Optoelectronic and material properties of nanocrystal-based CZTSe absorbers with Ag-alloying

Hages, Charles J.; Koeper, Mark J.; Agrawal, Rakesh

doi:10.1016/j.solmat.2015.10.039

Cited by 123 publications

(96 citation statements)

References 46 publications

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“…First, no correlation between the measured PL decay times and device performance over a wide range (1%-12%) of device efficiencies (shown in Figure 2) and open-circuit voltage V OC (see the Supporting Information) can be found from published TRPL data. [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24] These results are in contrast to that found from TRPL analysis of chalcopyrites and CdTe where a correlation with device efficiency and V OC is clear, as τ n is a measure of recombination losses. [33][34][35][36] However, for kesterites the connection between PL decay time and the assumed τ n is not apparent, as the reported decay times represent arbitrary measurement excitation conditions and data analysis procedures; characteristic decay times from a variety of fitting regions and techniques are reported for measured TRPL data.…”

Section: Introductioncontrasting

confidence: 92%

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Identifying the Real Minority Carrier Lifetime in Nonideal Semiconductors: A Case Study of Kesterite Materials

Hages

Redinger

Levcenko

et al. 2017

Advanced Energy Materials

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Time‐resolved photoluminescence (TRPL) is a powerful characterization technique to study carrier dynamics and quantify absorber quality in semiconductors. The minority carrier lifetime, which is critically important for high‐performance solar cells, is often derived from TRPL analysis. However, here it is shown that various nonideal absorber properties can dominate the TRPL signal making reliable extraction of the minority carrier lifetime not possible. Through high‐resolution intensity‐, temperature‐, voltage‐dependent, and spectrally resolved TRPL measurements on absorbers and devices it is shown that photoluminescence (PL) decay times for kesterite materials are dominated by minority carrier detrapping. Therefore, PL decay times do not correspond to the minority carrier lifetime for these materials. The lifetimes measured here are on the order of hundreds of picoseconds in contrast to the nanosecond lifetimes suggested by the decay curves. These results are supported with additional measurements, device simulation, and comparison with recombination limited PL decays measured on Cu(In,Ga)Se2. The kesterite material system is used as a case study to demonstrate the general analysis of TRPL data in the limit of various measurement conditions and nonideal absorber properties. The data indicate that the current bottleneck for kesterite solar cells is the minority carrier lifetime.

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Section: Introductioncontrasting

confidence: 92%

“…Data are taken from refs. [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24]. The solid lines represent device simulation results bounded by S F = 10 2 -10 6 cm s −1 and S B = 10 2 -10 7 cm s −1 ; the dashed line represents a lower bound on the efficiency for a reduced mobility gap E µ = E PL,Peak .…”

Section: Introductionmentioning

confidence: 99%

Identifying the Real Minority Carrier Lifetime in Nonideal Semiconductors: A Case Study of Kesterite Materials

Hages

Redinger

Levcenko

et al. 2017

Advanced Energy Materials

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114

150

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“…Specifically, we calculate the Urbach energy from the inverse slope of the linear portion in the sub-bandgap region of the plot between ln(−ln(1 − EQE)) and E − E g . [45] We extract an Urbach energy of ≈40-55 meV for all of the samples. Although the E U values are slightly overestimated due to inefficient charge-carrier collection at long wavelengths (see Section 2.4.3), the values measured here are consistent with those extracted from photothermal deflection spectroscopy measurements by Huang et al, where an E U of 53 meV was measured for both Cu 2 ZnSnS 4 and Cu 2 CdSnS 4 .…”

Section: Urbach Energymentioning

confidence: 99%

Suppressed Deep Traps and Bandgap Fluctuations in Cu₂CdSnS₄ Solar Cells with ≈8% Efficiency

Hadke

Levcenko

Gautam

et al. 2019

Advanced Energy Materials

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postdeposition alkali treatment to improve heterojunction diode quality in Cu(In,Ga) Se 2 (CIGS) solar cells and chloride treatment to passivate grain boundaries in CdTe solar cells. [1] These solar-cell technologies are already commercialized, with lab-scale photovoltaic efficiencies exceeding 22%. [2] However, kesterite-based solar cells, such as Cu 2 ZnSn(S,Se) 4 , which share many of the same characteristics of CIGS and CdTe, significantly lag behind, with a record power conversion efficiency (PCE) of 12.6%. [3] Although the dominant limiting factors for this low performance are a matter of considerable discussion, [4] the following observations are consistent among kesterite absorbers: i) a low photoluminescence quantum yield (PLQY) and a short chargecarrier lifetime, [5] ii) a high value of Urbach band tail energy (larger than 30 meV for S-rich kesterites) and lack of a steep absorption onset, [6,7] and iii) the presence of secondary phases. [4,6,8,9] The extent to which these factors individually affect the photovoltaic performance is debated, but their ubiquity among kesterite absorbers indicates the presence of a large density of point defects. [10][11][12] Specifically, i) the low PLQY arises from the presence of nonradiative mid-gap The identification of performance-limiting factors is a crucial step in the development of solar cell technologies. Cu 2 ZnSn(S,Se) 4 -based solar cells have shown promising power conversion efficiencies in recent years, but their performance remains inferior compared to other thin-film solar cells. Moreover, the fundamental material characteristics that contribute to this inferior performance are unclear. In this paper, the performance-limiting role of deep-trap-level-inducing 2Cu Zn +Sn Zn defect clusters is revealed by comparing the defect formation energies and optoelectronic characteristics of Cu 2 ZnSnS 4 and Cu 2 CdSnS 4 . It is shown that these deleterious defect clusters can be suppressed by substituting Zn withCd in a Cu-poor compositional region. The substitution of Zn with Cd also significantly reduces the bandgap fluctuations, despite the similarity in the formation energy of the Cu Zn +Zn Cu and Cu Cd +Cd Cu antisites. Detailed investigation of the Cu 2 CdSnS 4 series with varying Cu/[Cd+Sn] ratios highlights the importance of Cu-poor composition, presumably via the presence of V Cu , in improving the optoelectronic properties of the cation-substituted absorber. Finally, a 7.96% efficient Cu 2 CdSnS 4 solar cell is demonstrated, which shows the highest efficiency among fully cation-substituted absorbers based on Cu 2 ZnSnS 4 .

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“…This observation suggests that there is a turning point in the curve of E g vs. Ag concentration, which explains the controversial observation of previous works, i.e., it is reported in ref. 17,18 and 20 that the band gap increases with the ratio of Ag/(Ag + Cu), but it is found in ref. 19 that the band gap decreases with the ratio of Ag/(Ag + Cu).…”

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confidence: 95%

Efficient (Cu_1−xAg_x)₂ZnSn(S,Se)₄ solar cells on flexible Mo foils

Cheng

Yan

et al. 2018

RSC Adv.

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Cation substitution plays a crucial role in improving the efficiency of Cu 2 ZnSn(S,Se) 4 (CZTSSe) solar cells. In this work, we report a significant efficiency enhancement of flexible CZTSSe solar cells on Mo foils by partial substitution of Cu + with Ag + . It is found that the band gap (E g ) of (Cu 1Àx Ag x ) 2 ZnSn(S,Se) 4 (CAZTSSe) thin films can be adjusted by doping with Ag with x from 0 to 6%, and the minimum E g is achieved with x ¼ 5%. We also found that Ag doping can obviously increase the average grain size of the CAZTSSe absorber from 0.4 to 1.1 mm. Additionally, the depletion width (W d ) at the heterojunction interface of CAZTSSe/CdS is found to be improved. As a result, the open-circuit voltage deficit (V oc,def ) is gradually decreased, and the band tailing is suppressed. Benefiting from the enhanced open-circuit voltage (V oc ), the power conversion efficiency (PCE) is successfully enhanced from 4.34% (x ¼ 0) to 6.24% (x ¼ 4%), and the V oc,def decreases from 915 to 848 mV.

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Optoelectronic and material properties of nanocrystal-based CZTSe absorbers with Ag-alloying

Cited by 123 publications

References 46 publications

Identifying the Real Minority Carrier Lifetime in Nonideal Semiconductors: A Case Study of Kesterite Materials

Identifying the Real Minority Carrier Lifetime in Nonideal Semiconductors: A Case Study of Kesterite Materials

Suppressed Deep Traps and Bandgap Fluctuations in Cu₂CdSnS₄ Solar Cells with ≈8% Efficiency

Efficient (Cu_1−xAg_x)₂ZnSn(S,Se)₄ solar cells on flexible Mo foils

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Optoelectronic and material properties of nanocrystal-based CZTSe absorbers with Ag-alloying

Cited by 123 publications

References 46 publications

Identifying the Real Minority Carrier Lifetime in Nonideal Semiconductors: A Case Study of Kesterite Materials

Identifying the Real Minority Carrier Lifetime in Nonideal Semiconductors: A Case Study of Kesterite Materials

Suppressed Deep Traps and Bandgap Fluctuations in Cu2CdSnS4 Solar Cells with ≈8% Efficiency

Efficient (Cu1−xAgx)2ZnSn(S,Se)4 solar cells on flexible Mo foils

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Product

Resources

About

Suppressed Deep Traps and Bandgap Fluctuations in Cu₂CdSnS₄ Solar Cells with ≈8% Efficiency

Efficient (Cu_1−xAg_x)₂ZnSn(S,Se)₄ solar cells on flexible Mo foils