Perovskite Oxides for Energy and Environmental Catalysis: How Oxygen Vacancies, B-Site Metals, and the Metal–Oxygen Bond Network Regulate Reaction Performance
Perovskite Oxides for Energy and Environmental Catalysis: How Oxygen Vacancies, B-Site Metals, and the Metal–Oxygen Bond Network Regulate Reaction Performance
Introduction
Perovskite oxides are not only used in electronic ceramics, but can also serve as catalytic materials in energy- and environment-related reactions. This article mainly discusses transition-metal-containing oxide perovskites, with a focus on their catalytic behavior in thermal catalysis, electrocatalysis, and solid oxide fuel cell electrodes.
Typical perovskite oxides can be written as ABO₃ or ABO₃₋δ. In this structure, the A site is usually occupied by rare-earth or alkaline-earth metal ions, while the B site is usually occupied by transition-metal ions such as manganese, iron, cobalt, and nickel. Oxygen ions form the metal–oxygen octahedral framework. Catalytic activity is not determined by one element alone; instead, reactant adsorption, oxygen activation, electron transfer, and oxygen migration are jointly influenced by the A site, B site, oxygen site, oxygen vacancies, lattice oxygen, and surface oxygen species.
Perovskite oxides have attracted attention in the oxygen evolution reaction, oxygen reduction reaction, volatile organic compound oxidation, carbon monoxide oxidation, methane oxidation, and solid oxide fuel cell cathodes. This is because their composition is tunable, they contain abundant transition-metal sites, their oxygen non-stoichiometry can be adjusted, and their catalytic performance can be modified through doping, defect regulation, and surface engineering.
1. Basic Structure of Perovskite Oxides Used in Catalysis
Perovskite oxides used in catalysis can be understood from four levels: the A site, B site, oxygen site, and surface.
Structural position | Main role | Influence on catalytic performance |
A site | Regulates lattice size, structural stability, and charge balance | Affects oxygen vacancy formation, oxygen migration, thermal stability, and the tendency toward surface segregation |
B site | Provides transition-metal redox centers | Affects oxygen adsorption, electron transfer, metal valence cycling, and the binding strength of reaction intermediates |
Oxygen site | Forms the metal–oxygen framework and lattice oxygen network | Affects oxygen vacancy formation, lattice oxygen migration, and the ability of oxygen to participate in reactions |
Surface | Directly contacts reactants | Determines reactant adsorption, oxygen activation, product desorption, and surface reconstruction behavior |
Common research systems include:
Material direction | Representative systems | Suitable research focus |
Lanthanum manganite systems | LaMnO₃, La₁₋ₓSrₓMnO₃ | Oxygen migration, volatile organic compound oxidation, solid oxide fuel cell cathodes |
Lanthanum ferrite systems | LaFeO₃, La₁₋ₓSrₓFeO₃ | Oxygen vacancy regulation, structural stability, oxidation reactions, and electrode reactions |
Lanthanum cobaltite systems | LaCoO₃, La₁₋ₓSrₓCoO₃ | Oxygen reduction, oxygen evolution reaction, low-temperature oxygen exchange, and oxidation activity |
Lanthanum nickelate systems | LaNiO₃ and doped nickel-based perovskite oxides | B-site electronic structure, redox activity, and oxygen electrocatalysis |
Cobalt–iron composite systems | La₁₋ₓSrₓCo₁₋ᵧFeᵧO₃₋δ, Ba₁₋ₓSrₓCo₁₋ᵧFeᵧO₃₋δ | Oxygen surface exchange, oxygen-ion migration, and solid oxide cell cathode reactions |
It should be noted that many perovskite oxides do not necessarily operate directly through their initial surface during reaction. Especially under electrocatalytic conditions such as the oxygen evolution reaction, the surface may undergo reconstruction and form new oxide, hydroxide, or oxyhydroxide active layers. Therefore, in some cases, perovskite oxides can be regarded both as catalysts and as precursors to the active surface formed during reaction.
2. How the A Site, B Site, and Oxygen Site Jointly Affect Catalytic Performance
The catalytic performance of perovskite oxides arises from the synergistic regulation of “composition–defects–surface structure.”
Regulation method | Main influence | Points requiring attention |
A-site substitution | Changes ionic radius, charge balance, lattice distortion, and the tendency toward oxygen vacancy formation | Excessive doping may lead to secondary phases, A-site segregation, or thermal expansion mismatch |
B-site substitution | Changes transition-metal valence state, metal–oxygen bond strength, and electronic structure | Improved activity may be accompanied by decreased stability or metal dissolution |
A-site deficiency | Increases the demand for charge compensation and may increase oxygen vacancy concentration | Excessive deficiency may damage phase stability and long-term durability |
B-site compositing | Introduces two or more transition metals to tune oxygen binding strength and reaction pathways | It is necessary to confirm whether a homogeneous solid solution or locally enriched phases are formed |
Oxygen non-stoichiometry | Forms oxygen vacancies or oxygen-excess states, regulating oxygen migration and conductivity | Excessive oxygen vacancies may lead to lattice instability or restricted oxygen migration |
Surface regulation | Changes surface oxygen species, defect concentration, and accessible active sites | Surface modification layers must balance activity, mass transport, and stability |
The A site usually does not act directly as the main reaction active center, but it can influence B-site metal valence states and oxygen vacancy formation through lattice size, charge balance, and local structure. B-site transition metals are usually the core of activity regulation because they directly participate in electron transfer, valence cycling, and reaction intermediate adsorption. The oxygen site determines whether lattice oxygen can readily migrate, be replenished, and participate in surface reactions.
Therefore, perovskite oxide catalysts should not be judged simply by saying that “a certain element is highly active.” A more reasonable approach is to examine whether the B-site metal has suitable redox capability, whether the metal–oxygen bond strength is appropriate, whether oxygen vacancies can reversibly participate in oxygen exchange, and whether the surface structure can still maintain an effective catalytic state after reaction.
3. Oxygen Vacancy Regulation: The Key Lies in Reversible Oxygen Exchange Capacity
Oxygen vacancies are defect sites formed by the absence of oxygen ions in the perovskite oxide lattice. For energy and environmental catalytic reactions, the significance of oxygen vacancies is not limited to providing defect sites; they also influence oxygen adsorption, oxygen activation, lattice oxygen migration, metal valence regulation, and surface oxygen replenishment.
In volatile organic compound oxidation, carbon monoxide oxidation, methane oxidation, the oxygen evolution reaction, the oxygen reduction reaction, and solid oxide fuel cell cathode reactions, oxygen vacancies often significantly affect oxygen adsorption, oxygen activation, lattice oxygen migration, and oxygen replenishment. However, the specific activity is also influenced by B-site electronic structure, metal–oxygen bond strength, surface reconstruction, and stability. Oxygen vacancies are a key factor connecting “structural defects” with “catalytic activity.”
Role of oxygen vacancies | Significance for catalytic reactions |
Provide sites for oxygen adsorption and activation | Helps oxygen molecules, hydroxyl groups, or oxygen-containing intermediates approach surface active centers |
Promote the formation of surface active oxygen | Helps form active oxygen species that participate in oxidation reactions or electrode reactions |
Enhance lattice oxygen migration | Facilitates the replenishment of surface oxygen by bulk lattice oxygen and maintains the oxidation cycle |
Regulate B-site metal valence states | Affects the redox states of transition metals such as manganese, iron, cobalt, and nickel through charge compensation |
Influence reaction pathways | Can change the way adsorbed oxygen, surface oxygen, and lattice oxygen participate in the reaction |
More oxygen vacancies are not necessarily better. When oxygen vacancies are insufficient, oxygen adsorption and oxygen migration are limited. At a moderate level, they help balance oxygen exchange and structural stability. When excessive, they may weaken lattice stability, reduce oxygen migration efficiency, and lead to irreversible structural changes or secondary phase formation. Therefore, evaluation of oxygen vacancies should focus on their reversible formation, migration, and replenishment capacity, rather than simply pursuing stronger defect signals.
Oxygen vacancy state | Catalytic behavior | Key concerns |
Insufficient oxygen vacancies | Limited oxygen adsorption, oxygen activation, and lattice oxygen replenishment capacity | Low activity, difficulty initiating low-temperature reactions, slow oxygen exchange rate |
Moderate oxygen vacancies | Oxygen adsorption, oxygen migration, electron transfer, and structural stability are relatively balanced | Suitable for further optimization around composition, surface structure, and reaction conditions |
Excessive oxygen vacancies | Lattice stability decreases, and structural recovery after reaction becomes poor | Possible phase transformation, component segregation, abnormal conductivity, or activity decay |
Therefore, the focus of oxygen vacancy regulation is not simply to increase the number of defects, but to enable oxygen vacancies to be reversibly generated, migrated, replenished, and involved in the catalytic cycle during reaction. In experimental judgment, oxygen defect characterization, metal valence changes, crystal phase before and after reaction, and stability data should be considered together, so that catalytic performance is not judged only from a single oxygen vacancy signal.
4. Why B-Site Transition Metals Are Often the Core of Activity Regulation
B-site transition metals are an important source of catalytic performance in perovskite oxides. Metals such as manganese, iron, cobalt, and nickel have variable valence states, can participate in electron transfer during reaction, and influence the binding strength between oxygen species and the surface.
B-site factor | Influence on catalytic performance |
Metal valence state | Determines redox cycling capability and charge compensation mode |
Metal–oxygen bond strength | Affects oxygen adsorption, intermediate stability, and product desorption |
Electronic structure | Affects electron transfer rate, reaction barriers, and the activity of oxygen species |
Multimetal synergy | Can regulate activity, stability, oxygen vacancy concentration, and surface reconstruction behavior |
Tendency toward surface reconstruction | New active surface layers may form during reaction |
The research focus differs among different B-site systems:
B-site system | Key focus |
Manganese-based systems | Oxygen migration, volatile organic compound oxidation, and cathode stability in solid oxide cells |
Iron-based systems | Structural stability, oxygen vacancy regulation, oxidation reactions, and electrode reactions |
Cobalt-based systems | Oxygen reduction, oxygen evolution reaction, low-temperature oxygen exchange, and oxidation activity |
Nickel-based systems | Redox activity, electronic structure, and reaction intermediate adsorption |
Cobalt–iron composite systems | Oxygen surface exchange, oxygen-ion migration, and overall electrochemical reaction performance |
The activity of B-site metals should not be understood as “the more reactive, the better.” If the metal–oxygen bond is too strong, reaction intermediates may not desorb easily. If the metal–oxygen bond is too weak, oxygen adsorption and activation may be insufficient. The key to catalyst design is to bring adsorption, reaction, electron transfer, oxygen migration, and product desorption into an appropriate balance. Especially when nickel-based and cobalt-based perovskites are used for the oxygen evolution reaction, oxide, hydroxide, or oxyhydroxide active layers may form on the surface after reaction. Therefore, activity evaluation should combine post-reaction surface structure analysis to identify the true active phase.
5. Which Energy and Environmental Reactions Perovskite Oxides Participate In
The catalytic reactions suitable for discussion with perovskite oxides are mostly related to oxygen adsorption, oxygen activation, lattice oxygen migration, or oxygen-ion conduction. Different reactions have different core controlling steps, so they should not be judged by the same material selection logic.
Reaction direction | Reaction essence | Key role of perovskite oxides | Key indicators |
Oxygen evolution reaction | Water or hydroxide is converted into oxygen | B-site metals regulate oxygen-containing intermediate adsorption, while surface reconstruction and oxygen vacancies influence reaction rate | Overpotential, current density, Tafel slope, Faradaic efficiency, stability |
Aqueous oxygen reduction reaction | Oxygen is reduced to water or hydroxide in an aqueous electrolyte | Surface oxygen adsorption, electron transfer, and oxygen intermediate stability determine activity | Onset potential, half-wave potential, electron transfer number, peroxide yield, stability |
Volatile organic compound oxidation | The goal is usually to deeply oxidize volatile organic compounds into carbon dioxide and water while controlling partially oxidized by-products | Surface active oxygen and lattice oxygen jointly participate in the oxidation cycle | Light-off temperature, half-conversion temperature, complete-conversion temperature, carbon dioxide selectivity, resistance to water and poisoning |
Carbon monoxide oxidation | Carbon monoxide is converted into carbon dioxide | Oxygen vacancies promote oxygen adsorption and activation, and lattice oxygen can participate in the oxidation process | Conversion temperature, reaction rate, moisture resistance, carbonate coverage |
Complete methane oxidation | Strong C–H bonds are activated and oxidized | Surface oxygen species, lattice oxygen activity, and thermal stability jointly influence conversion | Conversion, carbon dioxide selectivity, sintering resistance, water resistance |
Solid oxide fuel cell cathode reaction | Oxygen is adsorbed, dissociated, reduced, and converted into oxygen ions | Oxygen surface exchange, oxygen-ion migration, electronic conduction, and electrode structure jointly determine performance | Polarization resistance, area-specific resistance, power density, thermal expansion matching, long-term stability |
The oxygen evolution reaction and oxygen reduction reaction are key sluggish reactions in water splitting, fuel cells, and metal–air batteries. Because of their tunable composition and abundant transition-metal sites, perovskite oxides are widely studied as non-noble-metal oxygen electrocatalysts. Volatile organic compound oxidation, carbon monoxide oxidation, and methane oxidation place greater emphasis on surface oxygen species, lattice oxygen replenishment capacity, low-temperature activity, and long-term resistance to deactivation. Solid oxide fuel cell cathodes also require simultaneous consideration of oxygen exchange, oxygen-ion migration, electronic conduction, thermal expansion matching, and electrode–electrolyte compatibility.
6. From Performance Data to Structural Evidence: How to Judge Catalytic Results
Evaluation of perovskite oxide catalysts should not rely only on single-run activity. High conversion, low overpotential, or low polarization resistance only indicates good performance under the current testing conditions. To determine whether the material design is valid, performance data must be analyzed together with crystal phase, metal valence state, oxygen vacancies, surface structure, specific surface area, and post-reaction stability.
Question to be answered | Evidence to focus on | Judgment points |
Whether the target perovskite phase has formed | Crystal phase analysis, elemental ratio analysis | Confirm whether impurities, unreacted precursors, or composition deviations exist, and avoid mistaking impurity-phase activity for the intrinsic role of the perovskite |
Whether activity enhancement comes from B-site metal regulation | Surface valence analysis, absorption spectroscopy, comparison of valence states before and after reaction | Determine whether B-site metals such as manganese, iron, cobalt, and nickel participate in redox cycling and electron transfer |
Whether oxygen vacancies truly participate in catalysis | Multi-method oxygen defect analysis, oxygen temperature-programmed desorption, hydrogen temperature-programmed reduction, electron paramagnetic resonance, thermogravimetric analysis | Determine whether oxygen vacancy changes correspond to oxygen adsorption, oxygen migration, lattice oxygen replenishment, or activity changes |
Whether activity differences are only caused by specific surface area | Specific surface area and pore structure testing | Distinguish apparent activity enhancement caused by increased surface area from structural activity enhancement caused by regulation of the metal–oxygen network |
Whether the structure remains after reaction | Comparison of crystal phase, morphology, elemental distribution, and surface valence before and after reaction | Determine whether sintering, phase transformation, component segregation, metal dissolution, or surface coverage has occurred |
Whether lattice oxygen participates in the reaction | Isotope labeling, in situ spectroscopy, temperature-programmed reaction analysis | Determine whether the reaction involves lattice oxygen consumption, oxygen vacancy formation, and oxygen replenishment cycles |
Whether electrode performance is affected by interfaces | Impedance analysis, symmetric cell testing, observation of interfacial microstructure | Determine whether the limiting step originates from the material itself, interfacial contact, electrode pore structure, or ion conduction |
Whether the results are reproducible | Parallel samples, batch-to-batch reproducibility, records of reaction precursors and calcination conditions | Determine whether performance changes are reliable and avoid misjudgment caused by differences in synthesis batch, particle size, or testing conditions |
The focus of experimental evaluation is not to perform every characterization method, but to ensure that performance data and structural evidence can correspond to each other. If activity enhancement is accompanied by reasonable B-site metal valence changes, explainable oxygen vacancy regulation, a stable crystal structure, or a controllable surface active layer, then the structure–performance relationship becomes more convincing.
Conversely, if activity enhancement is accompanied by obvious phase transformation, metal dissolution, particle sintering, surface carbonate coverage, or excessive batch-to-batch variation, then it is necessary to judge cautiously whether this direction is worth further optimization. At this point, one should first return to material composition, synthesis route, calcination conditions, and testing environment to confirm whether the performance change comes from controllable structural regulation rather than an accidental surface state or irreversible damage.
7. Deactivation Mechanisms and Troubleshooting Priorities: Changes in Structure, Surface, and Reaction Environment
Deactivation of perovskite oxide catalysts is usually not caused by a single factor, but by the combined changes in structural stability, surface state, and reaction environment. During reaction, the surface may undergo reconstruction, lattice oxygen may be continuously consumed, oxygen vacancies may undergo irreversible changes, particles may sinter and grow, and A-site or B-site elements may segregate, dissolve, or react with the reaction atmosphere.
Deactivation source | Typical manifestation | Priority checks |
High-temperature sintering | Particles grow, specific surface area decreases, and active sites decrease | Particle size, pore structure, specific surface area, and morphology before and after reaction |
Uncontrolled surface reconstruction | Unexpected new phases form on the surface, and the active layer structure becomes unstable | Surface valence, crystal phase, and local structure before and after reaction |
A-site element segregation | Elements such as strontium and barium become enriched on the surface and may form carbonates or sulfates | Surface elemental composition and surface species after exposure to carbon dioxide or sulfur-containing atmospheres |
B-site metal dissolution | Active metals such as manganese, iron, cobalt, and nickel are lost, and electrocatalytic stability decreases | Metal content in the electrolyte, post-reaction surface composition, and crystal phase changes |
Carbonate or strongly adsorbed species coverage | Surface active sites are covered, and low-temperature oxidation activity decreases | In situ infrared spectroscopy, temperature-programmed desorption, and carbon dioxide influence experiments |
Irreversible oxygen vacancy changes | Oxygen migration and lattice oxygen replenishment capacity decrease, and activity becomes difficult to recover | Oxygen defect characterization, oxygen species changes, and reduction behavior before and after reaction |
Water vapor or impurity poisoning | Reactant adsorption and oxygen activation are hindered, and long-term activity decays | Water resistance, sulfur resistance, chlorine resistance, and impurity tolerance |
Structural phase transformation or secondary phase formation | The perovskite framework is damaged, and post-reaction performance decreases irreversibly | Post-reaction crystal phase, elemental distribution, and local structure |
Electrode interface degradation | Cathode impedance increases in solid oxide fuel cells, and interfacial reactions become restricted | Electrode–electrolyte interface, thermal expansion matching, and long-term impedance changes |
It should be noted that surface reconstruction is not necessarily always a cause of deactivation. In some oxygen evolution and oxygen reduction reactions, the surface of perovskite oxides may form new active layers that actually participate in the catalytic process. The key is whether such reconstruction is controllable and stable, and whether it is accompanied by severe metal dissolution, lattice collapse, or irreversible phase transformation.
To determine whether a perovskite oxide catalyst has deactivated, one should not look only at the activity decrease itself. It is also necessary to consider the crystal phase, surface valence state, elemental composition, oxygen vacancy state, specific surface area, and morphology changes before and after reaction. Only by correlating performance decay with structural changes can one determine whether deactivation arises from sintering, surface coverage, metal dissolution, oxygen defect imbalance, or mismatch between the reaction environment and the material itself.
8. Material Selection Logic: Matching Metal Sites, Oxygen Defects, and Stability According to the Reaction Task
The selection of perovskite oxide catalysts should begin with the reaction task. Different reactions have different requirements for metal valence states, metal–oxygen bond strength, oxygen vacancies, lattice oxygen migration, surface stability, and electrode interfaces.
Thermal catalytic oxidation reactions usually focus on oxygen adsorption, lattice oxygen replenishment, low-temperature activity, and resistance to water and poisoning. Electrocatalytic oxygen evolution and oxygen reduction reactions focus on B-site metal electronic structure, oxygen-containing intermediate adsorption, surface reconstruction, and metal dissolution. Solid oxide fuel cell cathodes require simultaneous consideration of oxygen surface exchange, oxygen-ion conduction, electronic conduction, thermal expansion matching, and interfacial stability.
Research objective | Material selection direction | Key focus |
Volatile organic compound oxidation | Manganese-based, cobalt-based, iron-based perovskite oxides and composite systems | Low-temperature activity, lattice oxygen activity, carbon dioxide selectivity, water resistance |
Carbon monoxide oxidation | Cobalt-based, manganese-based, or oxygen-vacancy-rich perovskite oxides | Oxygen adsorption, oxygen activation, surface carbonate coverage |
Complete methane oxidation | Thermally stable manganese-based, cobalt-based, and iron-based perovskite oxides | C–H bond activation, high-temperature stability, sintering resistance |
Oxygen evolution reaction | Cobalt-based, nickel-based, iron-based, or composite B-site systems | Overpotential, surface reconstruction, metal dissolution, long-term stability |
Oxygen reduction reaction | Lanthanum manganites, lanthanum cobaltites, lanthanum nickelates, and doped systems | Oxygen adsorption strength, electron transfer, reaction pathway, and stability |
Solid oxide fuel cell cathode | Strontium-doped lanthanum manganites, strontium-doped lanthanum cobalt ferrites, barium–strontium cobalt ferrites | Oxygen surface exchange, oxygen-ion conduction, thermal expansion matching, and interfacial stability |
High-temperature oxidation reactions | Thermally stable perovskite oxides and composite structures | Sintering resistance, phase stability, and lattice oxygen replenishment capacity |
Material selection can be judged in the following order:
1. Whether the reaction is mainly controlled by oxygen adsorption, oxygen activation, oxygen migration, or oxygen release;
2. Whether the B-site metal has suitable redox capability;
3. Whether the metal–oxygen bond strength is favorable for reaction intermediate adsorption and product desorption;
4. Whether oxygen vacancies can be reversibly generated, migrated, and replenished during the reaction;
5. Whether surface oxygen species are favorable for the target selectivity;
6. Whether the perovskite structure or the active surface layer remains stable after reaction;
7. Whether the catalyst has a basis for reproducible synthesis and stable operation.
9. Product Selection Guide for Perovskite Oxides in Energy and Environmental Catalysis (Tables 1–5)
Research or experimental objective | Recommended table to start with | Why start with this table | Tables to consult together | Selection guidance |
Establish a basic formulation for lanthanum-based perovskite oxides | Table 1 | Table 1 focuses on A-site metal sources such as lanthanum, strontium, barium, and calcium, helping first define the main perovskite oxide framework and the direction of A-site doping | Tables 2 and 4 | First determine the A-site composition, then select B-site manganese, iron, cobalt, or nickel sources, and combine them with synthesis aids to establish a precursor preparation route |
Compare the effects of A-site regulation by strontium, barium, calcium, and related elements on oxygen vacancies and structural stability | Table 1 | A-site ionic radius, charge balance, and doping ratio influence lattice distortion, oxygen vacancy formation, and high-temperature stability | Tables 2 and 3 | Comparative experiments can be designed around strontium doping, barium–strontium compositing, or calcium-based systems, followed by analysis of structure–performance relationships using oxygen-defect and oxygen-ion-conducting materials |
Select B-site transition metals to regulate catalytic activity | Table 2 | Table 2 focuses on manganese, iron, cobalt, and nickel sources. B-site metals directly affect valence cycling, metal–oxygen bond strength, oxygen adsorption, and electron transfer | Tables 1 and 3 | Manganese-based, iron-based, cobalt-based, nickel-based, or composite B-site systems can be selected according to the target reaction, followed by activity and stability regulation through A-site doping and oxygen-defect-related materials |
Study volatile organic compound oxidation, carbon monoxide oxidation, or methane oxidation | Table 2 | These reactions focus on oxygen activation, lattice oxygen replenishment, and metal valence cycling. B-site manganese, cobalt, and iron systems are usually starting points for experimental screening | Tables 1 and 3 | First determine the oxidation catalysis direction based on the B-site metal, then improve oxygen migration and resistance to deactivation through A-site regulation with strontium, barium, calcium, and composite materials such as ceria |
Conduct electrocatalytic research on the oxygen evolution reaction or oxygen reduction reaction | Table 2 | The oxygen evolution and oxygen reduction reactions are sensitive to B-site electronic structure, metal valence states, and oxygen-containing intermediate adsorption, so the B-site metal combination should be clarified first | Tables 1 and 5 | First determine cobalt-based, nickel-based, iron-based, or composite B-site systems, then complete electrode evaluation by combining A-site doping design with electrolytes and conductive auxiliary materials |
Construct solid oxide fuel cell cathodes or composite electrode materials | Table 3 | Table 3 includes yttria-stabilized zirconia, ceria, and rare-earth oxides, as well as precursors for zirconia-based composite or interfacial materials, which are suitable for oxygen-ion conduction, interface stabilization, and composite electrode studies | Tables 1 and 2 | Oxygen-ion-conducting or composite electrode materials can be identified first, then combined with A-site and B-site precursors to construct strontium-doped lanthanum manganite, lanthanum cobalt ferrite, or barium–strontium cobalt ferrite systems |
Study oxygen vacancies, lattice oxygen replenishment, and oxygen storage/release behavior | Table 3 | Cerium oxide, gadolinium oxide, samarium oxide, zirconium oxide, and yttria-stabilized zirconia can be used for oxygen-defect regulation, oxygen-ion conduction, and composite interface regulation | Tables 1 and 2 | Suitable for analyzing how composites of perovskite oxides with ceria-based or zirconia-based materials influence oxygen migration and catalytic cycling |
Prepare multimetal oxides by sol–gel, complexation combustion, or polymeric complexation methods | Table 4 | Table 4 lists citric acid, ethylene glycol, ethylenediaminetetraacetic acid, glycine, and urea, which are suitable for uniform dispersion of multiple metal ions, precursor gel formation, combustion, or precipitation control | Tables 1 and 2 | Select complexing agents, fuels, or precipitation-control aids according to the synthesis method, then match them with A-site and B-site metal salts to reduce compositional segregation and secondary phase formation |
Compare the effects of solid-state synthesis and wet-chemical methods on phase formation and particle structure | Tables 1 and 2 | Tables 1 and 2 include oxides, carbonates, nitrates, and acetates, which can be used to establish comparative experiments with different precursor routes | Table 4 | Solid-state synthesis can start from oxides or carbonates, while wet-chemical methods can start from nitrates and complexing aids, with emphasis on comparing phase purity, particle size, specific surface area, and oxygen-defect state |
Evaluate the electrocatalytic performance of perovskite oxide electrodes | Table 5 | Table 5 includes alkaline test electrolytes and conductive auxiliary materials, which can be used to establish electrocatalytic evaluation systems for oxygen evolution, oxygen reduction, and related reactions | Tables 2 and 3 | First build the test system using potassium hydroxide and conductive carbon materials, then analyze activity, stability, and electron-transport effects together with B-site metal composition and oxygen-defect-related materials |
Troubleshoot low catalytic activity, poor stability, or large batch-to-batch variation | Tables 1, 2, and 4 | A-site components, B-site components, and synthesis aids jointly influence phase purity, elemental distribution, oxygen vacancies, and particle structure, making them the main entry points for troubleshooting experimental differences | Tables 3 and 5 | If the issue is concentrated in oxygen migration or electrode performance, Tables 3 and 5 can be consulted to examine oxygen-ion conduction, composite interfaces, and the electrode conductive network |
Table 1 | A-Site Metal Sources: Lanthanum, Strontium, Barium, and Calcium Precursors
Category | CAS No. | Aladdin Catalog No. | Name | Specification or purity | Product features and applications |
A-site lanthanum source | 10277-43-7 | L106051 | Lanthanum nitrate hexahydrate | PrimorTrace™, ≥99.999% metals basis | Commonly used to prepare lanthanum-based perovskite oxides through sol–gel, complexation combustion, and coprecipitation routes; can serve as an A-site precursor for lanthanum manganite, lanthanum ferrite, lanthanum cobaltite, and lanthanum nickelate systems |
A-site lanthanum source | 1312-81-8 | L431805 | Lanthanum(III) oxide | Basic-grade reagent, for preparation | Can be used in solid-state or high-temperature sintering routes to prepare lanthanum-based perovskite oxides; suitable for studying A-site lanthanum content, phase formation, and high-temperature structural stability |
A-site strontium source | 10042-76-9 | S431181 | Strontium nitrate | Anhydrous grade, PrimorTrace™, ultrapure grade, ≥99.99% metals basis | Can serve as a soluble A-site precursor for strontium-doped perovskite oxides, used to regulate charge balance, oxygen vacancy formation, and oxygen surface exchange capability |
A-site strontium source | 1633-05-2 | Strontium Carbonate | Electronic grade, ≥99.5%, 0–1 μm | Can be used in solid-state synthesis of strontium-doped lanthanum manganite, lanthanum cobaltite, and lanthanum cobalt ferrite systems; suitable for studying the influence of strontium doping on oxygen vacancies, conductivity, and cathode reactions | |
A-site barium source | 10022-31-8 | B431112 | Barium nitrate | Suitable for analysis, ACS, premium grade | Can serve as a soluble A-site precursor for barium-based or barium–strontium composite perovskite oxides, used to study the effects of barium incorporation on lattice size, oxygen non-stoichiometry, and oxygen migration behavior |
A-site barium source | 513-77-9 | Barium carbonate | Electronic grade, ≥99.8% metals basis | Can be used in solid-state synthesis of barium-based or barium–strontium cobalt ferrite materials; suitable for studying phase formation in high-temperature oxidation reactions and solid oxide fuel cell cathode materials | |
A-site calcium source | 13477-34-4 | B431112 | Calcium nitrate tetrahydrate | BioReagent, ≥99% | Can be used in the wet-chemical synthesis of calcium-based perovskite oxides such as calcium manganite and calcium ferrite; suitable for studying the effects of calcium-site incorporation on lattice stability and oxygen migration |
A-site calcium source | 471-34-1 | Calcium carbonate | ≥99.995% metals basis | Can be used in solid-state synthesis of calcium-based perovskite oxides or composite oxides; suitable for studying high-temperature sintering, phase stability, and alkaline-earth-metal regulation in oxidation catalysis |
Table 2 | B-Site Transition Metal Sources: Manganese, Iron, Cobalt, and Nickel Precursors
Category | CAS No. | Aladdin Catalog No. | Name | Specification or purity | Product features and applications |
B-site manganese source | 20694-39-7 | Manganese(II) nitrate tetrahydrate | ≥98% | Can serve as a wet-chemical synthesis precursor for manganese-based perovskite oxides, used to prepare oxidation catalytic materials such as lanthanum manganite, strontium-doped lanthanum manganite, and calcium manganite | |
B-site manganese source | 6156-78-1 | Manganese acetate | PrimorTrace™, ≥99.99% metals basis | Can be used in complexation sol–gel and low-temperature precursor routes to prepare manganese-based composite oxides; suitable for studying manganese valence changes, oxygen vacancies, and lattice oxygen activity | |
B-site manganese source | 1313-13-9 | Manganese dioxide | ≥99.95% metals basis | Can serve as a manganese source for solid-state synthesis or as an oxidizing manganese component, used in the preparation of manganese-based perovskite oxides and composite oxides; suitable for volatile organic compound oxidation and carbon monoxide oxidation studies | |
B-site iron source | 7782-61-8 | Iron(III) nitrate nonahydrate | European Pharmacopoeia (Ph. Eur.), suitable for analysis, ACS, premium grade | Can serve as a soluble B-site precursor for iron-based perovskite oxides, used in the wet-chemical synthesis of lanthanum ferrite, strontium-doped lanthanum ferrite, and cobalt–iron composite systems | |
B-site iron source | 1309-37-1 | F108317 | Ferric sesquioxide | AR, ≥99% | Can serve as an iron source for solid-state synthesis, used to prepare iron-based perovskite oxides and cobalt–iron composite oxides; suitable for studying structural stability, redox behavior, and durability in high-temperature reactions |
B-site cobalt source | 10026-22-9 | Cobalt(II) nitrate hexahydrate | Suitable for analysis, premium grade | Can serve as a wet-chemical synthesis precursor for cobalt-based perovskite oxides, used for compositional regulation of lanthanum cobaltite, strontium-doped lanthanum cobaltite, and cobalt–iron composite systems | |
B-site cobalt source | 1307-96-6 | Cobalt(II)oxide | Reagent grade | Can serve as a cobalt source for solid-state synthesis, used to prepare cobalt-based perovskite oxides and composite oxides; suitable for studying cobalt valence states, metal–oxygen bond strength, and low-temperature oxidation activity | |
B-site cobalt source | 1308-06-1 | Cobalt(II,III) oxide | Powder, <10 μm | Can serve as a B-site source for cobalt-based composite oxides and cobalt–iron perovskite materials; suitable for studying the effects of multivalent cobalt on oxygen adsorption, oxygen exchange, and electrocatalytic reactions | |
B-site nickel source | 13478-00-7 | N108888 | Nickel nitrate hexahydrate | PrimorTrace™, ≥99.999% metals basis | Can serve as a wet-chemical synthesis precursor for nickel-based perovskite oxides, used to study the electronic structure and redox activity of lanthanum nickelate and composite B-site systems |
B-site nickel source | 1313-99-1 | Nickel(II) oxide | Nanowires, diameter × length ~20 nm × 10 μm | Can serve as a nickel source or composite oxide component, used in nickel-based perovskite oxides, redox catalysis, and electrode material studies; the nanowire morphology is useful for constructing contact interfaces |
Table 3 | Oxygen-Defect Regulation, Oxygen-Ion Conductor Precursors, and Composite Electrode-Related Materials
Category | CAS No. | Aladdin Catalog No. | Name | Specification or purity | Product features and applications |
Oxygen-defect and oxygen storage/release regulation material | 1306-38-3 | C431729 | Cerium(IV) oxide | Nanopowder, particle size <25 nm | Has oxygen storage/release and cerium valence cycling characteristics; can be used for composite modification of perovskite oxides and to support studies of oxygen vacancies, lattice oxygen replenishment, and low-temperature oxidation activity |
Oxygen-defect and composite electrolyte component | 12064-62-9 | G105875 | Gadolinium oxide | PrimorTrace™, ≥99.99% metals basis | Can be used to prepare oxygen-ion-conducting materials such as gadolinium-doped ceria, and can also serve as an ion-conduction-regulating component in composite electrodes |
Oxygen-defect and composite electrolyte component | 12060-58-1 | S118883 | Samarium oxide | PrimorTrace™, ≥99.999% metals basis | Can be used to prepare composite ion conductors such as samarium-doped ceria; suitable for studying oxygen-ion conduction and interfacial reactions in solid oxide cell electrodes |
Zirconia-based composite and interface-stabilizing material | 1314-23-4 | Zirconium(IV) oxide | Nanoparticle dispersion, <100 nm particle size (BET), 5 wt.% in H₂O | Can be used in zirconia-based composite materials, electrode coatings, and interface stabilization studies; the nano-dispersion form facilitates the construction of uniform composite structures | |
Oxygen-ion conduction stabilizer | 1314-36-9 | Y431838 | Yttrium oxide 99+ | Suitable for analysis, premium reagent, ≥99% | Can serve as a zirconia stabilizer and a component of solid oxide cell-related materials, used to regulate oxygen-ion conduction, thermal stability, and electrode–electrolyte compatibility |
Oxygen-ion conductor and electrode composite material | 114168-16-0 | Z477814 | Zirconium(IV) oxide-yttria stabilized | Nanopowder | Can serve as a solid oxide cell electrolyte or composite cathode component, used to study oxygen-ion conduction, electrode interfaces, and thermal expansion matching |
Table 4 | Complexation, Sol–Gel, and Combustion Synthesis Aids
Category | CAS No. | Aladdin Catalog No. | Name | Specification or purity | Product features and applications |
Complexation sol–gel synthesis aid | 77-92-9 | Citric acid | Moligand™, anhydrous grade, ACS, ≥99.5% | Can serve as a metal-ion complexing agent for preparing compositionally uniform perovskite oxide precursors; suitable for homogenizing composition in multimetal systems | |
Complexation sol–gel synthesis aid | 5949-29-1 | Citric acid monohydrate | AR, ≥99.5% | Can be used in citric acid complexation methods to prepare precursors for lanthanum manganite, lanthanum ferrite, lanthanum cobaltite, and cobalt–iron composite perovskite oxides | |
Polymeric complexation synthesis aid | 107-21-1 | E1522420 | Ethylene glycol | USP, electronic grade, ≥99.5% | Can be used together with citric acid in polymeric complexation routes to help form uniform gel precursors; suitable for low-temperature synthesis studies of multimetal perovskite oxides |
Complexation regulation aid | 60-00-4 | Ethylenediaminetetraacetic acid | AR, ≥99.5% | Can complex various metal ions and regulate precursor solution stability and metal-ion distribution; suitable for the synthesis of complex doped perovskite oxides | |
Combustion synthesis aid | 56-40-6 | Glycine | Moligand™, ≥99% | Can serve as both a complexing agent and a fuel in combustion synthesis, used for rapid preparation of multimetal oxide precursors; suitable for screening perovskite phase formation conditions | |
Combustion synthesis and precipitation regulation aid | 57-13-6 | Urea | AR, ≥99% | Can be used in combustion synthesis, homogeneous precipitation, and precursor acid–base regulation; suitable for preparing composite oxide powders with good dispersibility |
Table 5 | Electrocatalytic Testing Electrolyte, Conductive Auxiliary Material, and Control Variables
Category | CAS No. | Aladdin Catalog No. | Name | Specification or purity | Product features and applications |
Electrocatalytic testing electrolyte | 1310-58-3 | Potassium hydroxide | Electronic grade, ≥99.999% metals basis, excludes sodium content | Can be used in alkaline oxygen evolution reaction and oxygen reduction reaction testing systems; suitable for evaluating the electrocatalytic activity, stability, and reaction pathways of perovskite oxides | |
Electrode conductive auxiliary material | 1333-86-4 | C431910 | Carbon, mesoporous | ≥99.95% metals basis, nanopowder, graphitized, <500 nm particle size (DLS) | Can be used to construct conductive networks in electrocatalytic electrode preparation and improve electronic contact between perovskite oxide particles and the current collector; it should also be treated as a testing control variable, especially in oxygen evolution reaction evaluation, where carbon oxidation and its influence on apparent activity need to be considered |
Note: The products listed above are representative Aladdin products. Additional product specifications can be searched on the Aladdin website using the product name, CAS number, or catalog number.
References
[1] Suntivich J., May K. J., Gasteiger H. A., Goodenough J. B., Shao-Horn Y. A Perovskite Oxide Optimized for Oxygen Evolution Catalysis from Molecular Orbital Principles. Science, 2011, 334: 1383–1385.
[2] Suntivich J., Gasteiger H. A., Yabuuchi N., Nakanishi H., Goodenough J. B., Shao-Horn Y. Design Principles for Oxygen-Reduction Activity on Perovskite Oxide Catalysts for Fuel Cells and Metal–Air Batteries. Nature Chemistry, 2011, 3: 546–550.
[3] Liu L. B., Yi C., et al. Perovskite Oxides Toward Oxygen Evolution Reaction: Intellectual Design Strategies, Properties and Perspectives. Electrochemical Energy Reviews, 2024, 7: 14.
[4] Li Z., Mao X., Feng D., et al. Prediction of Perovskite Oxygen Vacancies for Oxygen Electrocatalysis at Different Temperatures. Nature Communications, 2024, 15: 9318.
[5] Yang L., et al. Perovskite Oxides in Catalytic Combustion of Volatile Organic Compounds: Recent Advances and Future Prospects. Energy & Environmental Materials, 2022, 5(3): 751–776.
[6] Jiang Y., Feng Y., Rastegarpanah A., et al. Perovskite-type Oxide Catalysts for VOC Removal: Recent Advances and Future Prospects. Environmental Science: Nano, 2025, 12: 4491–4514. DOI: 10.1039/D5EN00680E.
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