Abstract: The Belle II experiment collects data from electron-positron collisions with a centre-of-mass energy close to that of the Y(4S) resonance. The experiment has been designed primarily to study B-meson produced in Y(4S)->BBbar decays but there are significant studies of charm hadrons, tau leptons and spectroscopy as well. This talk will focus on non-flavour area of Belle II's physics programme: low-multiplicity physics, i.e., final states of electron-positron collisions with only a few particles. This part of the Belle II programme has two distinct components. The first is the precision determination of e+ e- -> hadron cross sections over a wide range of centre-of-mass energies; this wide range of energies is accessed using events with initial-state radiation. These hadronic cross section measurements are the limiting factor in estimating the hadronic vacuum polarisation (HVP) contribution to the anomalous magnetic moment of the muon (g-2) via dispersion relations. Given the various tensions between different estimates of the HVP contribution, Belle II will provide much needed additional information. The most important process to measure is e+e- -> pi+pi-gamma, with only 3 particles in the final state. The second component of the programme is to search for beyond-the-standard-model particles that couple weakly to the standard model, the so-called dark sector. Belle II has world leading sensitivity to some proposed dark-sector particles in the mass range of 100 MeV up to approximately 10 GeV. These dark sector signatures generally have only one to four visible particles in the final state. Both these low-multiplicity aspects of the Belle II physics programme will be introduced.  

Abstract:
Integrating Large Language Models (LLMs) into modern research workflows presents a critical challenge. While AI agents excel at functional syntax, they lack scientific intuition, frequently hallucinating scientific logic or silently discarding governing physical laws to optimize performance. To safely harness LLMs without producing invalid tools, we advocate for the Scientist-AI-Loop (SAIL). This human-in-the-loop framework structurally decouples scientific logic from coding syntax. The researcher acts as the conceptual architect, enforcing theoretical boundaries and identifying breakdowns, while the AI handles implementation. Validated via two visualization tools, a real-time gravitational lensing application and a dynamic cosmic structure formation simulation, SAIL provides a domain-agnostic blueprint broadly applicable to science, from particle physics to cosmology and other disciplines. During development, SAIL exposed critical, invisible AI failures where agents confidently fabricated physics. By structuring the progression from initial concept to final code, SAIL compresses development timelines from months to mere days. More importantly, it safeguards scientific integrity, ensuring that generative tools can finally be trusted for professional modeling and science communication.

Test the tools here:

• Gravitational Lensing Application: https://nicosmo.github.io/lensing_visualization/
• Cosmic Web Explorer: https://nicosmo.github.io/cosmic_web_explorer/