Advanced Functional Materials and Devices (AFMD) Group

Detection of trap charge in small molecular organic bulk heterojunction solar cells

Physical Review B - Condensed Matter and Materials Physics 82:12 (2010)

Authors:

D Ray, L Burtone, K Leo, M Riede

Abstract:

We detect and measure the trap charges in a small molecular bulk heterojunction solar cell under operating conditions. The trap-charge density is estimated from capacitance measurements with light incident on the sample. At high intensities (∼1sun, 100mW/ cm2), the trapped charge concentration leads to a spatial distortion of the electric field in the device. The lower limit of the trap-charge density is estimated to be 6× 10 16 cm-3. The frequency dependence of the capacitance suggests that the charges are trapped in a manifold of deep states present in the energy gap of the semiconductors. The distortion of the electric field by this trap charge affects the charge-carrier collection efficiency. © 2010 The American Physical Society.

Organic thin-film layer investigation with pair-distribution function technique

Acta Crystallographica Section A: Foundations and advances International Union of Crystallography (IUCr) 66:a1 (2010) s73-s73

Authors:

Chris Elschner, Alexandr A Levin, Karl Leo, Moritz Riede

X-ray investigation of the morphology of DCV6T-Bu4 films for organic solar cells

Acta Crystallographica Section A: Foundations and advances International Union of Crystallography (IUCr) 66:a1 (2010) s97-s98

Authors:

Alexandr A Levin, Marieta Levichkova, Dirk Hildebrandt, Andre Weiss, Marina Klisch, Chris Elschner, David Wynands, Martin Pfeiffer, Karl Leo, Moritz Riede

Increase in internal quantum efficiency in small molecular oligothiophene: C60 mixed heterojunction solar cells by substrate heating

Applied Physics Letters 97:7 (2010)

Authors:

D Wynands, M Levichkova, K Leo, C Uhrich, G Schwartz, D Hildebrandt, M Pfeiffer, M Riede

Abstract:

We present small molecule solar cells with α,ω-bis- (dicyanovinylene)-sexithiophene: C60 mixed heterojunctions, reaching power conversion efficiencies of 4.9±0.2%. We use substrate heating during deposition of the mixed layer to achieve an optimized morphology and show that this significantly improves the internal quantum efficiencies (IQEs) to values approaching 70%. By optical modeling, we evaluate the amount of loss due to absorption in inactive layers and show that IQE of the active layer itself is about 80%. © 2010 American Institute of Physics.

Highly doped layers as efficient electron-hole recombination contacts for tandem organic solar cells

Journal of Applied Physics 108:3 (2010)

Authors:

R Timmreck, S Olthof, K Leo, MK Riede

Abstract:

A key feature of stacked organic solar cells is an efficient recombination contact at the interface between the solar cells in the stack. Here, an electron current has to be converted into a hole current without loss of energy. Furthermore, the recombination contact has to be highly transparent. We present a new approach for small molecule organic solar cells using highly doped organic layers. Our approach adapts the use of tunnel diodes known from inorganic tandem solar cells. We compare a metal cluster based recombination contact reported in literature to the new approach using different organic tandem solar cell structures. For this purpose, current-voltage characteristics of adequate solar cells are measured. The experiments show that highly doped layers as recombination contacts in tandem organic solar cells are superior to the metal cluster based approach. The proposed concept allows an addition of the open circuit voltages of the subcells of a tandem solar cell, without absorption or reflection at the recombination contact. The results further show that our concept does not depend on the specific choice of materials as it is seen for metal cluster based recombination contacts. It therefore represents a general approach which is compatible to mass manufacturing. © 2010 American Institute of Physics.