Two-color phase-controlled photoemission from a zero-dimensional nanostructure

Timo Paschen,Michael Krüger,Christoph Lemell,Florian Libisch,Michael Förster,Joachim Burgdörfer,Thomas Madlener,Peter Hommelhoff,Georg Wachter,G Cerullo,M Khalil,R Li,J Ogilvie,F Kärtner

doi:10.1051/epjconf/201920505004

Abstract

We demonstrate that multi-photon photoemission including above-threshold multiphoton orders from a nanotip can be coherently controlled with the optical phase between two light fields. By focusing 74 fs drive pulses at 1560 nm and their second harmonic at 780 nm onto the tip and changing the optical phase between the two colors, we observe an emission current modulation of up to 97.5 %. Additionally, electron energy spectra reveal a homogeneous modulation of all multiphoton orders. Hence, the electron current can be strongly increased (by a factor of 3.7) or almost completely turned off due to interference between two different quantum channels in the material. We argue that the extremely high degree of coherence evidenced by this near-unity current modulation depth is due to the confinement of the local field enhancement at the nanotip. The nano-rod effect allows to apply large DC fields, adding a further degree of freedom to investigate the modulation contrast of the photoemitted electron yield. We show that for an increasing DC electric field a non-cooperative distribution of electron emission leads to a decrease in modulation contrast.

Highlights

Ionization by two-color laser fields with well-defined relative phase allows one to tune and control electronic dynamics on the femtosecond time scale
We demonstrate that multi-photon photoemission including above-threshold multiphoton orders from a nanotip can be coherently controlled with the optical phase between two light fields
We show that for an increasing DC electric field a non-cooperative distribution of electron emission leads to a decrease in modulation contrast

Summary

Introduction

Ionization by two-color laser fields with well-defined relative phase allows one to tune and control electronic dynamics on the (sub-) femtosecond time scale. Timo Paschen1,*, Michael Förster1, Michael Krüger1, Christoph Lemell2, Georg Wachter2, Florian Libisch2, Thomas Madlener2, Joachim Burgdörfer2, and Peter Hommelhoff1,3 We demonstrate that multi-photon photoemission including above-threshold multiphoton orders from a nanotip can be coherently controlled with the optical phase between two light fields.

Results

Conclusion