Double Higgs Production via Vector Boson Fusion in SMEFT

TL;DR

This paper investigates how vector boson fusion can be used to detect signs of new physics in Higgs pair production at the LHC, focusing on effective field theory operators and their experimental signatures.

Contribution

It provides a comprehensive SMEFT analysis of VBF double Higgs production, identifying key operators and assessing their impact on observables at the HL-LHC.

Findings

VBF di-Higgs production shows modest enhancement over SM predictions.

In optimistic scenarios, VBF could be observable at HL-LHC.

Derivative operators can make VBF competitive with gluon fusion in certain cases.

Abstract

While gluon fusion dominates Higgs pair production at the LHC, vector boson fusion (VBF) offers a unique window into Beyond the Standard Model (BSM) physics through its distinctive kinematic features and direct sensitivity to Higgs-vector boson interactions. We perform a comprehensive analysis of double Higgs production via VBF in the Standard Model Effective Field Theory (SMEFT), systematically investigating how dimension-6 and dimension-8 bosonic operators - particularly those involving field derivatives - can enhance the production rate. We identify the most relevant Wilson coefficients (WCs) affecting the trilinear Higgs coupling ($hhh$) and Higgs-vector boson interactions ($hVV$, $hhVV$). Using constraints from global fits and interpolating fit results for unconstrained WCs with Naive Dimensional Analysis, we assess their effects on the $VV \to hh$ ($V = W,Z$) scattering amplitudes and cross-sections. Our analysis includes a study of EFT convergence and validity in models with scalar extensions of the SM. Numerical simulations for the planned High-Luminosity LHC experiment (HL-LHC) in general reveal only a modest and challenging to detect enhancement of the VBF di-Higgs production rate over the SM prediction. However, we show that in optimistic scenarios, such a process could be observed at the HL-LHC. In certain cases, when the enhancement is dominated by the dimension-6 or dimension-8 operators containing field derivatives (and thus leading to stronger energy-dependent effects), this channel becomes competitive with di-Higgs production via gluon fusion. This work highlights the role of VBF di-Higgs production as a complementary channel for probing anomalous Higgs couplings and their impact on BSM physics.