Enhanced light absorption in nanotextured amorphous thin-film silicon caused by femtosecond-laser materials processing
Differt D, Soleymanzadeh B, Lükermann F, Strüber C, Pfeiffer W, Stiebig H (2015)
Solar Energy Materials and Solar Cells 135: 72-77.
Zeitschriftenaufsatz
| Veröffentlicht | Englisch
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Abstract / Bemerkung
Efficient thin-film solar cells balance the reduced absorption occurring in thin absorber layers by means of various photon management strategies that often involve randomly nanotextured interfaces. We report on broadband absorption enhancement in nanotextured amorphous silicon processed by femtosecond laser materials processing. As identified by micro-Raman spectroscopy and surface profilometry, the absorption of a single femtosecond amplifier laser pulse (30 fs, 795 nm, 75 mJ cm(-2)) creates a thin nanotextured micro-crystalline surface layer. Optical microscopy in transmission and reflection geometry reveals a broadband absorption enhancement in the visual spectrum range for the nanotextured area. Scattered light spectroscopy in combination with spectral interferometry indicates that light trapping for about 100 fs is achieved in the femtosecond-laser processed amorphous silicon area and thus is responsible for the observed enhanced absorption and locally enhanced Raman yields. Thus fs-laser materials processing offers an interesting pathway towards advanced photon management in amorphous silicon based thin-film solar cells. (C) 2014 Elsevier B.V. All rights reserved.
Stichworte
Photon management: photovoltaic devices;
Hydrogenated amorphous silicon;
Raman spectroscopy;
Femtosecond laser materials processing
Erscheinungsjahr
2015
Zeitschriftentitel
Solar Energy Materials and Solar Cells
Band
135
Seite(n)
72-77
ISSN
0927-0248
Page URI
https://pub.uni-bielefeld.de/record/2733498
Zitieren
Differt D, Soleymanzadeh B, Lükermann F, Strüber C, Pfeiffer W, Stiebig H. Enhanced light absorption in nanotextured amorphous thin-film silicon caused by femtosecond-laser materials processing. Solar Energy Materials and Solar Cells. 2015;135:72-77.
Differt, D., Soleymanzadeh, B., Lükermann, F., Strüber, C., Pfeiffer, W., & Stiebig, H. (2015). Enhanced light absorption in nanotextured amorphous thin-film silicon caused by femtosecond-laser materials processing. Solar Energy Materials and Solar Cells, 135, 72-77. doi:10.1016/j.solmat.2014.10.001
Differt, Dominik, Soleymanzadeh, Babak, Lükermann, Florian, Strüber, Christian, Pfeiffer, Walter, and Stiebig, Helmut. 2015. “Enhanced light absorption in nanotextured amorphous thin-film silicon caused by femtosecond-laser materials processing”. Solar Energy Materials and Solar Cells 135: 72-77.
Differt, D., Soleymanzadeh, B., Lükermann, F., Strüber, C., Pfeiffer, W., and Stiebig, H. (2015). Enhanced light absorption in nanotextured amorphous thin-film silicon caused by femtosecond-laser materials processing. Solar Energy Materials and Solar Cells 135, 72-77.
Differt, D., et al., 2015. Enhanced light absorption in nanotextured amorphous thin-film silicon caused by femtosecond-laser materials processing. Solar Energy Materials and Solar Cells, 135, p 72-77.
D. Differt, et al., “Enhanced light absorption in nanotextured amorphous thin-film silicon caused by femtosecond-laser materials processing”, Solar Energy Materials and Solar Cells, vol. 135, 2015, pp. 72-77.
Differt, D., Soleymanzadeh, B., Lükermann, F., Strüber, C., Pfeiffer, W., Stiebig, H.: Enhanced light absorption in nanotextured amorphous thin-film silicon caused by femtosecond-laser materials processing. Solar Energy Materials and Solar Cells. 135, 72-77 (2015).
Differt, Dominik, Soleymanzadeh, Babak, Lükermann, Florian, Strüber, Christian, Pfeiffer, Walter, and Stiebig, Helmut. “Enhanced light absorption in nanotextured amorphous thin-film silicon caused by femtosecond-laser materials processing”. Solar Energy Materials and Solar Cells 135 (2015): 72-77.
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