waveband (1300–1650 nm) is of great significance, because it has a wide range of applications in the fields of military, information communication, and imaging . At present, two dimensional (2D) materials, due to their externally tunable bandgap and bound photoelectric properties, such as graphene, 2D transition metal dihalides (TMDs), and black phosphorus (BP), are becoming new stars in the field of telecommunications optical detection . However, the application of zero bandgap graphene is severely limited due to its low light absorption efficiency.…”

Ultrahigh Stability 3D TI Bi₂Se₃/MoO₃ Thin Film Heterojunction Infrared Photodetector at Optical Communication Waveband

“…This photodetector breaks the limit of the assisted absorbing materials' spectral range. More recently, bilayer or bulk hybrid enhanced graphene photodetectors for boosting detection performance . For excitons separation and trapping one type carrier, the type‐II band alignment meets requirements.…”

“…More recently, bilayer or bulk hybrid enhanced graphene photodetectors for boosting detection performance. [101][102][103][104][105][106] For excitons separation and trapping one type carrier, the type-II band alignment meets requirements. Compared to the single layer enhanced weak interaction between interfaces, bilayer or bulk hybrid assisted offer a more effective built-in field to promote the electron-hole separation.…”

Design strategies for two‐dimensional material photodetectors to enhance device performance

“…However, composites of OSPs and GNPs can exhibit mutually beneficial effects, as they combine both semiconducting behavior of the polymers and enhanced charge transport characteristics of graphene . A typical demonstration of graphene/organic semiconductor heterojunction was previously realized as a highly photosensitive material due to strong absorption of organic semiconductor . Furthermore, the photoconductivity was found to be wavelength‐dependent, exhibiting opposite polarity due to the direction of the charge transfer or due to different drift velocity, which arises from the photoexcitation to different conducting channels .…”

“…A typical demonstration of graphene/organic semiconductor heterojunction was previously realized as a highly photosensitive material due to strong absorption of organic semiconductor . Furthermore, the photoconductivity was found to be wavelength‐dependent, exhibiting opposite polarity due to the direction of the charge transfer or due to different drift velocity, which arises from the photoexcitation to different conducting channels . Such tunability will enable new functionalities in future electronic devices.…”

Enhancement of Charge Transport in Polythiophene Semiconducting Polymer by Blending with Graphene Nanoparticles