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Beyond silicon: materials, mechanisms, and methods for physical neural computing
Citation Link: https://doi.org/10.15480/882.17213
Publikationstyp
Journal Article
Date Issued
2026-05-08
Sprache
English
TORE-DOI
Journal
Volume
14
Start Page
72578
End Page
72612
Citation
IEEE Access 14: 72578-72612 (2026)
Publisher DOI
Scopus ID
Publisher
IEEE
Physical implementations of neural computation now extend far beyond silicon hardware, encompassing substrates such as memristive devices, photonic circuits, mechanical metamaterials, microfluidic networks, chemical reaction systems, and living neural tissue. By exploiting intrinsic physical processes, such as charge transport, wave interference, elastic deformation, mass transport, and biochemical regulation, these substrates can realize neural inference and adaptation directly in matter. As silicon GPU-centered AI faces growing energy and data-movement constraints, physical neural computation becomes increasingly relevant as a complementary path beyond conventional digital accelerators. This trend is driven in particular by pervasive intelligence, i.e., the deployment of on-device and edge AI across large numbers of resource-constrained systems. In such settings, co-locating computation with sensing and memory can reduce data shuttling and improve efficiency. Meanwhile, physical neural approaches have emerged across disparate disciplines, yet progress remains fragmented, with limited shared terminology and few principled ways to compare platforms. This survey unifies the field by mapping neural primitives to substrate-specific mechanisms, analyzing architectural and training paradigms, and identifying key engineering constraints including scalability, precision, programmability, and I/O interfacing overhead. To enable cross-domain comparison, we introduce a first-order benchmarking scheme based on standardized static and dynamic tasks and physically interpretable performance dimensions. We show that no single substrate dominates across the considered dimensions; instead, physical neural systems occupy complementary operating regimes, enabling applications ranging from ultrafast signal processing and in-memory inference to embodied control and in-sample biochemical decision making.
Subjects
benchmarking frameworks
in-memory computing
mechanical metamaterials
memristive systems
microfluidic and chemical computing
neuromorphic hardware
photonic neural networks
Physical neural computing
reservoir computing
DDC Class
530: Physics
Publication version
publishedVersion
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Beyond_Silicon_Materials_Mechanisms_and_Methods_for_Physical_Neural_Computing.pdf
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