Antiambipolar heterjunctions from solution-processed semiconductors
- 技術優勢
- s-SWCNT and a-IGZO thin films that can be solution-processed or sputtered with high spatial uniformity at the wafer scales-SWCNT/a-IGZO p-n heterojunction van der Waals heterostructures which considerably broaden the potential of this device concept
- 詳細技術說明
- Large-area, low-voltage, anti-ambipolar heterojunctions from solution-processed semiconductors
- *Abstract
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Layered two-dimensional (2D) semiconductors have been incorporated into heterostructure devices with gate-tunable electronic and optical functionalities that overcome processing challenges of scalability and/or homogeneity essential for use in large-area integrated circuits. This invention extends the concept of van der Waals heterojunctions to semiconducting p-type single-walled carbon nanotube (s-SWCNT) and n-type amorphous indium gallium zinc oxide (a-IGZO) thin films that can be solution-processed or sputtered with high spatial uniformity at the wafer scale. The resulting large-area, low-voltage p-n heterojunctions exhibit anti-ambipolar transfer characteristics with high on/off ratios well-suited for electronic, optoelectronic, and telecommunication technologies.
Anti-ambipolar devices exhibiting frequency doubling (or multiplying) circuits have been fabricated promising wide applications in analog communications, radio astronomy and THz sensing. Anti-ambipolarity devices also facilitate other analog signal processing circuits including binary phase shift keying (BPSK) circuits used for passband data transmission in digital communication systems that map the conceptual symbols digital 0 and digital 1 into physical quantities carried by alternating current (AC) signals. BPSK is widely used for telecommunications and wireless data transmission technologies such as WiFi.
- *Inventors
- Mark C. Hersam* Deep M. Jariwala Hyungil Kim Tobin J Marks Vinod K. Sangwan Weichao Xu
- *Publications
- Jariwala D, Sangwan VK, Seo J-W T, Xu W, Smith J, Kim CH, Lauhon LJ, Marks T, Hersam MC (2014). Nano Letters.
- 國家/地區
- 美國
