The theoretical proposal by Peter Higgs University of Edinburgh together with related work by François Englert Université Libre de Bruxelles and Robert Brout Université Libre de Bruxelles describes a pervasive scalar field that endows elementary particles with observed inertial mass. The Higgs field acquires a nonzero value in the vacuum through spontaneous breaking of the electroweak symmetry, so that particles interacting with this background field behave as if they possess inertia. Gauge bosons associated with the weak force pick up mass because their interactions probe the direction in field space that no longer respects the original symmetry, while the photon remains massless because it corresponds to an unbroken gauge direction. Fermions obtain mass through coupling strengths to the same scalar field, with larger couplings producing heavier particles. The Higgs boson appears as the quantum excitation of that field, a localized ripple whose detection validates the mechanism.
Mechanism of mass generation
The mechanism explains why masses emerge without explicit mass terms that would violate the symmetry structure of the Standard Model, preserving predictive power while accounting for diverse particle masses. The scalar nature of the Higgs field makes it unique among fundamental fields, since most other carrier fields are vectorial and mediate forces; the scalar field instead defines the structure of the vacuum across space. The pattern of masses and mixings among quarks and leptons follows from the values of their couplings to the Higgs field, which remain parameters to be probed experimentally and through theoretical constraints. The existence of a nonzero vacuum value has consequences for early-universe dynamics and model building in particle cosmology.
Experimental confirmation and impact
Signals compatible with a new scalar particle were reported by the ATLAS experiment at CERN and the CMS experiment at CERN, institutions that operate large-scale detectors at the Large Hadron Collider on the Franco-Swiss border in Geneva, providing empirical support for the theoretical framework. Confirmation of the Higgs mechanism secures the Standard Model explanation for how fundamental constituents acquire mass, which in turn underlies the formation of atoms, chemistry, stars and planets, thereby linking microscopic symmetry breaking to macroscopic structure. The discovery also stimulated international collaboration, technological advances in accelerator and detector engineering, and ongoing research into the field’s deeper connections to cosmology, naturalness questions and possible extensions beyond the Standard Model.
