• 
  Diederich, J.; Velazquez Rojas, J.; Paszuk, A.; Pour, M.A.Z.; Höhn, C.; Alvarado, I.A.R.; Schwarzburg, K.; Ostheimer, D.; Eichberger, R.; Schmidt, W.G.; Hannappel, T.; van de Krol, R.; Friedrich, D.: Ultrafast Electron Dynamics at the P-rich Indium Phosphide/TiO₂ Interface. Advanced Functional Materials 34 (2024), p. 2409455/1-13

10.1002/adfm.202409455
Open Access Version

Abstract:
The current efficiency records for generating green hydrogen via solar water splitting are held by indium phosphide (InP)-based photo-absorbers, protected by TiO2 layers grown through atomic layer deposition (ALD). InP is also a leading material for photonic integrated circuits and computing, where ultrafast near-surface behavior is key. A previous study described electronic pathways at the phosphorus-rich (P-rich) surface of p-doped InP(100) using time-resolved two-photon photoemission (tr-2PPE) spectroscopy. Here, the intricate electron pathways of the P-rich InP surface modified with ALD-deposited TiO2 are explored. Photoexcited bulk InP electrons migrate through a bulk-to-surface transition cluster of states and surface states and inject into the TiO2 conduction band (CB). Energy levels and occupation dynamics of CB states in P-rich InP and TiO2 adlayers are observed, with discrete states preserved up to 10 nm TiO2 deposition. Thermalization lifetimes of excited electrons > 0.8 eV above the InP conduction band minimum (CBM) are preserved for layer thicknesses up to 2.5 nm. Annealing at 300 °C to achieve crystalline TiO2 reconstructions destroys interfacial states, affecting charge transfer. These observations enable innovative engineering of the P-rich InP/TiO2 heterointerface, opening new possibilities for studying hot-carrier extraction, adsorbate effects, surface plasmons, and improving photovoltaic and PEC water-splitting devices.