Polymer Doping Enables a Two‐Dimensional Electron Gas for High‐Performance Homojunction Oxide Thin‐Film Transistors

Shin

Liu

et al. 2019

Adv Funct Materials

151

130

Studies on printable semiconductors and technologies have increased rapidly over recent decades, pioneering novel applications in many fields, such as energy, sensing, logic circuits, and information displays. The newest display technologies are already turning to metal oxide semiconductors, i.e., indium gallium zinc oxide, for the improvements needed to drive active matrix organic light-emitting diodes. Convenience and portability will be realized with flexible and wearable displays in the future. This report summarizes recent progress on the development of solution-processed thin film transistors, especially those deposited at low temperatures for next-generation flexible smart displays. The first part provides an overview on the history and current status of displays. Then, recent advances in state-of-the-art solution-processed transistors based on different semiconductors are presented, including metal oxides, organic materials, perovskites, and carbon nanotubes. Finally, conclusions are drawn and the remaining challenges and future perspectives are discussed. a large common cathode (opaque metal). This means that the light emission goes through the backplane and the TFT arrays are able to block the light, resulting in the reduced emission fill factor of the display. This mode is also called bottom emission. One effective way to avoid the light obstruction from TFTs in the backplane is to use top-emitting OLEDs, which have a transparent cathode. [2] In 2004, Pennsylvania State University demonstrated the first flexible phosphorescent AMOLED display with hydrogenated amorphous silicon on a 4 in. polyimide (PI) substrate. [7] One year later, a 48 × 48 organic pentacene TFT-driven AMOLED display on a polyethylene terephthalate (PET) substrate was reported by the same group. [8] In 2005, by employing a top-emission structure, researchers at Sony Corp. demonstrated the first full-color imaging on a flexible AMOLED with a pixel resolution of 80 ppi. [9] In 2013, Samsung Electronics showed curved OLED TVs for the first time. Two years later, the same company unveiled a smartphone with a curved edge display (Galaxy S6 Edge), which used touch sensors to improve the user interface and device design. Most recently, LG Display succeeded in developing the world's first large-size 77 in. transparent and flexible OLED display, which could be rolled up to a radius of 80 mm. [10] The ideal flexible AMOLED backplane should be robust, rollable/bendable, capable of complementary metal oxide semiconductor (CMOS) operation, and should lend itself to low-cost manufacturing. To advance toward next-generation flexible AMOLED displays, two key technological goals should be satisfied during fabrication. One is to develop TFT backplanes with good uniformity, stability, and electrical performance. Amorphous silicon (a-Si) TFTs are well known for their uniform electrical characteristics (µ FE < 1 cm 2 V −1 s −1 and I on /I off > 10 6 ) and have achieved great success in flat-panel LCD displays. However, the relatively low µ FE and the lig...

Section: Metal Oxide Tftsmentioning

confidence: 99%

Printable Semiconductors for Backplane TFTs of Flexible OLED Displays

Shin

Liu

et al. 2019

Adv Funct Materials

151

130

“…By adjusting the thickness of AlInO and the doping amount of Al, AlInO (30%)/In 2 O 3 heterostructure TFTs with a high mobility of 40 cm 2 /Vs, a threshold slope of 0.7 V/dec, and an on/off ratio of 10 7 could be realized [58]. [56]. The 2D electron gas was achieved by creating a band offset between In2O3 and In2O3:PEI via work function tuning of the PEI-doping ratio.…”

Section: Mobility Enhancement By Forming 2d Electron Gasmentioning

confidence: 99%

“…When the doping amount of Li was 20%, the mobility of In 2 O 3 /Li-ZnO heterojunction TFTs reached the maximum value of 11.4 cm 2 /Vs and the on/off current ratio of ~10 5 . Chen et al demonstrated high performance In 2 O 3 /In 2 O 3 :polyethylenimine (PEI) heterostructure TFTs [ 56 ]. The 2D electron gas was achieved by creating a band offset between In 2 O 3 and In 2 O 3 :PEI via work function tuning of the PEI-doping ratio.…”

Section: Heterojunction Oxide Tftsmentioning

confidence: 99%

Recent Advances of Solution-Processed Heterojunction Oxide Thin-Film Transistors

Zhao

et al. 2020

Nanomaterials

Thin-film transistors (TFTs) made of metal oxide semiconductors are now increasingly used in flat-panel displays. Metal oxides are mainly fabricated via vacuum-based technologies, but solution approaches are of great interest due to the advantages of low-cost and high-throughput manufacturing. Unfortunately, solution-processed oxide TFTs suffer from relatively poor electrical performance, hindering further development. Recent studies suggest that this issue could be solved by introducing a novel heterojunction strategy. This article reviews the recent advances in solution-processed heterojunction oxide TFTs, with a specific focus on the latest developments over the past five years. Two of the most prominent advantages of heterostructure oxide TFTs are discussed, namely electrical-property modulation and mobility enhancement by forming 2D electron gas. It is expected that this review will manifest the strong potential of solution-based heterojunction oxide TFTs towards high performance and large-scale electronics.

“…Similarly, the mobility enhancement in n‐type oxide TFTs by n‐doping was recently reported. [ 14 ] It is worthy to note that the F 4 TCNQ layers delivered insulating behavior with low conduction current of several tens of picoamperes (Figure S3, Supporting Information). This confirms that the performance enhancement of F 4 TCNQ‐inserted Cu x O TFTs originated from charge transfer p‐type doping rather than from the conductance of F 4 TCNQ layers.…”

Section: Resultsmentioning

confidence: 99%

“…Unlike conventional atomic substitution doping, the doping process does not induce any defects or impurities into the host lattice, thereby eliminating undesired carrier scattering while reserving the fundamental transport properties. [ 11 ] Originally, MCTD was mainly used with organic semiconductors [ 12,13 ] and recently has been extended to n‐type metal oxides [ 14,15 ] and low‐dimensional nanomaterials (2D semiconductors, [ 16 ] carbon nanotubes, [ 17,18 ] and nanocrystals [ 19 ] ). For p‐type MCTD doping, the dopants should have a higher electron affinity than that of the host materials; commonly used candidates are MoO 3 , NO 2 , and tetrafluoro‐tetracyanoquinodimethane (F 4 TCNQ).…”

Section: Introductionmentioning

confidence: 99%

Molecule Charge Transfer Doping for p‐Channel Solution‐Processed Copper Oxide Transistors

Liu

Noh

2020

Adv Funct Materials

The doping of semiconductors plays a critical role in improving the performance of modern electronic devices by precisely controlling the charge carrier density. However, the absence of a stable doping method for p‐type oxide semiconductors has severely restricted the development of metal oxide‐based transparent p–n junctions and complementary circuits. Here, an efficient and stable doping process for p‐type oxide semiconductors by using molecule charge transfer doping with tetrafluoro‐tetracyanoquinodimethane (F4TCNQ) is reported. The selections of a suitable dopant and geometry play a crucial role in the charge‐transfer doping effect. The insertion of a F4TCNQ thin dopant film (2–7 nm) between a Au source‐drain electrode and solution‐processed p‐type copper oxide (CuxO) film in bottom‐gate top‐contact thin‐film transistors (TFTs) provides a mobility enhancement of over 20‐fold with the desired threshold voltage adjustment. By combining doped p‐type CuxO and n‐type indium gallium zinc oxide TFTs, a solution‐processed transparent complementary metal‐oxide semiconductor inverter is demonstrated with a high gain voltage of 50. This novel p‐doping method is expected to accelerate the development of high‐performance and reliable p‐channel oxide transistors and has the potential for widespread applications.