Higgs pair production
Higgs boson pair production, also known as di-Higgs production, is a process in particle physics regarding the self-interactions of the Higgs boson. This process is essential for testing the structure of the Higgs potential and the mechanism of electroweak symmetry breaking (EWSB).
Motivation
After the Higgs boson was discovered in 2012, research efforts focused on exploring its interactions with other particles. While many of these couplings have been measured, the Higgs boson's self-coupling remains unmeasured. The shape of the Higgs potential in the Standard Model (SM) includes both trilinear and quartic self-couplings, which are key to understanding the nature of the Higgs field and EWSB.The Higgs potential in the SM is described as:
where is the Higgs boson mass, and and are the trilinear and quartic self-couplings. Precise measurements of these parameters could also indicate the presence of beyond the Standard Model (BSM) physics.
Production mechanisms at the LHC
At the Large Hadron Collider, Higgs boson pairs can be produced through several mechanisms:- Gluon–gluon fusion, the dominant production mode, proceeds via heavy quark loops and involves both box and triangle Feynman diagrams. Interference between these diagrams plays a significant role.
- Vector boson fusion, where Higgs bosons are radiated from virtual W or Z bosons exchanged between quarks.
- Associated production with top quark pairs or vector bosons, which become more relevant at higher center-of-mass energies.
Decay channels
Higgs boson pairs can decay through various channels. The most experimentally sensitive final states include:- HH → bb: Has the highest branching fraction but suffers from large QCD backgrounds.
- HH → bγγ: Low branching fraction but excellent mass resolution due to clean photon identification.
- HH → bτ+τ−: Offers a good compromise between signal rate and background contamination.
- Multilepton final states: Events with two or more leptons from bZZ, 4V, VVττ, 4τ, γγVV, and γγττ decays, with clean lepton signatures providing good background rejection despite moderate branching fractions.
- HH → bℓℓ+ETmiss: Semileptonic final states with contributions from bWW, bZZ, and bττ decays. Lower backgrounds than fully hadronic modes with reasonable branching fractions.
Experimental status
Higgs boson pair production has not yet been observed at the LHC. The Standard Model predicts a small cross-section for non-resonant HH production via gluon–gluon fusion, approximately 31 fb at a center-of-mass energy of 13 TeV. This small rate, coupled with large backgrounds in most decay channels, makes the search experimentally challenging.Higgs self-coupling constraints
The Higgs self-coupling directly affects the triangle diagram in ggF production and the t-diagram in VBF production. Experimental results place constraints on this coupling by measuring deviations in the total cross-section and kinematic distributions. Current constraints from global combinations of decay channels show that the self-coupling value is within experimental error of the SM value.Future prospects
The upcoming High Luminosity Large Hadron Collider, expected to deliver up to 3 ab−1 of data at, will significantly improve the sensitivity to HH production. The most recent combined ATLAS and CMS projections, prepared as input for the 2026 European Strategy for Particle Physics Update, suggest:- Discovery of SM non-resonant HH production with a combined significance exceeding 7σ,
- Discovery threshold reached with 2 ab−1 of combined data from both experiments,
- A measurement of with better than 30% precision,
- Discovery potential in certain BSM scenarios.
Future hadron colliders such as the FCC-hh could achieve percent-level precision on and may enable observation of triple Higgs boson production, directly constraining the quartic Higgs self-coupling.