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@ARTICLE{Xie:1044676,
      author       = {Xie, Zhiqiang and Wu, Jianchang and Luo, Junsheng and Feng,
                      Mingjie and Tian, Jingjing and Li, Chaohui and Zhang, Difei
                      and Chen, Lijun and Loi, Maria Antonietta and Tian, Bobo and
                      Hao, Shenglan and Cheng, Long and Osvet, Andres and Brabec,
                      Christoph},
      title        = {{E}mulating {S}ynaptic {E}vents and {N}ociceptor via
                      {O}rganic–{I}norganic {P}erovskite {T}hreshold {S}witching
                      {M}emristor},
      journal      = {Small Methods},
      volume       = {},
      issn         = {2366-9608},
      address      = {Weinheim},
      publisher    = {WILEY-VCH Verlag GmbH $\&$ Co. KGaA},
      reportid     = {FZJ-2025-03325},
      pages        = {2500542},
      year         = {2025},
      abstract     = {As artificial intelligence technology continuously
                      advances, a growing number of bio-mimetic advanced
                      electronic systems are rapidly emerging and being applied in
                      various fields, including humanoid robots and tactile
                      sensors. To effectively address progressively complex tasks
                      and challenging work environments, integrating synaptic and
                      nociceptive functions within a single device is crucial for
                      enhancing the ability to perceive changes and respond
                      accordingly to the external environment. Here, an
                      organic–inorganic perovskite memristor that exhibits
                      excellent volatile performance (ON/OFF ratio ≈102,
                      endurance > 104 cycles) is presented. The device effectively
                      replicates typical synaptic functions, encompassing short-
                      and long-term plasticity. Moreover, due to the switching
                      delay characteristics, essential biological nociceptive
                      features such as threshold, no adaptation, and sensitization
                      are also demonstrated. Further, the perovskite artificial
                      nociceptor is successfully integrated into a thermal
                      nociceptive system. Overall, the fusion of synaptic and
                      nociceptive behaviors paves the way for developing more
                      efficient and versatile systems that can mimic intricate
                      biological processes associated with sensory perception and
                      pain sensation.},
      cin          = {IET-2},
      ddc          = {620},
      cid          = {I:(DE-Juel1)IET-2-20140314},
      pnm          = {1212 - Materials and Interfaces (POF4-121)},
      pid          = {G:(DE-HGF)POF4-1212},
      typ          = {PUB:(DE-HGF)16},
      doi          = {10.1002/smtd.202500542},
      url          = {https://juser.fz-juelich.de/record/1044676},
}