Fan Wu scite author profile

Despite 55 years of efforts into short gate length transistors following the Moore's law, the gate length below 1 nm has not been realized. Here, we demonstrated a side-wall monolayer MoS 2 transistors with ultimate 0.34 nm gate length using the edge of graphene as gate electrode. Moreover, large area of chemical vapor deposition graphene and MoS 2 are used for 2-inch wafer production. These ultrashort devices show excellent ON/OFF current ratio of 2 × 10 5 . Simulation results indicate that the MoS 2 sidewall effective channel length approaches 0.34 nm in the ON state. This graphene edge gate combined with MoS 2 vertical channel structure provides an e cient gate control ability and enables the physical gate length scaling down to atomic level, which shows great potential to build next generation electronics.

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Two-stage amplification of an ultrasensitive MXene-based intelligent artificial eardrum

Gou

Jian

et al. 2022

Sci. Adv.

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We report an artificial eardrum using an acoustic sensor based on two-dimensional MXene (Ti 3 C 2 T x ), which mimics the function of a human eardrum for realizing voice detection and recognition. Using MXene with a large interlayer distance and micropyramid polydimethylsiloxane arrays can enable a two-stage amplification of pressure and acoustic sensing. The MXene artificial eardrum shows an extremely high sensitivity of 62 kPa −1 and a very low detection limit of 0.1 Pa. Notably, benefiting from the ultrasensitive MXene eardrum, the machine-learning algorithm for real-time voice classification can be realized with high accuracy. The 280 voice signals are successfully classified for seven categories, and a high accuracy of 96.4 and 95% can be achieved by the training dataset and the test dataset, respectively. The current results indicate that the MXene artificial intelligent eardrum shows great potential for applications in wearable acoustical health care devices.

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Graphene-Based Thermoacoustic Sound Source

Qiao

Gou

et al. 2020

ACS Nano

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Thermoacoustic (TA) effect has been discovered for more than 130 years. However, limited by the material characteristics, the performance of a TA sound source could not be compared with magnetoelectric and piezoelectric loudspeakers. Recently, graphene, a two-dimensional material with the lowest heat capacity per unit area, was discovered to have a good TA performance. Compared with a traditional sound source, graphene TA sound sources (GTASSs) have many advantages, such as small volume, no diaphragm vibration, wide frequency range, high transparency, good flexibility, and high sound pressure level (SPL). Therefore, graphene has a great potential as a next-generation sound source. Photoacoustic (PA) imaging can also be applied to the diagnosis and treatment of diseases using the photothermo-acoustic (PTA) effect. Therefore, in this review, we will introduce the history of TA devices. Then, the theory and simulation model of TA will be analyzed in detail. After that, we will talk about the graphene synthesis method. To improve the performance of GTASSs, many strategies such as lowering the thickness and using porous or suspended structures will be introduced. With a good PTA effect and large specific area, graphene PA imaging and drug delivery is a promising prospect in cancer treatment. Finally, the challenges and prospects of GTASSs will be discussed.

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Fan Wu

Vertical MoS2 transistors with sub-1-nm gate lengths

Two-stage amplification of an ultrasensitive MXene-based intelligent artificial eardrum

Graphene-Based Thermoacoustic Sound Source

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