Microscopic studies of polycrystalline nanoparticle growth in free space

Mohan, A.; Kaiser, M.; Verheijen, Marcel A.; Schropp, R.E.I.; Rath, J.K.

doi:10.1016/j.jcrysgro.2017.03.044

Cited by 4 publications

(2 citation statements)

References 37 publications

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“…High resolution TEM (Figure A–C) images reveal the typical nano‐porous “cauliflower” structure as recently found in silicon nanoparticles from the same apparatus and similar techniques . The “cauliflower” nanoparticles are aggregates of smaller germanium nanoparticles, likely of a quantum confined size.…”

Section: Resultssupporting

confidence: 88%

Germanium Quantum Dot Grätzel‐Type Solar Cell

Cardoso

Marom

Mayer

et al. 2018

Physica Status Solidi (a)

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Solar cells fabricated from sustainable quantum dot materials are currently not commercially available, but ongoing research provides a steady increase in efficiency and stability of laboratory devices. In this work, the first germanium quantum dot solar cell made with a gas aggregation nanoparticle source is presented. UV–vis spectroscopy reveals quantum confinement, and the spectral response of the germanium quantum dot Grätzel‐type solar cell confirms the presence of large and small band gap optical absorption due to a mix of particle sizes. Some of the particles are small enough to have substantial quantum confinement while others are so large that they have bulk‐like properties. The efficiency of the germanium quantum dot solar cells is very low but could reach 1% if the formation of germanium oxide layers is avoided in future experiments. This first quantum dot solar cell made with a gas aggregation nanoparticle source demonstrates, as a proof of concept, the technological potential for research and applications combining the fields of photovoltaics and gas aggregation nanoparticle sources.

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Section: Resultssupporting

confidence: 88%

Germanium Quantum Dot Grätzel‐Type Solar Cell

Cardoso

Marom

Mayer

et al. 2018

Physica Status Solidi (a)

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“…The fabrication of monodisperse silicon quantum dots with controllable separation distance is a prerequisite for successful application in a solar cell. Work by Mohan et al (Mohan A. et al, 2017) shows that it is possible to obtain silicon nanoparticles by using a pulsed SiH 4 /Ar plasma. In a recent work by Tang et al (Tang W. et al, 2015), the silicon nanoparticles were fabricated with a gas aggregation cluster source, which is a promising route.…”

Section: Quantum Dotsmentioning

confidence: 99%

Using Nanoparticles as a Bottom-up Approach to Increase Solar Cell Efficiency

Vece

2019

KONA

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Nanostructures in solar cells are used both for the active layers and for light management techniques. Particularly thin-film solar cells will benefit strongly from such nanoscale approaches as the light absorption needs to be improved. Nanoparticles produced by wet chemical techniques, sometimes in the form of quantum dots, are currently used to fabricate thin-film solar cells for research purposes. Light management studies use nanostructures that are often created by lithographic methods but which are too expensive for an industrial realisation. In this review paper, the opportunities for using nanoparticles as a bottom-up approach for both the active layer and light management nanostructures is discussed. Since both the wet chemical method and lithographic techniques have considerable limitations, the use of gas aggregation cluster sources is proposed as a promising method to advance the use of bottom-up nanoparticles for solar cells. Plasmonics, Mie scattering, quantum dots and new materials are reviewed with respect to the nanoparticle potential. The increase of solar cell efficiency by using ultra-clean and crystalline nanoparticles which are produced with a vacuum-compatible technique at low temperatures should be very interesting for science and technology, ultimately leading to industrial products.

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