22‐3: Negative Capacitance ZAO/ZnO Ferroelectric Thin‐Film Transistor for Neuromorphic Computing

22‐3: Negative Capacitance ZAO/ZnO Ferroelectric Thin‐Film Transistor for Neuromorphic Computing

We report complementary metal‐oxide semiconductor (CMOS)‐compatible, negative capacitance (NC) ferroelectric (FE) zirconium‐aluminum oxide (ZAO)/ZnO thin‐film transistors (TFTs) at a low thermal budget of 360 °C. The NC‐FE‐TFTs demonstrate uniform device‐to‐device performances, featuring a high memo...

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Veröffentlicht in:SID International Symposium Digest of technical papers 2024-06, Vol.55 (1), p.280-283
Hauptverfasser: Islam, Md Mobaidul, Jeong, Myeonggi, Ali, Arqum, Bae, Jinbaek, Roy, Samiran, Jang, Jin
Format: Artikel
Sprache:eng
Schlagworte:
Aluminum oxide
Capacitance
Ferroelectric materials
ferroelectric thin‐film transistor (FE‐TFT)
Ferroelectricity
negative capacitance (NC)
negative differential resistance (NDR)
Neuromorphic computing
Room temperature
Semiconductor devices
synaptic weight
Thin film transistors
Zinc oxide
zirconium‐aluminum‐oxide (ZAO)
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Zusammenfassung:We report complementary metal‐oxide semiconductor (CMOS)‐compatible, negative capacitance (NC) ferroelectric (FE) zirconium‐aluminum oxide (ZAO)/ZnO thin‐film transistors (TFTs) at a low thermal budget of 360 °C. The NC‐FE‐TFTs demonstrate uniform device‐to‐device performances, featuring a high memory window of 6.7 ± 0.1 V and steep subthreshold swing of 43 ± 4 mV dec–1 . The observation of negative differential resistance at room temperature confirms the NC effect in FE‐ZAO/ZnO TFTs. In addition, a learning accuracy of ≈92% is achieved, highlighting the potential for high precision neuromorphic computing application.
ISSN:0097-966X
2168-0159
DOI:10.1002/sdtp.17509