Probing axionlike particles with γγ final states from vector boson fusion processes at the LHC

We perform a feasibility study to search for axionlike particles (ALPs) using vector boson fusion (VBF) processes at the LHC. We work in an effective field theory framework with a cutoff scale $\\mathrm{\\ensuremath{\\Lambda}}$ and ALP mass ${m}_{a}$, and assume that ALPs couple to photons with strength $\\ensuremath{\\propto}1/\\mathrm{\\ensuremath{\\Lambda}}$. Assuming proton-proton collisions at $\\sqrt{s}=13\\text{ }\\text{ }\\mathrm{TeV}$, we present the total VBF ALP production cross sections, ALP decay widths and lifetimes, and relevant kinematic distributions as a function of ${m}_{a}$ and $\\mathrm{\\ensuremath{\\Lambda}}$. We consider the $a\\ensuremath{\\rightarrow}\\ensuremath{\\gamma}\\ensuremath{\\gamma}$ decay mode to show that the requirement of an energetic diphoton pair combined with two forward jets with large dijet mass and pseudorapidity separation can significantly reduce the Standard Model backgrounds, leading to a $5\\ensuremath{\\sigma}$ discovery reach for $10\\text{ }\\text{ }\\mathrm{MeV}\\ensuremath{\\lesssim}{m}_{a}\\ensuremath{\\lesssim}1\\text{ }\\text{ }\\mathrm{TeV}$ with $\\mathrm{\\ensuremath{\\Lambda}}\\ensuremath{\\lesssim}2\\text{ }\\text{ }\\mathrm{TeV}$, assuming an integrated luminosity of $3000\\text{ }\\text{ }{\\mathrm{fb}}^{\\ensuremath{-}1}$. In particular, this extends the LHC sensitivity to a previously unstudied region of the ALP parameter space.