Microsecond Carrier Lifetimes, Controlled p-Doping, and Enhanced Air Stability in Low-Bandgap Metal Halide Perovskites

Bowman, Alan R.; Klug, Matthew T.; Doherty, Tiarnan A. S.; Farrar, Michael D.; Senanayak, Satyaprasad P.; Wenger, Bernard; Divitini, Giorgio; Booker, Edward P.; Andaji‐Garmaroudi, Zahra; Macpherson, Stuart; Ruggeri, Edoardo; Sirringhaus, Henning; Snaith, Henry J.; Stranks, Samuel D.

doi:10.1021/acsenergylett.9b01446

Cited by 55 publications

(102 citation statements)

References 41 publications

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“…Improving the homogeneity of the perovskite film is of critical importance to the electrical properties such as defect density and carrier lifetime. [ 24,45 ] To investigate the phase distribution of Pb–Sn hybrid perovskite films using sequential deposition method, we carried out a detailed microstructure analysis. First, surface X‐ray photoelectron spectroscopy (XPS) reveals that the Sn/Pb atomic ratio matches the composition used in precursor solutions.…”

Section: Resultsmentioning

confidence: 99%

“…The decrease in FF can result from the uncontrolled p‐doping induced by Sn 2+ oxidation to Sn 4+ (Figure S14, Supporting Information), which significantly reduces the charge carrier diffusion length of Sn‐based perovskite films. [ 8,45 ] While the PSC with 60% Sn still shows a PCE of 13.7%, the performance quickly deteriorates upon further increasing Sn‐content ( x ≥ 0.75). We expect that the rough Sn‐rich perovskite films (Figure S8, Supporting Information) introduce shunting pathways and thereby more recombination losses in the solar cells.…”

Section: Resultsmentioning

confidence: 99%

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Understanding the Film Formation Kinetics of Sequential Deposited Narrow‐Bandgap Pb–Sn Hybrid Perovskite Films

Wang

Datta

et al. 2020

Advanced Energy Materials

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state-of-the-art inorganic photovoltaic (PV) technologies. [4] Developing all-perovskite tandem solar cells with complementary bandgaps is considered as the next step to surpass the Shockley-Queisser efficiency limit for single-junction devices. [5][6][7][8] Solution processability of all components at low-temperature would enhance incentives to explore large-scale implementation of such multi-junction cells. [9] Previous studies [10][11][12] of tandem solar cells have suggested that a combination of a wide-bandgap (1.7 to 1.9 eV) front cell and a narrow-bandgap (0.9 to 1.2 eV) rear cell is ideal for high efficiency multijunctions. Hybrid perovskites AMX 3 , where A is a monovalent cation (formamidinium (FA + ), methylammonium (MA + ) or Cs + ), M is a divalent metal cation (Pb 2+ or Sn 2+ ), and X is a halide anion (I − or Br − ), [13] have a broadly tunable bandgap via compositional engineering. [14] The bandgap of Pb-based perovskites can be continuously tuned from 1.5 to 2.3 eV by substituting I with Br. [15,16] On the other hand, a nonlinear bandgap behavior [17] is observed when alloying Pb (1.5 eV) and Sn-based (1.3 eV) perovskites, providing a minimum bandgap of ≈1.2 eV at 50% to 75% Sncontent. [18][19][20][21] Such mixed Pb-Sn perovskites are considered the most promising narrow-bandgap perovskite materials for tandem devices. [21,22] However, compared to their Pb analogs, Sn-based perovskite precursors have a greater tendency to react and crystallize at room temperature, [23] which makes it difficult to grow compact, smooth, and homogeneous Developing efficient narrow bandgap Pb-Sn hybrid perovskite solar cells with high Sn-content is crucial for perovskite-based tandem devices. Film properties such as crystallinity, morphology, surface roughness, and homogeneity dictate photovoltaic performance. However, compared to Pb-based analogs, controlling the formation of Sn-containing perovskite films is much more challenging. A deeper understanding of the growth mechanisms in Pb-Sn hybrid perovskites is needed to improve power conversion efficiencies. Here, in situ optical spectroscopy is performed during sequential deposition of Pb-Sn hybrid perovskite films and combined with ex situ characterization techniques to reveal the temporal evolution of crystallization in Pb-Sn hybrid perovskite films. Using a twostep deposition method, homogeneous crystallization of mixed Pb-Sn perovskites can be achieved. Solar cells based on the narrow bandgap (1.23 eV) FA 0.66 MA 0.34 Pb 0.5 Sn 0.5 I 3 perovskite absorber exhibit the highest efficiency among mixed Pb-Sn perovskites and feature a relatively low dark carrier density compared to Sn-rich devices. By passivating defect sites on the perovskite surface, the device achieves a power conversion efficiency of 16.1%, which is the highest efficiency reported for sequential solutionprocessed narrow bandgap perovskite solar cells with 50% Sn-content.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Understanding the Film Formation Kinetics of Sequential Deposited Narrow‐Bandgap Pb–Sn Hybrid Perovskite Films

Wang

Datta

et al. 2020

Advanced Energy Materials

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“…In that system, the large‐bandgap 2D surface layer is sufficiently thin that charge injection to the contacts can still occur, though the layer still passivates trap states at the surfaces and grain boundaries of the 3D material. The self‐assembled heterostructures presented in our work here could be optimized for application to low bandgap Pb:Sn 3D perovskite solar cells, relevant as bottom cells in tandem structures, which to date are even more hindered by nonradiative losses and stability issues than their pure‐lead counterparts . In another example, the most efficient light‐emitting diodes (LEDs) employing bulk perovskite films utilize 2D/3D mixed systems that allow an efficient cascade of injected carriers from the wider bandgap 2D materials to the lower bandgap 3D materials, leading to high luminescence efficiencies in the 3D layer .…”

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confidence: 99%

Controlling the Growth Kinetics and Optoelectronic Properties of 2D/3D Lead–Tin Perovskite Heterojunctions

et al. 2019

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Halide perovskites are emerging as valid alternatives to conventional photovoltaic active materials owing to their low cost and high device performances. This material family also shows exceptional tunability of properties by varying chemical components, crystal structure, and dimensionality, providing a unique set of building blocks for new structures. Here, highly stable self‐assembled lead–tin perovskite heterostructures formed between low‐bandgap 3D and higher‐bandgap 2D components are demonstrated. A combination of surface‐sensitive X‐ray diffraction, spatially resolved photoluminescence, and electron microscopy measurements is used to reveal that microstructural heterojunctions form between high‐bandgap 2D surface crystallites and lower‐bandgap 3D domains. Furthermore, in situ X‐ray diffraction measurements are used during film formation to show that an ammonium thiocyanate additive delays formation of the 3D component and thus provides a tunable lever to substantially increase the fraction of 2D surface crystallites. These novel heterostructures will find use in bottom cells for stable tandem photovoltaics with a surface 2D layer passivating the 3D material, or in energy‐transfer devices requiring controlled energy flow from localized surface crystallites to the bulk.

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“…Perovskite photovoltaic devices have demonstrated efficiencies of up to 25.2% in lab conditions [49] and typically have lifetimes ranging from tens of nanoseconds to microseconds [50]. Perovskites with short lifetimes (tens of ns) can be resolved with TRTS techniques [51], however perovskite lifetimes on the order of microseconds cannot be calculated with TRTS [40] and have been resolved with PL techniques [50]. Moreover, perovskite semiconductors can be fabricated using wet chemistry techniques.…”

Section: Germaniummentioning

confidence: 99%

The Development Of Long Timescale Terahertz Spectroscopy Techniques To Measure Lifetimes Of Photovoltaic Materials

Blinick¹

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Insulators…………………………… 2 1.2 Excitation of charge carriers into the conduction band………………… 6 1.3 Lifetimes of semiconductors………………………………………………. 8 1.3.1 Lifetimes and Recombination Processes…………………… 9 1.3.2 The effect of Shockley-Read-Hall recombination on lifetimes………………………………………………………. 12 Chapter 2: Experimental characterization of semiconductors……………… 14 2.1 Contact measurements to calculate lifetimes………………………….. 15 2.2 Non-contact measurements to calculate lifetimes…………………….

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Microsecond Carrier Lifetimes, Controlled p-Doping, and Enhanced Air Stability in Low-Bandgap Metal Halide Perovskites

Cited by 55 publications

References 41 publications

Understanding the Film Formation Kinetics of Sequential Deposited Narrow‐Bandgap Pb–Sn Hybrid Perovskite Films

Understanding the Film Formation Kinetics of Sequential Deposited Narrow‐Bandgap Pb–Sn Hybrid Perovskite Films

Controlling the Growth Kinetics and Optoelectronic Properties of 2D/3D Lead–Tin Perovskite Heterojunctions

The Development Of Long Timescale Terahertz Spectroscopy Techniques To Measure Lifetimes Of Photovoltaic Materials

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