Degradation mechanism(s) of GaAs solar cells with Cu contacts

Leest, R. H. van; Kleijne, K. de; Bauhuis, G.J.; Mulder, P.; Cheun, Hyeunseok; Lee, H.; Yoon, Wonki; Heijden, R. van der; Bongers, E.; Vlieg, Elias; Schermer, J.J.

doi:10.1039/c6cp01428c

Cited by 12 publications

(24 citation statements)

References 44 publications

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“…After 55 days at 200 ○ C the cell on an Au carrier shows a smooth Au/GaAs interface at the back (see figure 4a), whereas the cell on a Cu carrier shows an intermixed Au/Cu layer and a GaAs contact layer that appears to have been almost fully consumed by the Au/Cu matrix already after 3.7 days at 200 ○ C (see figure 4b). This undulation of the metal/GaAs interface and intermixing of the Au and Cu is similar to the undulation and intermixing previously observed for substrate-based cells after 1320 h (55 days) at 200 ○ C (see figure 6b in reference [35]). The intermixing of the Au and Cu is in agreement with the observed colour change of the carrier foil (see figure 3).…”

Section: B Characterization and Accelerated Life-time Testingsupporting

confidence: 65%

“…The significant decrease in J sc observed for the thin-film cells on Cu carriers is in sharp contrast with the small changes (typically 1-2%) observed for cells on an Au carrier and substrate-based cells with and without Cu (both in this study and in previous work [34], [35], [40]). This indicates that the degradation process causing the decrease in J sc is specific for thin-film cells on a Cu carrier and therefore of interest for further investigation.…”

Section: B Characterization and Accelerated Life-time Testingcontrasting

confidence: 49%

“…Unfortunately experimental determination is difficult and hence there are very few activation energies reported for solar cell degradation [29], [32], [33] and none of these concern (Cu) diffusion. The European Cooperation for Space Standardization (ECSS) standard for In previous studies [34], [35] a substrate-based model system utilizing a 45% coverage front contact grid was used to investigate the effects of Cu diffusion on GaAs solar cells. In these studies it was shown that at temperatures < 250 ○ C Cu diffusion has no significant effect on the J-V characteristics of (substrate-based) solar cells.…”

Section: Introductionmentioning

confidence: 99%

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Temperature-Induced Degradation of Thin-Film III–V Solar Cells for Space Applications

Leest

Mulder

Gruginskie

et al. 2017

IEEE J. Photovoltaics

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Abstract-High efficiency, thin-film III-V solar cells offer excellent characteristics for implementation in flexible solar panels for space applications. In order to investigate the space compatibility of such cells. The temperature-induced degradation of both substrate-based cells with Au and Au/Cu contacts and thin-film cells on Au and Cu carriers was studied by accelerated ageing testing (AAT) at 200 ○ C. With less than 3% decrease in efficiency after 37 days at 200 ○ C (equivalent to 10 years at 100 ○ C for Ea = 0.70 eV) the substrate-based cells show excellent results. With a 10% decrease in efficiency after 37 days of AAT the thin-film cells on an Au carrier exhibit promising results, given the early stage of development of the thin-film cells. On the other hand severe degradation is observed for thin-film cells on a Cu carrier (decrease in efficiency > 60% after 37 days of AAT). At least two factors contribute to this severe degradation: thermally-induced stress and Cu diffusion.

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Section: B Characterization and Accelerated Life-time Testingsupporting

confidence: 65%

Section: B Characterization and Accelerated Life-time Testingcontrasting

confidence: 49%

Section: Introductionmentioning

confidence: 99%

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Temperature-Induced Degradation of Thin-Film III–V Solar Cells for Space Applications

Leest

Mulder

Gruginskie

et al. 2017

IEEE J. Photovoltaics

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“…non temperature-induced) lightand/or electrically-induced degradation mechanisms these operating conditions were excluded in the test procedure used in this study. In a previous study 20 we used the abbreviation ALT for this test procedure, but as this might be confusing we will refer to the adapted test procedure as accelerated ageing testing (AAT). The main difficulty with this accelerated testing approach is that it requires a known activation energy.…”

Section: Introductionmentioning

confidence: 99%

Metal diffusion barriers for GaAs solar cells

Leest¹,

Mulder²,

Bauhuis³

et al. 2017

Phys. Chem. Chem. Phys.

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In this study accelerated ageing testing (AAT), J-V characterization and TEM imaging in combination with phase diagram data from literature are used to assess the potential of Ti, Ni, Pd and Pt as diffusion barriers for Au/Cu-based metallization of III-V solar cells. Ni barriers show the largest potential as at an AAT temperature of 250 • C both cells with 10 and 100 nm thick Ni barriers show significantly better performance compared to Au/Cu cells, with the cells with 10 nm Ni barriers even showing virtually no degradation after 7.5 days at 250 • C (equivalent to 10 years at 100 • C at an E a of 0.70 eV). Detailed investigation shows that Ni does not act as a barrier in the classical sense, i.e. preventing diffusion of Cu and Au across the barrier. Instead Ni modifies or slows down the interactions taking place during device degradation and thus effectively acts as an 'interaction' barrier. Different interactions occur at temperatures below and above 250 • C and for thin (10 nm) and thick (100 nm) barriers. The results of this study indicate that 10-100 nm thick Ni intermediate layers in the Cu/Au based metallization of III-V solar cells may be beneficial to improve the device stability upon exposure to elevated temperatures.

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“…Furthermore, Cu has also been used as a part of the back side contact in GaAs solar cells, but Cu is also known to diffuse easily into III-V semiconductors and thus to reduce the V oc . [20][21][22] In our approach, we have studied GaInNAs solar cells with double-layer Ag/Cu reflectors exhibiting high reflectance, good adhesion, and low contact resistance. Moreover, a thin Ag layer acts as a diffusion barrier, preventing Cu diffusion into the semiconductor structure even when the cell is subjected to thermal annealing.…”

mentioning

confidence: 99%

Enhancement of photocurrent in GaInNAs solar cells using Ag/Cu double-layer back reflector

Aho

Tukiainen

et al. 2016

Applied Physics Letters

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The effect of a Ag/Cu-based double-layer back reflector on current generation in GaInNAs single-junction solar cell is reported. Compared to Ti/Au reflector, the use of Ag/Cu led to a 28% enhancement of short-circuit current density, attaining a value of ∼14 mA/cm2 at AM1.5D (1000 W/m2) under a GaAs filter. The enhanced current generation is in line with requirements for current-matching in GaInP/GaAs/GaInNAs triple-junction solar cells. The Ag/Cu reflectors also had a low contact resistivity of the order of 10−6 Ω·cm2 and none of the samples exhibited notable peeling of metals in the adhesion tests. Moreover, no discernible diffusion of the metals into the semiconductor was observed after thermal annealing at 200 °C.

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Degradation mechanism(s) of GaAs solar cells with Cu contacts

Cited by 12 publications

References 44 publications

Temperature-Induced Degradation of Thin-Film III–V Solar Cells for Space Applications

Temperature-Induced Degradation of Thin-Film III–V Solar Cells for Space Applications

Metal diffusion barriers for GaAs solar cells

Enhancement of photocurrent in GaInNAs solar cells using Ag/Cu double-layer back reflector

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