Multistage Photosynaptic Transistor Based on the Regulation of Ferroelectric P（VDF-TrFE）

Lihua HE; Enlong LI; Rengjian YU; Huipeng CHEN; Guocheng ZHANG

doi:10.3788/gzxb20215009.0904002

[1] M A ZIDAN, J P STRACHAN, W D LU. The future of electronics based on memristive systems. Nature Electronics, 1, 22-29(2018).

[2] Zhongrui WANG, S JOSHI, S E SAVEL'EV et al. Memristors with diffusive dynamics as synaptic emulators for neuromorphic computing. Nature Materials, 16, 101-108(2017).

[3] S CHOI, S H TAN, Zefan LI et al. SiGe epitaxial memory for neuromorphic computing with reproducible high performance based on engineered dislocations. Nature Materials, 17, 335-340(2018).

[4] M PREZIOSO, F MERRIKH-BAYAT, B D HOSKINS et al. Training and operation of an integrated neuromorphic network based on metal-oxide memristors. Nature, 521, 61-64(2015).

[5] T CHANG, I EBONG et al. Nanoscale memristor device as synapse in neuromorphic systems. Nano Letters, 10, 1297-1301(2010).

[6] E J FULLER, F E GABALY, F LEONARD et al. Li-ion synaptic transistor for low power analog computing. Advanced Materials, 29, 1604310(2017).

[7] I S ESQUEDA, Xiaodong YAN, C RUTHERGLEN et al. Aligned carbon nanotube synaptic transistors for large-scale neuromorphic computing. ACS Nano, 12, 7352-7361(2018).

[8] M T SHARBATI, Yanhao DU, J TORRES et al. Low-power， electrochemically tunable graphene synapses for neuromorphic computing. Advanced Materials, 30, 1802353(2018).

[9] Xiaobin YAN, Jianhui ZHAO, Sen LIU et al. Memristor with Ag-cluster-doped TiO₂films as artificial synapse for neuroinspired computing. Advanced Functional Materials, 28, 1705320(2018).

[10] M K KIM, J S LEE. Ferroelectric analog synaptic transistors. Nano Letters, 19, 2044-2050(2019).

[11] Lei ZHAO, Zhen FAN, Shengliang CHENG et al. An artificial optoelectronic synapse based on a photoelectric memcapacitor. Advanced Electronic Materials, 6, 1900858(2019).

[12] Bang LI, Wei WEI, Xin YAN et al. Mimicking synaptic functionality with an InAs nanowire phototransistor. Nanotechnology, 29, 464004(2018).

[13] Chenyang SHI, Jinling LAN, Jingjuan WANG et al. Flexible and insoluble artificial synapses based on chemical cross‐linked wool keratin. Advanced Functional Materials, 30, 2002882(2020).

[14] D BERCO. Rectifying resistive memory devices as dynamic complementary artificial synapses. Frontiers in Neuroscience, 12, 755(2018).

[15] D KUZUM, R G JEYASINGH, B LEE et al. Nanoelectronic programmable synapses based on phase change materials for brain-inspired computing. Nano Letters, 12, 2179-2186(2012).

[16] G AGNUS, Weisheng ZHAO, V DERYCKE et al. Two-terminal carbon nanotube programmable devices for adaptive architectures. Advanced Materials, 22, 702-706(2010).

[17] Lin SHAO, Hailu WANG, Yi YANG et al. Optoelectronic properties of printed photogating carbon nanotube thin film transistors and their application for light-stimulated neuromorphic devices. ACS Applied Materials Interfaces, 11, 12161-12169(2019).

[18] Yi YANG, Yongli HE, S NIE et al. Light stimulated IGZO-based electric-double-layer transistors for photoelectric neuromorphic devices. IEEE Electron Device Letters, 39, 897-900(2018).

[19] S M KWON, S W CHO, M KIM et al. Environment-adaptable artificial visual perception behaviors using a light-adjustable optoelectronic neuromorphic device array. Advanced Materials, 31, 1906433(2019).

[20] Kai WANG, Shilei DAI, Yiwei ZHAO et al. Light-stimulated synaptic transistors fabricated by a facile solution process based on inorganic perovskite quantum dots and organic semiconductors. Small, 15, 1900010(2019).

[21] T AHMED, S KURIAKOSE, E L H MAYES et al. Optically stimulated artificial synapse based on layered black phosphorus. Small, 15, 1900966(2019).

[22] S SEO, S KIM et al. Artificial optic-neural synapse for colored and color-mixed pattern recognition. Nature Communications, 9, 5106(2018).

[23] Yilin SUN, Liu QIAN, Dan XIE et al. Photoelectric synaptic plasticity realized by 2D perovskite. Advanced Functional Materials, 29, 1902538(2019).

[24] M K KIM, J S LEE. Synergistic improvement of long-term plasticity in photonic synapses using ferroelectric polarization in hafnia-based oxide-semiconductor transistors. Advanced Materials, 32, 1907826(2020).

[25] Chen ZHANG, Wenbin YE, Kui ZHOU et al. Bioinspired artificial sensory nerve based on nafion memristor. Advanced Functional Materials, 29, 1808783(2019).

[26] Xiaofeng WU, Ruofei JIA, JIE Jiansheng et al. Air effect on the ideality of p‐type organic field‐effect transistors： a double‐edged sword. Advanced Functional Materials, 29, 1906653(2019).

[27] Yongli HE, Yi YANG, Sha NIE et al. Electric-double-layer transistors for synaptic devices and neuromorphic systems. Journal of Materials Chemistry C, 6, 5336-5352(2018).

[28] G BORNSCHEIN, O ARENDT, S HALLERMANN et al. Paired-pulse facilitation at recurrent Purkinje neuron synapses is independent of calbindin and parvalbumin during high-frequency activation. Journal of Physiology-London, 591, 3355-3370(2013).