Tandem solar cells that pair silicon with a metal halide perovskite are a promising option for surpassing the single-cell efficiency limit. We report a monolithic perovskite/silicon tandem with a certified power conversion efficiency of 29.15%. The perovskite absorber, with a bandgap of 1.68 electron volts, remained phase-stable under illumination through a combination of fast hole extraction and minimized nonradiative recombination at the hole-selective interface. These features were made possible by a self-assembled, methyl-substituted carbazole monolayer as the hole-selective layer in the perovskite cell. The accelerated hole extraction was linked to a low ideality factor of 1.26 and single-junction fill factors of up to 84%, while enabling a tandem open-circuit voltage of as high as 1.92 volts. In air, without encapsulation, a tandem retained 95% of its initial efficiency after 300 hours of operation.
Perovskite–silicon tandem solar cells offer the possibility of overcoming the power conversion efficiency limit of conventional silicon solar cells. Various textured tandem devices have been presented aiming at improved optical performance, but optimizing film growth on surface-textured wafers remains challenging. Here we present perovskite–silicon tandem solar cells with periodic nanotextures that offer various advantages without compromising the material quality of solution-processed perovskite layers. We show a reduction in reflection losses in comparison to planar tandems, with the new devices being less sensitive to deviations from optimum layer thicknesses. The nanotextures also enable a greatly increased fabrication yield from 50% to 95%. Moreover, the open-circuit voltage is improved by 15 mV due to the enhanced optoelectronic properties of the perovskite top cell. Our optically advanced rear reflector with a dielectric buffer layer results in reduced parasitic absorption at near-infrared wavelengths. As a result, we demonstrate a certified power conversion efficiency of 29.80%.
Approaches to boost the efficiency and stability of perovskite solar cells often address one singular problem in a specific device configuration. In this work, we utilize a poly(ionic-liquid) (PIL) to...
Through the optimization
of the perovskite precursor composition
and interfaces to selective contacts, we achieved a p-i-n-type perovskite
solar cell (PSC) with a 22.3% power conversion efficiency (PCE). This
is a new performance record for a PSC with an absorber bandgap of
1.63 eV. We demonstrate that the high device performance originates
from a synergy between (1) an improved perovskite absorber quality
when introducing formamidinium chloride (FACl) as an additive in the
“triple cation” Cs0.05FA0.79MA0.16PbBr0.51I2.49 (Cs-MAFA) perovskite
precursor ink, (2) an increased open-circuit voltage, V
OC, due to reduced recombination losses when using a lithium
fluoride (LiF) interfacial buffer layer, and (3) high-quality hole-selective
contacts with a self-assembled monolayer (SAM) of [2-(9H-carbazol-9-yl)ethyl]phosphonic acid (2PACz) on ITO electrodes. While
all devices exhibit a high performance after fabrication, as determined
from current–density voltage, J–V, measurements, substantial differences in device performance
become apparent when considering longer-term stability data. A reduced
long-term stability of devices with the introduction of a LiF interlayer
is compensated for by using FACl as an additive in the metal-halide
perovskite thin-film deposition. Optimized devices maintained about
80% of the initial average PCE during maximum power point (MPP) tracking
for >700 h. We scaled the optimized device architecture to larger
areas and achieved fully laser patterned series-interconnected mini-modules
with a PCE of 19.4% for a 2.2 cm2 active area. A robust
device architecture and reproducible deposition methods are fundamental
for high performance and stable large-area single junction and tandem
modules based on PSCs.
Monolithic perovskite/silicon tandem solar cells recently surpass the efficiency of silicon single‐junction solar cells. Most tandem cells utilize >250 μm thick, planarized float‐zone (FZ) silicon, which is not compatible with commercial production using <200 μm thick Czochralski (CZ) silicon. The perovskite/silicon tandem cells based on industrially relevant 100 μm thick CZ‐silicon without mechanical planarization are demonstrated. The best power conversion efficiency (PCE) of 27.9% is only marginally below the 28.2% reference value obtained on the commonly used front‐side polished FZ‐Si, which are about three times thicker. With both wafer types showing the same median PCE of 27.8%, the thin CZ‐Si‐based devices are preferred for economic reasons. To investigate perspectives for improved current matching and, therefore, further efficiency improvement, optical simulations with planar and textured silicon have been conducted: the perovskite's bandgap needs to be increased by ≈0.02 eV when reducing the silicon thickness from 280 to 100 μm. The need for bandgap enlargement has a strong impact on future tandem developments ensuring photostable compositions with lossless interfaces at bandgaps around or above 1.7 eV.
Silicon solar cells have been the working horses of the photovoltaic industry for decades. Continuous technological progress has led to increases in power conversion efficiency (PCE) and driven the levelized cost of electricity (LCOE) down to 1.33 $ct kWh À1 in sunny regions such as Chile. [1] To continue this success story, the combination of a silicon bottom solar cell with a low-cost, wide-bandgap top cell into a tandem device is perceived as an intriguing technological path toward costeffective multijunction solar cells with PCEs beyond the silicon single-junction efficiency limit of 29.5%. [2] In particular, perovskite/silicon tandem solar cells have triggered impressive research and development that peaked in devices with PCEs approaching 30%. [3][4][5] However, as of late 2021, the majority of the reported monolithic perovskite/silicon tandem solar cells with highest PCE results rely on silicon heterojunction (SHJ) bottom cells, exploiting SHJ's high opencircuit voltages (see, e.g., Jost et al. for a recent review). [6] The
We present a monolithic two-terminal perovskite/ silicon tandem solar cell based on an industrial silicon bottom cell fabricated with mass-production-feasible processes. The solar cell exhibited a steady-state power conversion efficiency of 28.7% and an open-circuit voltage of over 1.9 V.
Achieving high solar-to-hydrogen (STH) efficiency concomitant with long-term durability using low-cost, scalable photo-absorbers is a long-standing challenge. Here we report the design and fabrication of a conductive adhesive-barrier (CAB) that translates >99% of photoelectric power to chemical reactions. The CAB enables halide perovskite-based photoelectrochemical cells with two different architectures that exhibit record STH efficiencies. The first, a co-planar photocathode-photoanode architecture, achieved an STH efficiency of 13.4% and 16.3 h to t60, solely limited by the hygroscopic hole transport layer in the n-i-p device. The second was formed using a monolithic stacked silicon-perovskite tandem, with a peak STH efficiency of 20.8% and 102 h of continuous operation before t60 under AM 1.5G illumination. These advances will lead to efficient, durable, and low-cost solar-driven water-splitting technology with multifunctional barriers.
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