Fill Factor Losses and Deviations from the Superposition Principle in Lead Halide Perovskite Solar Cells

Grabowski, David; Liu, Zhifa; Schöpe, G.; Rau, Uwe; Kirchartz, Thomas

doi:10.1002/solr.202200507

Cited by 31 publications

(45 citation statements)

References 82 publications

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“…A simple way to distinguish between the ideal case with a voltage-independent photocurrent ( J sc ) and the nonideal case with a voltage-dependent photocurrent J ph is to plot the sum J ( V , Φ) + J sc (Φ) (with J sc > 0), which is depicted in Figure a–c for different thicknesses and illumination intensities. This approach of shifting the light J – V curves into the first quadrant and plotting them logarithmically has been infrequently used in various photovoltaic technologies ,,,, starting with Si in the late 1970s but has so far not been discussed in the context of organic photovoltaics. The shifted J – V curve resembles a dark J – V curve and represents the deviation from the voltage-independent ideal case J ( V , Φ) + J sc (Φ) = J d ( V ) – ( J ph ( V , Φ) – J sc (Φ)) = J d ( V ) – Δ J ph ( V , Φ), where J ph > 0 and Δ J ph < 0.…”

Section: Resultsmentioning

confidence: 99%

Understanding the Thickness and Light-Intensity Dependent Performance of Green-Solvent Processed Organic Solar Cells

et al. 2023

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For indoor light harvesting, the adjustable band gap of molecular semiconductors is a significant advantage relative to many inorganic photovoltaic technologies. However, several challenges have to be overcome that include processability in nonhalogenated solvents, sufficiently high thicknesses (>250 nm) and high efficiencies at illuminances typically found in indoor environments. Here, we report on the development and application of new methods to quantify and identify performance losses based on thickness- and intensity-dependent current density–voltage measurements. Furthermore, we report on the fabrication of solar cells based on the blend PBDB-T:F-M processed in the nonhalogenated solvent o-xylene. In the low-intensity regime, insufficiently high shunt resistances limit the photovoltaic performance and by analyzing current density voltage–curves for solar cells with various shunt resistances we find that ∼100 kΩ cm2 are required at 200 lux. We provide a unified description of fill factor losses introducing the concept of light-intensity-dependent apparent shunts that originate from incomplete and voltage-dependent charge collection. In experiment and simulation, we show that good fill factors are associated with a photo-shunt inversely scaling with intensity. Intensity regions with photo-shunt resistances close to the dark-shunt resistance are accompanied by severe extraction losses. To better analyze recombination, we perform a careful analysis of the light intensity and thickness dependence of the open-circuit voltage and prove that trap-assisted recombination dominates the recombination losses at low light intensities.

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Section: Resultsmentioning

confidence: 99%

Understanding the Thickness and Light-Intensity Dependent Performance of Green-Solvent Processed Organic Solar Cells

et al. 2023

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“…While the fill factor of halide perovskites with typical bandgaps in the range ≈1.6 eV could exceed 90% in the detailed balance limit, in practice reported fill factors were mostly in the range of 80% to 84% for the best devices. [ 18 ] Recently, however, strategies based on interface modifications were reported to improve the fill factor up to 86% even for areas >1 cm 2 while at the same time enabling high efficiencies above 23%. [ 19 ] Also in the field of higher bandgap p–i–n type perovskite solar cells, high fill factors above 86% were achieved by interfacial passivation with guanidinium bromide.…”

Section: Highest Efficiency Research Photovoltaic Cellsmentioning

confidence: 99%

Device Performance of Emerging Photovoltaic Materials (Version 3)

Almora

Baran

Bazan

et al. 2022

Advanced Energy Materials

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Following the 2nd release of the "Emerging PV reports," the best achievements in the performance of emerging photovoltaic devices in diverse emerging photovoltaic research subjects are summarized, as reported in peer-reviewed articles in academic journals since August 2021. Updated graphs, tables, and analyses are provided with several performance parameters, e.g., power conversion efficiency, open-circuit voltage, short-circuit current density, fill factor, light utilization efficiency, and stability test energy yield. These parameters are presented as a function of the photovoltaic bandgap energy and the average visible transmittance for each technology and application, and are put into perspective using, e.g., the detailed balance efficiency limit. The 3rd installment of the "Emerging PV reports" extends the scope toward triple junction solar cells.The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/aenm.202203313.

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“…From the Suns‐ V oc and Suns‐PL analysis, it is straight‐forward to produce pseudo‐ J ‐ V curves and to calculate the corresponding pseudo‐fill factor (pFF) and pseudo‐maximum power point ( pP max ) of these curves. [ 36–38 ] While SQ analysis defines the upper limit of the FF and maximum power point ( P max ) by considering only radiative recombination losses, the pP max and pFF provide a measure of the highest possible values that could be achieved with the current level of non‐radiative recombination without the influence of series resistance or transport losses. Another useful parameter is the charge collection efficiency

\frac{{{J_{{\rm{SC,i}}}}}}{{{J_{\rm{L}}}}}

which defines the probability that photogenerated electron‐hole pairs will dissociate and transport to the electrodes.…”

Section: Introductionmentioning

confidence: 99%

“…This can be extended to compare ϕ i at each pixel to the mean PL intensity

\overline {{\phi _i}}

dQFL{S_i} = \;kT\ln \left( {\frac{{{\phi _i}}}{{\overline {{\phi _i}} }}} \right)

in order to produce a relative QFLS map. By applying the common assumption that at steady state (indicated by subscript SS)

\overline {QFL{S_{{\rm{i,SS}}\;}}}

= qV OC,SS [ 36,42,43 ] and add the relative QFLS to each pixel, the local QFLS is given by,

\begin{array}{*{20}{c}}{QFL{S_i} = q{V_{{\rm{OC,}}\;{\rm{SS}}}}\; + kT\ln \left( {\frac{{{\phi _i}}}{{\overline {{\phi _{{\rm{i,SS}}}}} }}} \right)}\end{array}

…”

Section: Introductionmentioning

confidence: 99%

“…The pFF and pP max analysis used here has been described in detail by others. [ 36–38 ] The parameters are calculated using an explicit analytical solution which is derived in the Supporting Information. The general approach for the voltage‐related parameters is to use the definition of the ideality factor in Equation (2) to define the change in V OC from a reference value V ref measured at a corresponding reference photocurrent density J L,ref ,

\begin{array}{*{20}{c}}{{V_{{\rm{OC}}}} = {V_{{\rm{Ref}}}}\; + n{V_{\rm{t}}}\ln \left( {\frac{{{J_{\rm{L}}}}}{{{J_{{\rm{L}},{\rm{ref}}}}}}} \right)}\end{array}

…”

Section: Introductionmentioning

confidence: 99%

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Ideality Factor Mapping of Back‐Contact Perovskite Solar Cells

Rietwyk

Lin

Tan

et al. 2023

Advanced Energy Materials

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They enjoy high optical absorption, nearideal band gaps, high carrier mobilities, and long carrier diffusion lengths. [1][2][3][4][5][6] Meanwhile, this class of materials consists of Earth-abundant elements and is solution-processable, making it a low-cost material. [7,8] At present, sandwich structure perovskite solar cells (PSC) have demonstrated power conversion efficiencies (PCE) as high as 25.7%, only 0.4% behind monocrystalline silicon. [9] However, there has been growing interest in PSC with a back-contact architecture due to various advantages in the design compared to sandwich PSC. A key improvement is the enhanced light harvesting, due to the elimination of the front contact and its parasitic light absorption. This offers the opportunity to employ an anti-reflective coating and a front-textured perovskite layer. [6] Drift-diffusions simulations reveal an improvement in photocurrents by ≈20% [10] and with further optimization, the PCE of back-contact PSC is expected to exceed their sandwich structure counterparts. [11,12] This has already been demonstrated in the case of silicon-based devices, with champion silicon back-contact solar cells enjoying a PCE of 26.6%. [13] There has also been growing interest in PSC with a back-contact architecture as a component in tandem cells in order to exceed the Shockley-Queisser (SQ) limit of a single junction. [14,15] To date, the stabilized PCE for back-contact PSC has reached 11.5 and 9.1% for single and poly-crystalline perovskite-based devices, respectively. [16,17] While short-circuit current densities (J SC ) have exceeded 20 mA cm −2 for poly-crystalline PSC, the reported fill factors (FF) ≤ 0.56 and open-circuit voltage (V OC ) ≤ 1.06 V have been underwhelming. [17][18][19][20][21][22][23][24][25][26][27] Low FF is typically attributed to poor carrier transport and excessive recombination in the absorber layer and/or across the perovskite/transport layer interfaces. [28] Recently, our group has demonstrated that the incorporation of a mesoporous TiO 2 layer, which increases the interfacial contact area, improves charge extraction resulting in significant increases in the J SC and FF of 36 and 25%, respectively. [17] The low V OC indicates high non-radiative recombination rates. Recently, Tainter et al. [27] reported on back-contact cells that enjoy long diffusion lengths (≥12 µm), slow surface recombination velocities ≈2 cm s −1 with short circuit currents of 18.4 mA cm −2 (external quantum efficiency (EQE) of 70%) but a meager V OC = 0.57 V. They propose the limiting factor in their devices to be high dark saturation currents, a parameter that The efficiency of back-contact perovskite solar cells has steadily increased over the past few years and now exceeds 11%, with interest in these devices shifting from proof-of-concept to viable technology. In order to make further improvements in the efficiency of these devices it is necessary to understand the cause of the low fill factor, low open-circuit voltage (V OC ), and severe hysteresis. Here a time-dependent...

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Fill Factor Losses and Deviations from the Superposition Principle in Lead Halide Perovskite Solar Cells

Cited by 31 publications

References 82 publications

Understanding the Thickness and Light-Intensity Dependent Performance of Green-Solvent Processed Organic Solar Cells

Understanding the Thickness and Light-Intensity Dependent Performance of Green-Solvent Processed Organic Solar Cells

Device Performance of Emerging Photovoltaic Materials (Version 3)

Ideality Factor Mapping of Back‐Contact Perovskite Solar Cells

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