English

Solving the compute crisis with physics-based ASICs

Emerging Technologies 2025-07-15 v1 Hardware Architecture

Abstract

Escalating artificial intelligence (AI) demands expose a critical "compute crisis" characterized by unsustainable energy consumption, prohibitive training costs, and the approaching limits of conventional CMOS scaling. Physics-based Application-Specific Integrated Circuits (ASICs) present a transformative paradigm by directly harnessing intrinsic physical dynamics for computation rather than expending resources to enforce idealized digital abstractions. By relaxing the constraints needed for traditional ASICs, like enforced statelessness, unidirectionality, determinism, and synchronization, these devices aim to operate as exact realizations of physical processes, offering substantial gains in energy efficiency and computational throughput. This approach enables novel co-design strategies, aligning algorithmic requirements with the inherent computational primitives of physical systems. Physics-based ASICs could accelerate critical AI applications like diffusion models, sampling, optimization, and neural network inference as well as traditional computational workloads like scientific simulation of materials and molecules. Ultimately, this vision points towards a future of heterogeneous, highly-specialized computing platforms capable of overcoming current scaling bottlenecks and unlocking new frontiers in computational power and efficiency.

Keywords

Cite

@article{arxiv.2507.10463,
  title  = {Solving the compute crisis with physics-based ASICs},
  author = {Maxwell Aifer and Zach Belateche and Suraj Bramhavar and Kerem Y. Camsari and Patrick J. Coles and Gavin Crooks and Douglas J. Durian and Andrea J. Liu and Anastasia Marchenkova and Antonio J. Martinez and Peter L. McMahon and Faris Sbahi and Benjamin Weiner and Logan G. Wright},
  journal= {arXiv preprint arXiv:2507.10463},
  year   = {2025}
}

Comments

16 pages, 5 figures

R2 v1 2026-07-01T04:00:24.048Z