High Harmonic Generation from a Noble Metal

High-harmonic generation (HHG) in solids has typically been explored in transparent dielectrics and semiconductors. Metals have long been dismissed due to their strong reflectivity at infrared wavelengths. Here, we demonstrate HHG from silver - a noble metal - using few-cycle near-infrared laser pulses at near-normal incidence. Our results show that sub-cycle electron dynamics within the material's penetration depth can drive high-order harmonics, challenging the prevailing notion that metals are unsuited for infrared-driven strong-field processes. Despite silver's high reflectivity and large free-electron density, we observe nonperturbative harmonics extending into the extreme ultraviolet (up to 20 eV). Moreover, silver's multi-shot damage threshold proves surprisingly high (30 TW/cm^2) - comparable to large-bandgap dielectrics like magnesium oxide - thereby enabling intense strong-field processes in a metallic environment. Measuring the orientation dependence of the emitted harmonics reveals that the process arises from coherent electron dynamics in the crystal lattice, rather than from a plasma-driven mechanism. Time-dependent density-matrix simulations based on maximally localized Wannier functions show that low-order harmonics predominantly originate from conduction electrons near the Fermi surface (s- and p-type orbitals), whereas higher harmonics rely on bound d-electron excitations. These findings establish metals - long thought unfavorable for HHG - as a promising platform for ultrafast strong-field physics, extending high-harmonic spectroscopy to regimes in which lattice order and plasma formation directly intersect. This work expands the frontier of solid-state HHG to all-metallic attosecond pulse generation and underscores the potential of metals as robust XUV sources for advanced attosecond metrology.