Technology Roadmap of Bioinspired Computing Hardware

Shuang Wang; Zhiyuan Li; Mengjiao Pei; Qinqi Ren; Ming Deng; Kah Wee Ang; Alon Ascoli; Sarbajit Banerjee; Michele Bonnin; Yoeri van de Burgt; Bojun Cheng; Leon Chua; Pier Paolo Civalleri; Fernando Corinto; Tie Jun Cui; Saptarshi Das; Ahmet Samil Demirkol; Sebastiaan van Dijken; Yijia Fan; Lu Fang; Matteo Farronato; Zi Rui Feng; Emanuele Gemo; Marco Gilli; Sreetosh Goswami; Yuhui He; Chaoran Huang; Qianqian Huang; Cheol Seong Hwang; Daniele Ielmini; Yoon Ho Jang; Zdenka Kuncic; Max Christian Lemme; Can Li; Shi Jun Liang; Keqin Liu; Shaojie Liu; Jin Luo; Qian Ma; Wolfgang Maass; Piergiulio Mannocci; Ioannis Messaris; Feng Miao; Thomas Mikolajick; Vasilis Ntinas; John Ponis; Themis Prodromakis; Dimitris Prousalis; Qiming Shao; Stefan Slesazeck; John Paul Strachan; Hongwei Tan; Jianshi Tang; Ronald Tetzlaff; Le Phuong Lan Tran; Ilia Valov; Anthony Vorias; Benshan Wang; Jiangjing Wang; Shengbo Wang; Xiaozhe Wang; Yasai Wang; Huaqiang Wu; Qiangfei Xia; Kai Xiao; Zhihua Xiao; Zheshun Xiong; Tengji Xu; Ming Jay Yang; Yuchao Yang; Yuekun Yang; Wei Zhang; Yang Chai

doi:10.1021/acsnano.5c17087

Technology Roadmap of Bioinspired Computing Hardware

Shuang Wang
, Zhiyuan Li
, Mengjiao Pei
, Qinqi Ren
, Ming Deng
, Kah Wee Ang
, Alon Ascoli
, Sarbajit Banerjee
, Michele Bonnin
, Yoeri van de Burgt
, Bojun Cheng
, Leon Chua
, Pier Paolo Civalleri
, Fernando Corinto
, Tie Jun Cui
, Saptarshi Das
, Ahmet Samil Demirkol
, Sebastiaan van Dijken
, Yijia Fan
, Lu Fang

Matteo Farronato, Zi Rui Feng, Emanuele Gemo, Marco Gilli, Sreetosh Goswami, Yuhui He, Chaoran Huang, Qianqian Huang, Cheol Seong Hwang, Daniele Ielmini, Yoon Ho Jang, Zdenka Kuncic, Max Christian Lemme, Can Li, Shi Jun Liang, Keqin Liu, Shaojie Liu, Jin Luo, Qian Ma, Wolfgang Maass, Piergiulio Mannocci, Ioannis Messaris, Feng Miao, Thomas Mikolajick, Vasilis Ntinas, John Ponis, Themis Prodromakis, Dimitris Prousalis, Qiming Shao, Stefan Slesazeck, John Paul Strachan, Hongwei Tan, Jianshi Tang, Ronald Tetzlaff, Le Phuong Lan Tran, Ilia Valov, Anthony Vorias, Benshan Wang, Jiangjing Wang, Shengbo Wang, Xiaozhe Wang, Yasai Wang, Huaqiang Wu, Qiangfei Xia, Kai Xiao, Zhihua Xiao, Zheshun Xiong, Tengji Xu, Ming Jay Yang, Yuchao Yang, Yuekun Yang, Wei Zhang, Yang Chai

Research output: Contribution to journal › Review article › peer-review

Abstract

The rapid growth of artificial intelligence (AI) is increasingly constrained by fundamental hardware bottlenecks in computation throughput and energy efficiency. Bioinspired computing (BIC) offers a promising alternative by emulating the intrinsic advantages of biological systems, such as parallelism, adaptability, and robustness. Progress in BIC hardware demands interdisciplinary convergence that bridges materials science and device physics with neuroscience, computer science, mathematics, and information science. Therefore, the development of this cross-disciplinary field urgently requires a comprehensive roadmap that analyzes systematically and in-depth the frontier issues and the latest progress. In this roadmap, we categorize the critical challenges into three components: hardware foundations, architectures, and prototype realizations. We highlight how biological features inspire the design of BIC hardware through device physics and discuss their performance metrics and engineering challenges. We then describe how diverse signaling rules and structural organizations in BIC architectures support specific computational prototypes, including electronic and photonic BIC chips, and present a technological roadmap that outlines opportunities to expand the functional scope of BIC hardware through coordinated advances in devices, architectures, and system demonstrations. This ongoing convergence of interdisciplinary knowledge can help accelerate the shift toward high-efficiency AI hardware.

Original language	English (US)
Pages (from-to)	8102-8163
Number of pages	62
Journal	ACS nano
Volume	20
Issue number	10
DOIs	https://doi.org/10.1021/acsnano.5c17087
State	Published - Mar 17 2026

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

All Science Journal Classification (ASJC) codes

General Materials Science
General Engineering
General Physics and Astronomy

Access to Document

10.1021/acsnano.5c17087

Cite this

Wang, S., Li, Z., Pei, M., Ren, Q., Deng, M., Ang, K. W., Ascoli, A., Banerjee, S., Bonnin, M., van de Burgt, Y., Cheng, B., Chua, L., Civalleri, P. P., Corinto, F., Cui, T. J., Das, S., Demirkol, A. S., van Dijken, S., Fan, Y., ... Chai, Y. (2026). Technology Roadmap of Bioinspired Computing Hardware. ACS nano, 20(10), 8102-8163. https://doi.org/10.1021/acsnano.5c17087

@article{fa2aede67d8d46b9ab39422095226f96,

title = "Technology Roadmap of Bioinspired Computing Hardware",

abstract = "The rapid growth of artificial intelligence (AI) is increasingly constrained by fundamental hardware bottlenecks in computation throughput and energy efficiency. Bioinspired computing (BIC) offers a promising alternative by emulating the intrinsic advantages of biological systems, such as parallelism, adaptability, and robustness. Progress in BIC hardware demands interdisciplinary convergence that bridges materials science and device physics with neuroscience, computer science, mathematics, and information science. Therefore, the development of this cross-disciplinary field urgently requires a comprehensive roadmap that analyzes systematically and in-depth the frontier issues and the latest progress. In this roadmap, we categorize the critical challenges into three components: hardware foundations, architectures, and prototype realizations. We highlight how biological features inspire the design of BIC hardware through device physics and discuss their performance metrics and engineering challenges. We then describe how diverse signaling rules and structural organizations in BIC architectures support specific computational prototypes, including electronic and photonic BIC chips, and present a technological roadmap that outlines opportunities to expand the functional scope of BIC hardware through coordinated advances in devices, architectures, and system demonstrations. This ongoing convergence of interdisciplinary knowledge can help accelerate the shift toward high-efficiency AI hardware.",

author = "Shuang Wang and Zhiyuan Li and Mengjiao Pei and Qinqi Ren and Ming Deng and Ang, \{Kah Wee\} and Alon Ascoli and Sarbajit Banerjee and Michele Bonnin and \{van de Burgt\}, Yoeri and Bojun Cheng and Leon Chua and Civalleri, \{Pier Paolo\} and Fernando Corinto and Cui, \{Tie Jun\} and Saptarshi Das and Demirkol, \{Ahmet Samil\} and \{van Dijken\}, Sebastiaan and Yijia Fan and Lu Fang and Matteo Farronato and Feng, \{Zi Rui\} and Emanuele Gemo and Marco Gilli and Sreetosh Goswami and Yuhui He and Chaoran Huang and Qianqian Huang and Hwang, \{Cheol Seong\} and Daniele Ielmini and Jang, \{Yoon Ho\} and Zdenka Kuncic and Lemme, \{Max Christian\} and Can Li and Liang, \{Shi Jun\} and Keqin Liu and Shaojie Liu and Jin Luo and Qian Ma and Wolfgang Maass and Piergiulio Mannocci and Ioannis Messaris and Feng Miao and Thomas Mikolajick and Vasilis Ntinas and John Ponis and Themis Prodromakis and Dimitris Prousalis and Qiming Shao and Stefan Slesazeck and Strachan, \{John Paul\} and Hongwei Tan and Jianshi Tang and Ronald Tetzlaff and Tran, \{Le Phuong Lan\} and Ilia Valov and Anthony Vorias and Benshan Wang and Jiangjing Wang and Shengbo Wang and Xiaozhe Wang and Yasai Wang and Huaqiang Wu and Qiangfei Xia and Kai Xiao and Zhihua Xiao and Zheshun Xiong and Tengji Xu and Yang, \{Ming Jay\} and Yuchao Yang and Yuekun Yang and Wei Zhang and Yang Chai",

note = "Publisher Copyright: {\textcopyright} 2026 American Chemical Society",

year = "2026",

month = mar,

day = "17",

doi = "10.1021/acsnano.5c17087",

language = "English (US)",

volume = "20",

pages = "8102--8163",

journal = "ACS nano",

issn = "1936-0851",

publisher = "American Chemical Society",

number = "10",

}

Wang, S, Li, Z, Pei, M, Ren, Q, Deng, M, Ang, KW, Ascoli, A, Banerjee, S, Bonnin, M, van de Burgt, Y, Cheng, B, Chua, L, Civalleri, PP, Corinto, F, Cui, TJ, Das, S, Demirkol, AS, van Dijken, S, Fan, Y, Fang, L, Farronato, M, Feng, ZR, Gemo, E, Gilli, M, Goswami, S, He, Y, Huang, C, Huang, Q, Hwang, CS, Ielmini, D, Jang, YH, Kuncic, Z, Lemme, MC, Li, C, Liang, SJ, Liu, K, Liu, S, Luo, J, Ma, Q, Maass, W, Mannocci, P, Messaris, I, Miao, F, Mikolajick, T, Ntinas, V, Ponis, J, Prodromakis, T, Prousalis, D, Shao, Q, Slesazeck, S, Strachan, JP, Tan, H, Tang, J, Tetzlaff, R, Tran, LPL, Valov, I, Vorias, A, Wang, B, Wang, J, Wang, S, Wang, X, Wang, Y, Wu, H, Xia, Q, Xiao, K, Xiao, Z, Xiong, Z, Xu, T, Yang, MJ, Yang, Y, Yang, Y, Zhang, W & Chai, Y 2026, 'Technology Roadmap of Bioinspired Computing Hardware', ACS nano, vol. 20, no. 10, pp. 8102-8163. https://doi.org/10.1021/acsnano.5c17087

TY - JOUR

T1 - Technology Roadmap of Bioinspired Computing Hardware

AU - Wang, Shuang

AU - Li, Zhiyuan

AU - Pei, Mengjiao

AU - Ren, Qinqi

AU - Deng, Ming

AU - Ang, Kah Wee

AU - Ascoli, Alon

AU - Banerjee, Sarbajit

AU - Bonnin, Michele

AU - van de Burgt, Yoeri

AU - Cheng, Bojun

AU - Chua, Leon

AU - Civalleri, Pier Paolo

AU - Corinto, Fernando

AU - Cui, Tie Jun

AU - Das, Saptarshi

AU - Demirkol, Ahmet Samil

AU - van Dijken, Sebastiaan

AU - Fan, Yijia

AU - Fang, Lu

AU - Farronato, Matteo

AU - Feng, Zi Rui

AU - Gemo, Emanuele

AU - Gilli, Marco

AU - Goswami, Sreetosh

AU - He, Yuhui

AU - Huang, Chaoran

AU - Huang, Qianqian

AU - Hwang, Cheol Seong

AU - Ielmini, Daniele

AU - Jang, Yoon Ho

AU - Kuncic, Zdenka

AU - Lemme, Max Christian

AU - Li, Can

AU - Liang, Shi Jun

AU - Liu, Keqin

AU - Liu, Shaojie

AU - Luo, Jin

AU - Ma, Qian

AU - Maass, Wolfgang

AU - Mannocci, Piergiulio

AU - Messaris, Ioannis

AU - Miao, Feng

AU - Mikolajick, Thomas

AU - Ntinas, Vasilis

AU - Ponis, John

AU - Prodromakis, Themis

AU - Prousalis, Dimitris

AU - Shao, Qiming

AU - Slesazeck, Stefan

AU - Strachan, John Paul

AU - Tan, Hongwei

AU - Tang, Jianshi

AU - Tetzlaff, Ronald

AU - Tran, Le Phuong Lan

AU - Valov, Ilia

AU - Vorias, Anthony

AU - Wang, Benshan

AU - Wang, Jiangjing

AU - Wang, Shengbo

AU - Wang, Xiaozhe

AU - Wang, Yasai

AU - Wu, Huaqiang

AU - Xia, Qiangfei

AU - Xiao, Kai

AU - Xiao, Zhihua

AU - Xiong, Zheshun

AU - Xu, Tengji

AU - Yang, Ming Jay

AU - Yang, Yuchao

AU - Yang, Yuekun

AU - Zhang, Wei

AU - Chai, Yang

PY - 2026/3/17

Y1 - 2026/3/17

N2 - The rapid growth of artificial intelligence (AI) is increasingly constrained by fundamental hardware bottlenecks in computation throughput and energy efficiency. Bioinspired computing (BIC) offers a promising alternative by emulating the intrinsic advantages of biological systems, such as parallelism, adaptability, and robustness. Progress in BIC hardware demands interdisciplinary convergence that bridges materials science and device physics with neuroscience, computer science, mathematics, and information science. Therefore, the development of this cross-disciplinary field urgently requires a comprehensive roadmap that analyzes systematically and in-depth the frontier issues and the latest progress. In this roadmap, we categorize the critical challenges into three components: hardware foundations, architectures, and prototype realizations. We highlight how biological features inspire the design of BIC hardware through device physics and discuss their performance metrics and engineering challenges. We then describe how diverse signaling rules and structural organizations in BIC architectures support specific computational prototypes, including electronic and photonic BIC chips, and present a technological roadmap that outlines opportunities to expand the functional scope of BIC hardware through coordinated advances in devices, architectures, and system demonstrations. This ongoing convergence of interdisciplinary knowledge can help accelerate the shift toward high-efficiency AI hardware.

AB - The rapid growth of artificial intelligence (AI) is increasingly constrained by fundamental hardware bottlenecks in computation throughput and energy efficiency. Bioinspired computing (BIC) offers a promising alternative by emulating the intrinsic advantages of biological systems, such as parallelism, adaptability, and robustness. Progress in BIC hardware demands interdisciplinary convergence that bridges materials science and device physics with neuroscience, computer science, mathematics, and information science. Therefore, the development of this cross-disciplinary field urgently requires a comprehensive roadmap that analyzes systematically and in-depth the frontier issues and the latest progress. In this roadmap, we categorize the critical challenges into three components: hardware foundations, architectures, and prototype realizations. We highlight how biological features inspire the design of BIC hardware through device physics and discuss their performance metrics and engineering challenges. We then describe how diverse signaling rules and structural organizations in BIC architectures support specific computational prototypes, including electronic and photonic BIC chips, and present a technological roadmap that outlines opportunities to expand the functional scope of BIC hardware through coordinated advances in devices, architectures, and system demonstrations. This ongoing convergence of interdisciplinary knowledge can help accelerate the shift toward high-efficiency AI hardware.

UR - https://www.scopus.com/pages/publications/105033012436

UR - https://www.scopus.com/pages/publications/105033012436#tab=citedBy

U2 - 10.1021/acsnano.5c17087

DO - 10.1021/acsnano.5c17087

M3 - Review article

C2 - 41771048

AN - SCOPUS:105033012436

SN - 1936-0851

VL - 20

SP - 8102

EP - 8163

JO - ACS nano

JF - ACS nano

IS - 10

ER -

Technology Roadmap of Bioinspired Computing Hardware

Abstract

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