My research explores the connection between particles, the smallest things we know, and our Universe, the largest there is. Our best theory of the particle world, the Standard Model (SM), does not answer important questions about the Universe we observe, such as why there is much more matter than antimatter. Physicists have proposed many theories to address these questions, and I've shown that the very fact that we are here is a test of the validity of such theories, as they often predict an unstable Universe (PLB, 2014). In my research, I have also proposed models that unify nature's forces and address the
SM's shortcomings (PRD, 2017). Lately, I have worked on how the dynamics of the early Universe could have led to gravitational waves that would be clear evidence of physics beyond the SM (JHEP, 2021).
Beyond my physics research, I've co-founded the Art and Science Initiative, created a multisensory exhibit for the London
Science Museum, and was invited by the UN to a multi-year future-envisioning exercise. I co-host a podcast documenting the journey towards the first feature film written by an AI.
et al., 2022, Simple and statistically sound recommendations for analysing physical theories, Reports on Progress in Physics, Vol:85, ISSN:0034-4885
Camargo-Molina JE, Enberg R, Lofgren J, 2021, A new perspective on the electroweak phase transition in the Standard Model Effective Field Theory, Journal of High Energy Physics, ISSN:1029-8479
Allanach BC, Camargo-Molina JE, Davighi J, 2021, Global fits of third family hypercharge models to neutral current B-anomalies and electroweak precision observables, European Physical Journal C, Vol:81, ISSN:1434-6044
et al., 2021, Global fits of axion-like particles to XENON1T and astrophysical data, Journal of High Energy Physics, ISSN:1029-8479
Camargo-Molina JE, Markkanen T, Scott P, 2019, Dark energy without fine tuning, The Journal of High Energy Physics, Vol:44, ISSN:1029-8479, Pages:1-14