Photoelectron spectroscopy of metal cluster anions: Cu−n, Ag−n, and Au−n

Abstract

Negative ion photoelectron spectra of Cu⁻_n, Ag⁻_n(n=1–10), and Au⁻_n (n=1–5) are presented for electron binding energies up to 3.35 eV at an instrumental resolution of 6–9 meV. The metal cluster anions are prepared in a flowing afterglow ion source with a cold cathode dc discharge. In the spectra of Cu⁻₂, Ag⁻₂, and Au⁻₂, the M₂ X ¹Σ⁺_g←M⁻₂ X ²Σ⁺_u transitions are vibrationally resolved. We analyze these spectra to yield the adiabatic electron affinities, vibrational frequencies, bond length changes, and dissociation energies. The a ³Σ⁺_u triplet states of Cu₂ and Ag₂ are also observed. Using experimental and theoretical data, we assign the major features in the Cu⁻₃ and Ag⁻₃ spectra to the transition from the linear ground state of the anion (M⁻₃¹Σ⁺_g) to an excited linear state of the neutral (M₃ ²Σ⁺_u). The Au⁻₃ spectrum is attributed to a two‐photon process, photodissociation followed by photodetachment of the Au⁻ or Au⁻₂ fragment. For larger clusters, we measure the threshold and vertical detachment energies as a function of size. Trends in the electron affinities and excited state energy levels as a function of cluster size and composition are discussed in terms of simple models.