Metal Halide Perovskite Solar Cells: Sources of High Efficiency, Stability Bottlenecks, and Experimental Decision Logic
Metal Halide Perovskite Solar Cells: Sources of High Efficiency, Stability Bottlenecks, and Experimental Decision Logic
Introduction
Perovskite is not a single substance, but a class of materials with specific crystal-structure characteristics. In the photovoltaic field, the term “perovskite” usually refers to metal halide perovskites. These materials are composed of organic or inorganic cations, metal ions, and halide ions, and are commonly used as light-absorbing layers in solar cells. The U.S. Department of Energy also notes that the perovskites commonly discussed in photovoltaics should be more accurately referred to as metal halide perovskites, which are different from many oxide perovskite materials.
These materials have attracted attention for two core reasons:
Core question | Key answer |
Why can they achieve high efficiency? | Strong light absorption in thin layers, tunable bandgaps, relatively good charge-transport properties, and suitability for forming tandem cells with silicon and other materials |
Why are they difficult to stabilize? | Moisture, oxygen, heat, light, voltage bias, ion migration, interfacial reactions, and insufficient encapsulation can jointly trigger degradation |
1. What Are Metal Halide Perovskites?
Metal halide perovskites can usually be understood in terms of the A site—B site—X site. The A site is generally occupied by organic or inorganic cations, the B site by metal ions, and the X site by halide ions such as iodide, bromide, and chloride.
Structural position | Common composition | Main influence |
A site | Methylammonium, formamidinium, cesium, and other cations | Affects lattice size, phase stability, and crystallization behavior |
B site | Lead, tin, and other metal ions | Affects bandgap, light absorption, charge transport, and environmental risks |
X site | Iodide, bromide, chloride, and other halide ions | Affects absorption range, bandgap, crystal phase, and defect behavior |
Three concepts should be distinguished first:
Concept | Explanation |
Perovskite structure | Refers to a class of crystal structures, not a single fixed compound |
Oxide perovskites | Mostly used in electronic ceramics, ferroelectrics, dielectric materials, catalysis, and related fields |
Metal halide perovskites | Commonly used in photovoltaics, light emission, and detection; this article focuses on solar cells |
2. Why Can Perovskite Solar Cells Achieve High Efficiency?
Metal halide perovskites can function as highly efficient light-absorbing layers mainly because of four material characteristics. According to the U.S. Department of Energy webpage, the efficiency of small-area perovskite solar cells has increased from about 3% in 2009 to more than 26%, while perovskite/silicon tandem cells have reached efficiencies approaching 34%; specific certified records will continue to be updated as new test results become available.
Source of high efficiency | Significance for solar cells |
Strong light absorption | A relatively thin absorber layer can absorb a large amount of sunlight |
Tunable bandgap | The absorption range can be adjusted through composition control, making the material suitable for both single-junction and tandem cells |
Long carrier diffusion length, allowing charges to be effectively separated and collected | Photogenerated electrons and holes have the opportunity to be efficiently extracted |
A certain degree of defect tolerance | Some defects have a relatively limited impact on performance, which is beneficial for low-temperature thin-film fabrication |
“Defect tolerance” does not mean that defects are unimportant. Deep-level defects, surface defects, grain-boundary defects, and interfacial defects can still cause non-radiative recombination, lowering the open-circuit voltage, fill factor, and long-term stability.
3. How Composition Control Affects Bandgap, Film Formation, and Stability
Composition control in perovskites involves balancing bandgap, phase stability, crystallization behavior, defect density, and environmental risks.
Control position | Common direction | Main objective | Issues requiring attention |
A site | Methylammonium, formamidinium, cesium, and mixed cations | Adjust lattice stability, phase stability, and crystallization process | Single-component systems may face thermal-stability, phase-stability, or film-formation issues |
B site | Lead, tin, and mixed lead–tin systems | Tune bandgap, light absorption, and charge transport | Lead involves environmental risks; in tin-based systems, Sn²⁺ is easily oxidized to Sn⁴⁺, so tin vacancies, defects, and leakage current need attention |
X site | Iodide, bromide, chloride, and mixed halides | Adjust absorption range and bandgap | Mixed-halide systems require attention to light-induced phase separation and stability |
Dimensional structure | Three-dimensional, two-dimensional, quasi-two-dimensional, and two-dimensional/three-dimensional interfaces | Adjust surface stability, interfacial recombination, and tolerance to moisture and oxygen | Excessive insulating organic layers may hinder charge transport |
In experiments, whether the composition is reasonable should first be judged by asking three questions:
Question | Key point for judgment |
Does the bandgap match the target device? | Single-junction cells, wide-bandgap top cells in tandems, and low-bandgap bottom cells in tandems have different requirements |
Can the film readily form the target phase? | Phase purity, crystallization integrity, and surface coverage should be confirmed first |
Is the main stability weakness clear? | Identify whether moisture/oxygen, heat, light, bias, or interfacial reactions are the most prominent issue |
4. From Precursors to the Absorber Layer: How Film Quality Affects Efficiency and Reproducibility
Perovskite solar cells are usually not made from bulk crystals. Instead, thin films are formed from precursor salts, solvents, and deposition processes. The U.S. Department of Energy’s description of the fabrication process includes mixing precursor salts, depositing an ultrathin perovskite layer, heating to form the film, and then depositing other functional layers.
Experimental step | Main influence | Priority observations |
Precursor ratio | Target phase formation, residual salt content, defect level, and crystallization pathway | Whether the solution is clear and whether the ratio is reproducible |
Solvent system | Solubility, evaporation rate, formation of coordination intermediates, and crystallization rate | Whether the wet film is uniform and whether premature crystallization occurs |
Deposition method | Film thickness, coverage, surface uniformity, and local defects | Whether pinholes, streaks, or edge accumulation appear |
Annealing conditions | Phase transformation, grain growth, removal of residual solvent, and film compactness | Whether the film color is uniform and whether the crystal phase is stable |
Substrate cleaning | Interfacial wetting, film continuity, and contact quality with the underlying layer | Whether dewetting, shrinkage holes, or local non-film-forming regions appear |
Environmental humidity | Crystallization process, water participation in reactions, defect formation, and subsequent degradation risk | Whether the same formulation shows clear differences under different humidity conditions |
Common characterization methods and the specific questions they address:
Question to confirm | Applicable method |
Whether the target crystal phase has formed | X-ray diffraction |
Whether the absorption range matches the design | Ultraviolet–visible absorption spectroscopy |
Whether defect-related recombination is serious | Photoluminescence and time-resolved photoluminescence |
Whether the film provides continuous coverage | Optical microscopy and scanning electron microscopy |
Whether the surface is excessively rough | Atomic force microscopy |
Whether the elemental distribution deviates from the design | Surface-composition and depth-profile composition analysis |
When device efficiency is low, the first step should not be to directly replace the transport layer or additives. Instead, one should confirm whether the perovskite layer has formed the correct phase, provides continuous coverage, has few pinholes, and contains a controllable amount of residual phases.
5. From the Absorber Layer to the Complete Device: How Structural Design Affects Charge Collection and Efficiency
The main role of the perovskite absorber layer is to absorb light and generate electrons and holes. To produce an effective current, these electrons and holes must not recombine inside the absorber layer or at interfaces; instead, they need to be directed toward different electrodes. The electron transport layer receives and transports electrons while suppressing holes from entering the electron side. The hole transport layer receives and transports holes while suppressing electrons from entering the hole side. The metal electrode and transparent conductive substrate then connect these charges to the external circuit.
Therefore, the efficiency of a perovskite solar cell depends not only on the absorber layer itself, but also on whether the energy levels of the transport layers are well matched, whether the interfacial contact is good, whether charge extraction is smooth, and whether the electrode is stable.
Device layer | Main function | Common issues |
Transparent conductive substrate | Transmits light and collects charge | Surface contamination, roughness, and non-uniform conductivity |
Electron transport layer | Selectively extracts electrons and suppresses reverse recombination | Energy-level mismatch, transport resistance, and interfacial defects |
Perovskite absorber layer | Absorbs light and generates electrons and holes | Pinholes, residual phases, ion migration, and defect recombination |
Hole transport layer | Selectively extracts holes | Moisture absorption by dopants, insufficient thermal stability, and interfacial reactions |
Metal electrode | Collects current and completes the external circuit connection | Metal diffusion, halide reactions, and contact degradation |
6. How Performance Data Correspond to Experimental Problems
For perovskite solar cells, the highest efficiency alone is not enough. Open-circuit voltage, short-circuit current density, fill factor, hysteresis, steady-state output, and external quantum efficiency each correspond to different problems.
Experimental observation | Priority check | Common cause direction |
Low open-circuit voltage | Defect recombination and interfacial recombination | Surface defects, grain-boundary defects, energy-level mismatch, and transport-layer interfacial losses |
Low short-circuit current density | Light absorption and charge extraction | Insufficient film thickness, mismatched absorption range, pinholes, and transport-layer blocking |
Low fill factor | Resistance and interfacial contact | High series resistance, leakage current, poor interfacial contact, and insufficient transport-layer conductivity |
Clear difference between forward and reverse scans | Hysteresis and ion migration | Ion migration, interfacial charge accumulation, and differences in test preconditioning |
Steady-state output lower than scan efficiency | Instability at the actual operating point | Ion redistribution, interfacial charge accumulation, and light-induced degradation |
Large batch-to-batch variation | Film formation and interfacial reproducibility | Solution aging, humidity fluctuation, substrate cleaning, and annealing deviations |
Reliable data should include at least the following:
1. Forward and reverse scan results;
2. Steady-state power output;
3. External quantum efficiency and integrated current cross-check;
4. Statistical results from multiple devices;
5. Clear test conditions and device area;
6. Stability test conditions and retention rate.
7. Stability Bottlenecks: How Materials, Interfaces, and Encapsulation Jointly Affect Device Lifetime
The stability problem of metal halide perovskite solar cells cannot be attributed solely to moisture sensitivity. During operation and storage, real devices are simultaneously affected by moisture, oxygen, heat, light, and operating bias. The perovskite absorber layer itself may undergo phase transitions, decomposition, or ion migration; the interface between the transport layer and perovskite may suffer intensified recombination or chemical reactions; the metal electrode may also diffuse and, together with halide migration, trigger interfacial degradation. If encapsulation cannot effectively block moisture and oxygen ingress, external environmental stress will continuously amplify these failure processes.
Therefore, the stability of perovskite devices is not a single-material problem. It is a comprehensive reliability issue involving the absorber layer, transport layers, electrodes, and encapsulation under the combined effects of light, heat, moisture/oxygen, and electric field. Before commercialization, the key challenges to address are precisely efficiency retention under long-term operating conditions, interfacial stability, and encapsulation reliability.
Failure source | Possible result | Experimental manifestation |
Moisture | Hydration, decomposition, or phase changes of the absorber layer | Film color change, decreased absorption, and rapid efficiency loss |
Oxygen | Defect changes or oxidation processes jointly induced with light | Accelerated degradation under illumination in air |
Thermal stress | Phase transitions, ion diffusion, and interfacial reactions | Decreased voltage and fill factor after high-temperature exposure |
Light | Light-induced defect changes or ion migration; in mixed-halide systems, possible halide phase separation | Output fluctuation under continuous illumination |
Voltage bias | Ion accumulation at interfaces, altering the built-in electric field | Enhanced hysteresis and decreased steady-state output |
Electrode reactions | Metal diffusion, halide corrosion, and contact degradation | Increased series resistance and irreversible efficiency loss |
Insufficient encapsulation | Continuous ingress of external moisture and oxygen into the device | Large differences between storage stability and operational stability |
Stability improvement needs to consider the following directions simultaneously:
Control direction | Target effect |
Composition design | Improve phase stability and reduce the proportion of easily decomposable components |
Crystallization control | Reduce defect density and the number of pinholes |
Surface passivation | Reduce non-radiative recombination and surface reaction sites |
Interface modification | Improve energy-level matching and interfacial chemical stability |
Transport-layer replacement | Reduce risks related to moisture absorption, diffusion, and thermal failure |
Electrode and encapsulation | Reduce metal diffusion, moisture/oxygen ingress, and edge failure |
8. From Small-Area Devices to Modules: Which Performance and Process Issues Are Amplified?
Small-area perovskite devices are usually fabricated under controlled conditions. Because the film area is small, the defect area is limited, and the current transport path is short, high efficiency can be achieved more readily. After scaling up to modules, the absorber layer, transport layers, and electrodes must remain uniform over a larger area. Multiple sub-cells also need to be connected in series through scribing and interconnection. At this stage, local pinholes, film-thickness fluctuations, non-uniform interfacial contact, scribing damage, moisture/oxygen ingress from encapsulation edges, and current mismatch between sub-cells can all be amplified into module efficiency loss or long-term degradation.
Therefore, module scale-up is not simply making small-area devices larger. It simultaneously tests large-area film formation, interlayer interfaces, series interconnection, encapsulation reliability, and long-term validation. The U.S. Department of Energy has also pointed out that small-area perovskite devices have already shown competitive efficiencies, but the stable fabrication of high-efficiency devices over large areas remains challenging; large-scale manufacturing requires reproducible preparation of uniform, high-performance perovskite materials under manufacturing environments.
Focus for small-area devices | Additional issue after scale-up |
Highest efficiency of a single device | Average efficiency and uniformity over a large area |
Spin coating or small-area coating | Scalable processes such as slot-die coating, blade coating, spray coating, and evaporation |
Single-point current–voltage testing | Module series losses and area-normalized efficiency |
Small-cell encapsulation | Edge sealing, interlayer adhesion, and long-term moisture protection |
Short-term laboratory stability | Outdoor illumination, temperature cycling, damp heat, and bias acting together |
Single-batch results | Multi-batch reproducibility and third-party validation |
9. In What Order Should a New Perovskite System Be Evaluated Experimentally?
For a new metal halide perovskite system, the evaluation sequence should not begin with the highest single-device efficiency. Instead, the material target should first be confirmed, followed by stepwise examination of the film, interfaces, device performance, and stability. This helps avoid misjudging a film-formation problem as a transport-layer problem, and also avoids discussing scale-up too early before the results are stable.
Step | Question to answer first | Key checks |
1 | Are the target device and bandgap requirement clear? | Single-junction cell, top cell in a tandem, bottom cell in a tandem, or reference device; whether the target absorption range and bandgap are clear |
2 | Does the material composition match the target performance? | Whether the A site, B site, and X site match the target bandgap, phase stability, and film-formation requirements |
3 | Does the film form the target crystal phase? | Crystal phase, absorption spectrum, film coverage, residual phases, and phase stability |
4 | Does the film quality meet the requirements for device fabrication? | Film-thickness uniformity, pinholes, streaks, grain state, surface roughness, and substrate wetting |
5 | Have recombination and defects become the main loss source? | Photoluminescence, time-resolved photoluminescence, grain-boundary defects, surface defects, and interfacial recombination |
6 | Are the transport layers and interfaces well matched? | Energy-level matching, charge selectivity, interfacial contact, wettability, and chemical stability |
7 | Where do the main device performance losses come from? | Open-circuit voltage, short-circuit current density, fill factor, hysteresis, and steady-state power output |
8 | Where is the main stability weakness? | Moisture/oxygen, heat, light, bias, ion migration, electrode reactions, and encapsulation reliability |
9 | Are the results reproducible? | Multi-device statistics, external quantum efficiency, current cross-check, steady-state output, and consistency of test conditions |
10 | Is there a basis for scale-up validation? | Large-area film uniformity, process window, module interconnection, encapsulation edges, and long-term operational stability |
10. Product Selection Navigation for Metal Halide Perovskite Solar Cell–Related Products(Product Tables 1–6)
Research or experimental goal | Recommended table to consult first | Why consult this table first | Suggested related table(s) | Navigation notes |
Build perovskite precursor solutions and film-forming conditions | Table 1 | Table 1 focuses on main precursor solvents, coordinating solvents, and antisolvents, making it suitable for first establishing the basic conditions for dissolution, coordination, evaporation, and crystallization control | Tables 2 and 3 | First determine the solvent system, then combine A-site cations, lead halide salts, or tin halide salts to build the absorber-layer formulation |
Compare how different film-formation routes affect thin-film morphology | Table 1 | Film uniformity, pinholes, grain formation, and intermediate-phase formation are closely related to the solvent system | Table 4 | If film coverage is uneven or the grain state is unsatisfactory, Table 4 can be consulted to examine crystallization modifiers and surface passivation materials |
Design mixed-cation systems involving methylammonium, formamidinium, and cesium | Table 2 | Table 2 lists methylammonium salts, formamidinium salts, and cesium salts, which can be used to regulate the lattice, phase stability, and crystallization behavior | Tables 3 and 4 | First determine the A-site composition, then combine it with the ratios of lead halides or tin halides; passivation materials can subsequently be used to reduce surface recombination |
Adjust the iodide/bromide ratio to design absorber layers with different bandgaps | Table 2 | Table 2 provides A-site precursors as iodide and bromide sources, suitable for designing iodide-based, bromide-based, and mixed iodide–bromide systems | Tables 3 and 6 | If the target is a wide-bandgap or all-inorganic system, Table 3 can be used to select lead halides, while Table 6 can be used to establish material references |
Construct lead-based perovskite absorber layers | Table 3 | Table 3 focuses on lead iodide, lead bromide, and lead chloride, which are core metal halide sources for forming lead-based absorber layers | Tables 2 and 1 | Select the lead halide according to the target bandgap, then combine it with A-site salts and the solvent system to define the first-round film-forming conditions |
Study tin-based or mixed lead–tin low-bandgap perovskites | Table 3 | Table 3 includes tin halides and tin fluoride, which can be used for tin-based systems, low-bandgap absorber layers, and studies on controlling tin oxidation | Tables 2 and 4 | Tin-based systems require simultaneous attention to precursor purity, tin oxidation, defect passivation, and the crystallization process |
Address thin-film surface defects, grain-boundary recombination, and interfacial stability issues | Table 4 | Table 4 focuses on two-dimensional/quasi-two-dimensional interface modifiers, small-cation passivation salts, and crystallization modifiers | Tables 5 and 6 | When the open-circuit voltage is low, hysteresis is obvious, or stability is insufficient, surface treatment and interface-modification strategies can first be screened from Table 4 |
Construct two-dimensional/three-dimensional interfaces or surface protective layers | Table 4 | Materials such as phenethylammonium salts and butylammonium salts can be used for surface two-dimensionalization, grain-boundary passivation, and studies on moisture/oxygen tolerance | Tables 2 and 3 | Suitable for improving surface recombination and interfacial stability after the formulation of the three-dimensional absorber layer has been determined |
Select electron transport layers, hole transport layers, and interfacial buffer layers | Table 5 | Table 5 covers electron-transport materials, hole-transport materials, interfacial layers, and doping additives, making it suitable for building complete device structures | Tables 1 and 4 | After absorber-layer film formation has been determined, screening should consider transport-layer energy levels, wettability, interfacial reactions, and hysteresis behavior |
Troubleshoot low open-circuit voltage, poor fill factor, or obvious hysteresis | Table 5 | These problems are often related to transport-layer selection, interfacial recombination, charge extraction, and dopant systems | Table 4 | If recombination losses remain after adjusting the transport layer, Table 4 should be consulted to examine surface defects and interfacial passivation |
Establish representative perovskite material references or validate single-source precursor routes | Table 6 | Table 6 lists representative preformed perovskite absorber materials and metal electrode materials, making it convenient for material comparison and device-structure validation | Tables 5 and 1 | It can be used to compare methylammonium-, formamidinium-, and cesium-based absorber materials in terms of film formation, bandgap, and device stability |
Compare the effects of silver and gold electrodes on device degradation | Table 6 | Table 6 includes commonly used metal electrode materials, which can be used to study electrode contact, halide migration, and interfacial reactions | Tables 5 and 4 | Electrode stability evaluation should also consider the transport layer, interfacial layer, and perovskite surface treatment |
Study all-inorganic cesium lead halide perovskite systems | Table 6 | Table 6 includes representative cesium lead iodide and cesium lead bromide materials, suitable for studies on all-inorganic absorber layers and thermal stability | Tables 2 and 3 | If an all-inorganic system needs to be prepared from precursor routes, Tables 2 and 3 can be used to select cesium salts and lead halides |
Establish a complete first-round screening route from solution preparation to device fabrication | Table 1 | Table 1 determines the precursor solution and crystallization basis, which is the starting point for whether the first round of experiments can form a usable film | Tables 2, 3, and 5 | Devices can be built stepwise in the order of “solvent system—A-site and halide composition—metal halides—transport layers—electrodes” |
Analyze whether stability degradation originates from the absorber layer, interface, or electrode | Table 4 | Table 4 corresponds to surface defects, two-dimensional interfaces, and grain-boundary passivation, making it an important entry point for stability diagnosis | Tables 5 and 6 | If degradation is accompanied by interfacial recombination, hysteresis, or electrode reactions, transport-layer and electrode materials should be evaluated together |
Table 1 | Precursor Solution Preparation, Film Formation, and Antisolvent Systems
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Main precursor solvent | 68-12-2 | N,N-Dimethylformamide (DMF) | Anhydrous, ≥99.8% | Commonly used for dissolving lead halides, methylammonium salts, and formamidinium salts; can be combined with dimethyl sulfoxide to regulate coordination intermediates and the film-forming process | |
Antisolvent and organic-layer solvent | 108-90-7 | C431386 | Chlorobenzene | Anhydrous, ≥99.8% | Commonly used for antisolvent treatment during spin coating and for preparing some organic transport layers; helps control rapid nucleation and surface morphology of perovskite films |
Coordinating precursor solvent | 872-50-4 | 1-Methyl-2-pyrrolidinone (NMP) | Anhydrous, ≥99.5% | A high-boiling polar solvent that can be used for slow crystallization, coating-based film formation, and precursor solvent-system screening | |
Coordinating precursor solvent | 67-68-5 | D119415 | Dimethyl sulfoxide (DMSO) | Spectroscopic grade, ≥99.9% (GC) | Can form coordination intermediates with lead halides and slow crystallization; commonly used to improve the uniformity and coverage of perovskite films |
Antisolvent and organic-layer solvent | 108-88-3 | T399681 | Toluene | Semiconductor grade, ≥99% | Can be used for antisolvent treatment in some perovskite film-forming processes or for preparing organic functional layers; suitable for comparing how antisolvent evaporation rate affects film morphology |
Main precursor solvent | 96-48-0 | H1520798 | γ-Butyrolactone | PrimorTrace™, electronic grade | Can be used in high-concentration precursor solutions and slow-crystallization systems; suitable for coating processes, solvent-ratio optimization, and crystallization-kinetics studies |
Table 2 | Precursors for A-Site Cation and Halide Composition Control
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
A-site organic cation and bromide source | 6876-37-5 | Methylammonium bromide (MABr) | Anhydrous, ≥99% | Provides methylammonium and bromide components; can be used for methylammonium lead bromide systems, mixed iodide–bromide systems, and wide-bandgap perovskite composition control | |
A-site organic cation and bromide source | 146958-06-7 | Formamidinium bromide | Anhydrous, ≥99% | Provides formamidinium and bromide components; can be used for formamidinium lead bromide systems, mixed-cation systems, and wide-bandgap absorber-layer formulations for tandem cells | |
A-site inorganic cation and iodide source | 7789-17-5 | Cesium iodide | PrimorTrace™, ≥99.99% metals basis, shot | Provides cesium and iodide components; can be used for mixed-cation perovskites, all-inorganic cesium lead iodide systems, and phase-stability control studies | |
A-site inorganic cation and bromide source | 7787-69-1 | Cesium bromide | PrimorTrace™, ultra-dry grade, ≥99.99% metals basis | Provides cesium and bromide components; can be used for cesium lead bromide systems, mixed-halide systems, and wide-bandgap perovskite material design | |
A-site organic cation and iodide source | 14965-49-2 | Methylammonium iodide (MAI) | PrimorTrace™, ≥99.99% metals basis | A classic methylammonium iodide source; can be used for methylammonium lead iodide absorber layers, mixed-cation systems, and reference device formulations | |
A-site organic cation and iodide source | 879643-71-7 | Formamidinium iodide (FAI) | ≥99.5% (4 Times Purification) | A core precursor for formamidinium lead iodide systems; can be used for high-efficiency iodide-based perovskite absorber layers and mixed-cation phase-stability studies |
Table 3 | B-Site Metal Halides, Tin-Based Components, and Lead–Tin System Precursors
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Lead-based B-site metal and iodide source | 10101-63-0 | Lead iodide | PrimorTrace™, ultra-dry grade, ≥99.999% metals basis | A core precursor for lead-based iodide absorber layers; can be used to prepare methylammonium lead iodide, formamidinium lead iodide, and mixed-cation perovskite films by one-step or two-step methods | |
Tin-based B-site metal and iodide source | 10294-70-9 | Tin iodide | PrimorTrace™, ultra-dry grade, ≥99.99% metals basis | A precursor for tin-based and mixed lead–tin perovskites; can be used for low-bandgap absorber layers, lead-free or low-lead systems, and studies on tin oxidation stability | |
Lead-based B-site metal and chloride source | 7758-95-4 | Lead chloride | PrimorTrace™, ultra-dry grade, ≥99.99% metals basis | Can be used in chloride-containing precursor systems and crystallization-control studies; helps compare the influence of chloride sources on grain growth, film uniformity, and interfacial properties | |
Lead-based B-site metal and bromide source | 10031-22-8 | Lead bromide | PrimorTrace™, ≥99.999% metals basis | A core precursor for lead bromide perovskites and mixed iodide–bromide perovskites; can be used for wide-bandgap absorber layers, tandem top-cell materials, and phase-separation studies | |
Tin-based stabilizing additive | 7783-47-3 | Tin(II) Fluoride | ≥99% | Commonly used in tin-based perovskite systems to regulate tin vacancies and tin oxidation; helps reduce defects and leakage risks in tin-based absorber layers | |
Tin-based B-site metal and bromide source | 10031-24-0 | Tin(II) bromide | ≥99% | Can be used for tin-based bromide or mixed lead–tin halide perovskite research; suitable for comparing how tin sources and bromide components affect bandgap, crystallization, and stability |
Table 4 | Two-Dimensional/Quasi-Two-Dimensional Interface Modifiers, Defect Passivation, and Crystallization-Control Materials
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Small-cation defect-passivation salt | 19227-70-4 | Guanidinium iodide | Anhydrous, ≥99% | Can be used in mixed-cation systems, surface defect passivation, and lattice-environment regulation; suitable for studying the influence of small cations on film formation, recombination, and stability | |
Crystallization-control additive | 1762-95-4 | Ammonium thiocyanate | PrimorTrace™, ≥99.99% metals basis | Can be used to regulate the crystallization process, grain growth, and defect state of perovskite precursors; suitable for film-forming process and additive screening studies | |
Two-dimensional/quasi-two-dimensional interface modifier | 53916-94-2 | Phenethylammonium bromide | ≥99.5% (4 times recrystallized) | A bulky organic ammonium bromide salt that can be used to construct surface two-dimensional perovskite layers, passivate interfacial defects, and regulate the surface properties of wide-bandgap perovskites | |
Two-dimensional/quasi-two-dimensional interface modifier | 151059-43-7 | Phenylethylammonium Iodide | ≥99.5% (4 Times Purification) | Commonly used for two-dimensional/three-dimensional interface passivation and surface protection; can reduce surface recombination and improve the tolerance of perovskite films to moisture and oxygen | |
Two-dimensional/quasi-two-dimensional interface modifier | 36945-08-1 | Butylammonium Iodide (BAI) | ≥99% (4 Times Purification) | A linear alkylammonium iodide salt that can be used for surface two-dimensionalization, grain-boundary passivation, and damp-heat stability studies; excessive dosage may increase charge-transport resistance |
Table 5 | Electron Transport Layers, Hole Transport Layers, Interfacial Layers, and Doping Additives
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Electron-transport/hole-blocking interfacial material | 4733-39-5 | 2,9-Dimethyl-4,7-diphenyl-1,10-phenanthroline (BCP) | Sublimed grade, ≥99.8% metals basis | Commonly used as an interfacial buffer between fullerene layers and metal electrodes; improves electron collection and reduces reverse hole transport and interfacial recombination | |
Electron transport layer material | 13463-67-7 | Nano Titanium oxide | Electronic grade, ≥99.8% metals basis, 300–700 nm | A classic electron transport material for n-i-p perovskite devices; suitable for studying electron extraction, interfacial treatment, and ultraviolet-light stability | |
Electron transport layer material | 18282-10-5 | Tin oxide | PrimorTrace™, ≥99.99% metals basis, 50–70 nm | A low-temperature electron transport layer material for n-i-p devices and flexible-substrate processes; commonly used to improve electron extraction and interfacial energy-level matching | |
Hole transport layer material | 1313-99-1 | Nickel oxide | PrimorTrace™, ≥99.99% metals basis | An inorganic hole transport material for p-i-n devices; suitable for improving thermal stability and studying the perovskite/hole-transport-layer interface | |
Hole transport layer material | 155090-83-8 | Poly(3,4-ethylenedioxythiophene)-poly(styrenesulfonate) (PEDOT:PSS) | PEDOT:PSS = 1:6, 1.5% in water | Commonly used as a low-temperature hole transport layer in p-i-n structures; can be used to study interfacial wetting, film-formation compatibility, and device hysteresis | |
Hole transport layer material | 1333317-99-9 | Poly[bis(4-phenyl)(2,4,6-trimethylphenyl)amine] | Mw = 15000–25000 | A hydrophobic polymeric hole transport material that can be used in high-efficiency p-i-n or n-i-p devices; suitable for studying interfacial energy levels, film uniformity, and stability | |
Hole transport layer dopant additive | 90076-65-6 | Bis(trifluoromethane)sulfonimide lithium salt (LiTFSI) | ≥99.9% | Commonly used to dope organic hole transport layers and improve hole transport capability; in stability studies, moisture absorption, ion migration, and interfacial effects should be considered | |
Hole transport layer material | 207739-72-8 | Spiro-MeOTAD | ≥99.9% | A classic organic hole transport material commonly used in n-i-p perovskite solar cells; can be combined with lithium salts and pyridine-type additives to regulate transport performance | |
Electron transport layer material | 160848-22-6 | [6,6]-Phenyl C 61 methyl butyrate | ≥99.5% | A fullerene-derivative electron transport material commonly used in p-i-n devices; can improve electron extraction and passivate some surface defects of perovskites | |
Hole transport layer auxiliary additive | 3978-81-2 | 4-tert-Butylpyridine | ≥98% | Commonly used together with Spiro-MeOTAD systems to regulate the film formation and doping environment of the hole transport layer; its long-term influence on the perovskite interface should also be considered |
Table 6 | Metal Electrodes, Representative Perovskite Materials, and Single-Source Precursors
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Metal electrode material | 7440-22-4 | Silver | PrimorTrace™, ≥99.99% metals basis, powder, <250 μm | A commonly used metal-electrode-related material; can be used for studying silver-electrode stability, metal diffusion, and halide reactions; specific preparation should match evaporation, sputtering, printing, or paste-based processes | |
Metal electrode material | 7440-57-5 | Gold | ≥99.99% metals basis, powder, <850 μm, ≥99.99% trace metals basis | A commonly used metal-electrode-related material; can be used as a gold-electrode material reference and for studying contact stability, metal diffusion, and interfacial reactions; specific electrode preparation should match evaporation, sputtering, printing, or paste-based processes and confirm compatibility between material form and process | |
Representative iodide-based perovskite absorber material | 69507-98-8 | Methylammonium lead iodide | ≥99% | A classic iodide-based perovskite absorber material; can be used for reference devices, structure–property relationship studies, and thin-film stability comparisons | |
Representative bromide-based perovskite absorber material | 1008105-17-6 | Formamidinium Lead Bromide | ≥99% | A formamidinium lead bromide perovskite material; can be used for wide-bandgap absorber layers, bromide-based perovskite film formation, and mixed-halide system comparisons | |
Representative iodide-based perovskite absorber material | 1451592-07-6 | Formamidinium Lead Iodide | ≥99% | A formamidinium lead iodide perovskite material; can be used for high-efficiency iodide-based absorber layers, phase stability studies, and mixed-cation system research | |
Representative bromide-based perovskite absorber material | 69276-13-7 | Methylammonium tribromoplumbate | ≥99% | A methylammonium lead bromide perovskite material; can be used for wide-bandgap absorber layers, bromide-based perovskite devices, and bandgap-control references | |
Representative all-inorganic bromide-based perovskite absorber material | 15243-48-8 | Cesium Lead Tribromide | ≥98% | An all-inorganic cesium lead bromide perovskite material; can be used for wide-bandgap devices, all-inorganic systems, and thermal-stability studies | |
Representative all-inorganic iodide-based perovskite absorber material | 18041-25-3 | Cesium Lead Triiodide | ≥98% | An all-inorganic cesium lead iodide perovskite material; can be used for all-inorganic absorber layers, black-phase stabilization, and device thermal-stability studies |
Note: The above are representative Aladdin products. For more product specifications, search by “product name/CAS/catalog number” on the Aladdin official website.
References
[1] Kojima A., Teshima K., Shirai Y., Miyasaka T. Organometal Halide Perovskites as Visible-Light Sensitizers for Photovoltaic Cells. Journal of the American Chemical Society, 2009, 131: 6050–6051.
[2] U.S. Department of Energy. Perovskite Solar Cells.
[3] U.S. Department of Energy. Perovskite Research Directions.
[4] Khenkin M. V., Katz E. A., Abate A., et al. Consensus statement for stability assessment and reporting for perovskite photovoltaics based on ISOS procedures. Nature Energy, 2020, 5: 35–49.
[5] Boyd C. C., Cheacharoen R., Leijtens T., McGehee M. D. Understanding Degradation Mechanisms and Improving Stability of Perovskite Photovoltaics. Chemical Reviews, 2019, 119: 3418–3451.
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