Classification of Collective Modes in a Charge Density Wave by Momentum-Dependent Modulation of the Electronic Band Structure

Abstract

We present time- and angle-resolved photoemission spectroscopy measurements on the charge density wave system CeTe3. Optical excitation transiently populates the unoccupied band structure and reveals a gap size of 2 = 0.59 eV. The occupied Te-5p band dispersion is coherently modified by three modes at 1 = 2.2 THz, 2 = 2.7 THz and 3 = 3 THz. All three modes lead to small rigid energy shifts whereas is only affected by 1 and 2. Their spatial polarization is analyzed by fits of a transient model dispersion and DFT frozen phonon calculations. We conclude that the modes 1 and 2 result from in-plane ionic lattice motions, which modulate the charge order, and that 3 originates from a generic out-of-plane A1g phonon. We thereby demonstrate how the rich information from trARPES allows identification of collective modes and their spatial polarization, which explains the mode-dependent coupling to charge order.