Solution-Processed Networks of Silicon Nanocrystals: The Role of Internanocrystal Medium on Semiconducting Behavior

abstract

We have produced networks of surface-oxidized and hydrogen-terminated silicon nanocrystals (Si-NCs), both intrinsic and n-type doped, on flexible plastic foil from nanoparticle inks The charge transport in these networks was : comprehensively studied by means of time-dependent conductivity, steady-state current versus voltage characteristics, and steady-state photocurrent measurements as a function of incident light intensity. These measurements were complemented by surface chemistry and structural/morphological analysis from Fourier transform infrared spectroscopy and electron microscopy. Whereas H-terminated Si-NC networks function as semiconductors (both in air and in vacuum), where conductivity enhancement upon impurity doping and photoconductivity were observed, these characteristics are not present in networks of surface-oxidized Si-NCs. For both network types, the observation of a power law behavior for steady-state current versus voltage and a current decaying with time at constant bias indicate that charge transport is controlled by space-charge-limited current (involving trap states) via percolation paths through the networks. We have also monitored the evolution of the networks (photo)conductivity when the internanocrystal separating medium formed by Si-H bonds is progressively replaced by a native oxide upon exposure to air. Although a decrease in the (photo)conductivity is observed, the networks still behave as semiconductors even after a long-term air exposure. From an analysis of all (photo)current data, we deduce that in networks of oxidized Si-NCs inter-NC charge transfer requires the participation of oxide-related electronic states, whereas in H-terminated Si-NC networks direct inter-NC charge transfer plays a major role in the overall long-range conduction process.

keywords

LIGHT-EMITTING DEVICES; HYBRID SOLAR-CELLS; A-SI-H; POROUS SILICON; CARRIER TRANSPORT; CHARGE INJECTION; OXIDATION; SURFACES; ELECTROLUMINESCENCE; PHOTOLUMINESCENCE

subject category

Chemistry; Science & Technology - Other Topics; Materials Science

authors

Pereira, RN; Niesar, S; You, WB; da Cunha, AF; Erhard, N; Stegner, AR; Wiggers, H; Willinger, MG; Stutzmann, M; Brandt, MS

Groups

acknowledgements

The work has been supported by the EU (PSYNANO), the DFG (grants SFB 631 C3, GK 1240), Evonik Degussa S2B Nanotronics, the state of North Rhine-Westfalia, the Karl-Max von Bauernfeind-Verein of the TUM, the International Graduate School

Share this project:

Related Publications

We use cookies for marketing activities and to offer you a better experience. By clicking “Accept Cookies” you agree with our cookie policy. Read about how we use cookies by clicking "Privacy and Cookie Policy".