Browsing by Author "Gregorkiewicz, Tom"
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- Carrier multiplication in germanium nanocrystalsPublication . Saeed, Saba; de Weerd, Chris; Stallinga, Peter; Spoor, Frank C. M.; Houtepen, Arjan J.; Siebbeles, Laurens D. A.; Gregorkiewicz, TomCarrier multiplication is demonstrated in a solid-state dispersion of germanium nanocrystals in a silicon-dioxide matrix. This is performed by comparing ultrafast photo-induced absorption transients at different pump photon energies below and above the threshold energy for this process. The average germanium nanocrystal size is approximately 5-6 nm, as inferred from photoluminescence and Raman spectra. A carrier multiplication efficiency of approximately 190% is measured for photo-excitation at 2.8 times the optical bandgap of germanium nanocrystals, deduced from their photoluminescence spectra.
- Optical excitation and external photoluminescence quantum efficiency of Eu3+ in GaNPublication . de Boer, W. D. A. M.; McGonigle, C.; Gregorkiewicz, Tom; Fujiwara, Y.; Tanabe, S.; Stallinga, PeterWe investigate photoluminescence of Eu-related emission in a GaN host consisting of thin layers grown by organometallic vapor-phase epitaxy. By comparing it with a reference sample of Eu-doped Y2O3, we find that the fraction of Eu3+ ions that can emit light upon optical excitation is of the order of 1%. We also measure the quantum yield of the Eu-related photoluminescence and find this to reach (similar to 10%) and (similar to 3%) under continuous wave and pulsed excitation, respectively.
- Resonant energy transfer in Si Nanocrystal SolidsPublication . Limpens, Rens; Lesage, Arnon; Stallinga, Peter; Poddubny, Alexander N.; Fujii, Minoru; Gregorkiewicz, TomEnergy exchange between closely packed semiconductor quantum dots allows for long-range transfer of electronic energy and enables new functionalities of nanostructured materials with a huge application potential in photonics, optoelectronics, and photovoltaics. This is illustrated by impressive advances of quantum-dot solids based on nanocrystals (NCs) of direct bandgap materials, where this effect has been firmly established. Regretfully, the (resonant) energy transfer in close-packed ensembles of NCs remains elusive for silicon the main material for electronic and photovoltaic industries. This is the subject of the present study in which we conclusively demonstrate this process taking place in dense dispersions of Si NCs in an SiO2 matrix. Using samples with different NC configurations, we can directly determine the wavelength dependent energy transfer rate and show that it (i) can be modulated by material parameters, and (ii) decreases with the NCs size, and thus being consistent with the energy flow proceeding from smaller to larger NCs. This result opens the way to new applications of Si NCs, requiring energy transport and extraction. In particular, it forms a fundamental step toward development of an excitonic all-Si solar cell, operating in some analogy to polymer devices.