OpenAI’s GPT-5.2 has helped uncover a surprising breakthrough in theoretical physics:
A class of gluon scattering amplitudes long assumed to be zero actually becomes nonzero under a precisely defined “half-collinear” momentum regime.
This result challenges textbook assumptions in quantum field theory, opens new research paths (including extensions to gravitons), and showcases a powerful new model for AI-assisted discovery, where LLMs spot elegant patterns hidden in superexponentially complex math.
AI accelerating research yet again.
The paper: arxiv.org/abs/2602.12176
@aipost
A class of gluon scattering amplitudes long assumed to be zero actually becomes nonzero under a precisely defined “half-collinear” momentum regime.
This result challenges textbook assumptions in quantum field theory, opens new research paths (including extensions to gravitons), and showcases a powerful new model for AI-assisted discovery, where LLMs spot elegant patterns hidden in superexponentially complex math.
AI accelerating research yet again.
The paper: arxiv.org/abs/2602.12176
@aipost
OpenAI’s GPT-5.2 has helped uncover a surprising breakthrough in theoretical physics:
A class of gluon scattering amplitudes long assumed to be zero actually becomes nonzero under a precisely defined “half-collinear” momentum regime.
This result challenges textbook assumptions in quantum field theory, opens new research paths (including extensions to gravitons), and showcases a powerful new model for AI-assisted discovery, where LLMs spot elegant patterns hidden in superexponentially complex math.
AI accelerating research yet again.
The paper: arxiv.org/abs/2602.12176
@aipost 馃彺
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