Open access peer-reviewed chapter

Perovskite Nanomaterials – Synthesis, Characterization, and Applications

Written By

Nada F. Atta, Ahmed Galal and Ekram H. El-Ads

Submitted: 31 March 2015 Reviewed: 18 August 2015 Published: 03 February 2016

DOI: 10.5772/61280

From the Edited Volume

Perovskite Materials - Synthesis, Characterisation, Properties, and Applications

Edited by Likun Pan and Guang Zhu

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Abstract

Inorganic perovskite-type oxides are fascinating nanomaterials for wide applications in catalysis, fuel cells, and electrochemical sensing. Perovskites prepared in the nanoscale have recently received extensive attention due to their catalytic nature when used as electrode modifiers. The catalytic activity of these oxides is higher than that of many transition metals compounds and even some precious metal oxides. They exhibit attractive physical and chemical characteristics such as electronic conductivity, electrically active structure, the oxide ions mobility through the crystal lattice, variations on the content of the oxygen, thermal and chemical stability, and supermagnetic, photocatalytic, thermoelectric, and dielectric properties.

Keywords

  • Nanomaterials
  • Perovskites
  • Sensors
  • Catalysis
  • Fuel cells

1. Introduction

1.1. General introduction to perovskites

The mineral CaTiO3 was discovered by Geologist Gustav Rose in the Ural Mountains in 1839, and it was named perovskite in recognition beholden to Count Lev Alexevich von Perovski, an eminent Russian mineralogist [15]. The name perovskite represented any compound that has ABC3 formula where an octahedron of C ions surrounded the B ion. The Earth’s crust contains various types of perovskites and the most abundant ones are MgSiO3 and FeSiO3. Perovskite family includes several types of oxides like transition metal oxides with the formula ABO3. Some examples of ABO3 perovskites and their corresponding properties are summarized in Table 1 [1, 2, 5].

Perovskite oxides exhibit an array of electrical properties and a variety of solid-state phenomena from insulating, semiconducting, metallic, and superconducting characters; therefore, they are very fascinating to be studied and applied in a large scale. Many of ABO3 perovskites are cubic or nearly cubic in structure in their ideal form; however, one or more phase transitions may be achieved particularly at low temperature. In addition, many of them showed magnetic ordering and as a result, large variety of magnetic structures can be found. Some perovskites contained localized electrons, some contained delocalized energy-band states, and the behavior of other perovskites was a transition between these two types. The perovskite structures can incorporate ions of various size and charge showing great flexibility of composition. Moreover, substitutions of ions into the A- and/or B-sites or deviation from ideal stoichiometry resulted in altering the electronic properties of the perovskites. Perovskites exhibit atomic arrangement in the form of 3-dimensional array of corner sharing octahedra. On the other hand, layered perovskites included 2-dimensional layers of corner sharing octahedral separated by cations layers. As a result, the electronic energy bands of perovskites and layered perovskites are very unusual and their structure is unique in properties [1, 2]. Perovskites displayed diversity of electric, optical, and magnetic properties because of the fact that 90% of the elements in the periodic table can be stable in the perovskite structure and the feasibility of partial substitutions of cations in A- and B-sites forming A1-xA′xB1-yB′yO3 [6]. Perovskites showed great interest in several applications due to their wide various and useful properties in photochromic, electrochromic, image storage, switching, filtering, and surface acoustic wave signal processing devices. They were utilized as catalytically active catalyst for several reactions like carbon monoxide and hydrocarbons oxidation, hydrogen evolution reaction and nitrogen oxides, and oxygen reduction reactions. They also have a good impact in many electrochemical applications like sensing, biosensing, photoelectrolysis of water-producing hydrogen, and fuel cells [1, 2].

Insulating Metallic Magnetic Superconducting
SrTiO3 (n-type)
WO3 ReO3 PbCrO3 NaxWO3 (t)
NaTaO3 NaWO3 LaCrO3 KxWO3 (t)
SrTiO3 KMoO3 CaMnO3 KxWO3 (h)
BaTiO3 SrNbO3 LaMnO3 RbxWO3 (h)
KTaO3 LaTiO3 LaCoO3 CsxWO3 (h)
LiNbO3 LaWO3 LaFeO3 LixWO3 (h)

Table 1.

Some perovskites and corresponding properties [1].

t; tetragonal, h; hexagonal


1.2. Crystallography of the perovskite structure

In the ABO3 form, B is a transition metal ion with small radius, larger A ion is an alkali earth metals or lanthanides with larger radius, and O is the oxygen ion with the ratio of 1:1:3. In the cubic unit cell of ABO3 perovskite, atom A is located at the body center, atom B is located at the cube corner position, and oxygen atoms are located at face-centered positions (Figure 1). The 6-fold coordination of B cation (octahedron) and the 12-fold coordination of the A cation resulted in the stabilization of the perovskite structure. The perfect perovskite structure was described by Hines et al. as corner linked BO6 octahedra with interstitial A cations [110]. Some distortions may exist in the ideal cubic form of perovskite resulted in orthorhombic, rhombohedral, hexagonal, and tetragonal forms (Figure 1) [37]. Figure 2 represented the distortion from cubic perovskite to orthorhombic one. In general, all perovskite distortions maintaining the A- and the B-site oxygen coordination was achieved by the tilting of the BO6 octahedra and an associated displacement of the A cation [4].

V.M. Goldschmidt presented much of the early work on the synthetic perovskites and developed the principle of the tolerance factor t, which is applicable to the empirical ionic radii at room temperature [29]:

t= (rA+rO) / [21/2(rB+rO)],BB1

where rA is the radius of the A-site cation, rB is the radius of the B-site cation, and rO is the radius of oxygen ion O2–. The tolerance factor can be used to estimate the suitability of the combination of cations for the perovskite structure [2]. It is a real measure of the degree of the distortion of perovskite from the ideal cubic structure so the value of t tends to unity as the structure approaches the cubic form [4]. From the equation, the tolerance factor will decrease when rA decreases and/or rB increases. Based on the analysis of tolerance factor value, Hines et al. solely suggested that the perovskite structure can be estimated. For 1.00 < t < 1.13, 0.9 < t < 1.0, and 0.75 < t <0.9, the perovskite structure is hexagonal, cubic, and orthorhombic, respectively. For t < 0.75, the structure was adopted to hexagonal ilmenite structure (FeTiO3) [4].

Generally, two requirements should be fulfilled for perovskite formation:

  1. Electroneutrality; the perovskite formula must have neutral balanced charge therefore the product of the addition of the charges of A and B ions should be equivalent to the whole charge of the oxygen ions. An appropriate charge distribution should be attained in the forms of A1+B5+O3, A4+B2+O3 or A3+B3+O3.

  2. Ionic radii requirements; rA > 0.090 nm and rB > 0.051 nm, and the tolerance factor must have values within the range 0.8 < t < 1.0 [28].

Figure 1.

Different perovskite unit cells. Blue spheres represent the A cations, yellow spheres represent the B cations and red spheres represent oxygen anions forming an octahedra [4].

Figure 2.

Perovskite distortion from (a) cubic to (b) orthorhombic [4].

1.3. Typical properties of perovskites

Perovskite exhibited a variety of fascinating properties like ferroelectricity as in case of BaTiO3 and superconductivity as in case of Ba2YCu3O7. They exhibited good electrical conductivity close to metals, ionic conductivity and mixed ionic and electronic conductivity. In addition, several perovskites exhibited high catalytic activity toward various reactions. Table 2 contains a summary of typical properties of perovskites. Several typical properties will be discussed in this section like ferroelectricity, magnetism, superconductivity, and catalytic activity [9].

Typical property Typical compound
Ferromagnetic property BaTiO3, PdTiO3
Piezoelectricity Pb(Zr, Ti)O3, (Bi, Na)TiO3
Electrical conductivity ReO3, SrFeO3, LaCoO3, LaNiO3, LaCrO3
Superconductivity La0.9Sr0.1CuO3, YBa2Cu3O7, HgBa2Ca2Cu2O8
Ion conductivity La(Ca)AlO3, CaTiO3, La(Sr)Ga(Mg)O3, BaZrO3, SrZrO3, BaCeO3
Magnetic property LaMnO3, LaFeO3, La2NiMnO6
Catalytic property LaCoO3, LaMnO3, BaCuO3
Electrode La0.6Sr0.4CoO3, La0.8Ca0.2MnO3

Table 2.

Typical properties of perovskite oxides [9].

1.3.1. Dielectric properties

There are some properties inherent to dielectric materials like ferroelectricity, piezoelectricity, electrostriction, and pyroelectricity. One of the important characteristic of perovskites is ferroelectric behavior, which is obvious in BaTiO3, PdZrO3, and their doped compounds. The ferroelectric behavior of BaTiO3 was strongly related to its crystal structure. BaTiO3 was subjected to three phase transitions; as the temperature increases, it was converted from monoclinic to tetragonal then to cubic. At temperature higher than 303 K, BaTiO3 does not show any ferroelectric behavior as it crystallizes into cubic structure. BaTiO3 showed high dielectric constant based on the anisotropy of its crystal structure resulting in large dipole moment generation in BaTiO3 [9].

1.3.2. Electrical conductivity and superconductivity

One of the obvious properties of perovskites is superconductivity. Cu-based perovskites act as high-temperature superconductors, and La-Ba-Cu-O perovskite was first reported. The presence of Cu in B-site is essential for the superconductivity and various superconducting oxides can be manufactured with different A-site ions. Some examples of high temperature superconductors are YBa2Cu3O7, Bi2Sr2Ca2Cu3O10, and HgBa2Ca2Cu3O8+δ with critical temperature of superconducting transition (Tc) of 130–155 K. The superconductivity is associated with the layers of Cu-O in Cu-based perovskites, and the Tc value is associated with the Cu-O layers number in the crystal lattice. The synthesis of 5 or more Cu-O-layered perovskites did not achieve successfully due to the low chemical stability. One of the highly significant superconductors with great Tc value is YBa2Cu3O7. In addition, the oxygen nonstiochiometry is one of the most significant reasons for the high value of Tc. In YBa2Cu3O7–δ, when the value of δ < 0.5, it crystallizes into orthorhombic structure, which is superconductive. For δ > 0.5, it showed a tetragonal structure that does not show any superconductivity. The crystal structure affected greatly the superconductivity in high Tc oxides, and as a result, high Tc values can be achieved by improving the chemical stability of the perovskite crystal structure. Furthermore, some perovskites exhibited great electronic conductivity similar to that of metals like Cu. LaCoO3 and LaMnO3 are examples of perovskites exhibiting high electronic conductivity, and therefore they are utilized as cathodes in solid oxide fuel cells displaying superior hole conductivity of 100 S/cm. The electronic conductivity of the perovskites can be enhanced by doping the A-site with another cation, which resulted in increasing the quantity of the mobile charge carriers created by the reparations of charge [9].

1.3.3. Catalytic activity

Perovskites showed excellent catalytic activity and high chemical stability; therefore, they were studied in a wide range in the catalysis of different reactions. Perovskites can be described as a model of active sites and as an oxidation or oxygen-activated catalyst. The stability of the perovskite structure allowed the compounds preparation from elements with unusual valence states or a high extent of oxygen deficiency. Perovskites exhibited high catalytic activity, which is partially associated with the high surface activity to oxygen reduction ratio or oxygen activation that resulted from the large number of oxygen vacancies. Perovskites can act as automobile exhaust gas catalyst, intelligent automobile catalyst and cleaning catalyst, etc., for various catalytic environmental reactions. It was reported in the literature that perovskites containing Cu, Co, Mn, or Fe showed excellent catalytic activity toward the direct decomposition of NO at high temperature, which is considered one of the difficult reactions in the catalysis (2NO N2+O2). Perovskites showed superior activity for this reaction at high temperatures because of the presence of oxygen deficiency and the simple elimination of the surface oxygen in the form of a reaction product. NO decomposition activity was enhanced upon doping. Also, under an atmosphere that is rich with oxygen up to 5%, Ba(La)Mn(Mg)O3 perovskite exhibited superior activity toward the decomposition of NO [9].

Perovskite showed a great impact as an automobile catalyst; intelligent catalyst. Pd-Rh-Pt catalysts was utilized as an effective catalyst for the removal of NO, CO and uncombusted hydrocarbons. There is another catalyst that consists of fine particles, with high surface-to-volume ratio, and can be utilized to reduce the amount of precious metals used. However, these fine particles exhibited very bad stability under the operation conditions leading to catalyst deactivation. Therefore, perovskite oxides can be used showing redox properties to preserve a great dispersion state. Upon oxidation, Pd is oxidized in the form of LaFe0.57Co0.38Pd0.05O3 and upon reduction; fine metallic particles of Pd were produced with radius of 1–3 nm. This cycle resulted in partial replacement of Pd into and sedimentation from the framework of the perovskite under oxidizing and reducing conditions, respectively, displaying a great dispersion state of Pd. Also, this cycle improved the excellent long-term stability of Pd during the pollutants removal from the exhaust gas. Exposing the catalyst to oxidizing and reducing atmosphere resulted in the recovery of the high dispersion state of Pd. This catalyst is known as intelligent catalyst because of the great dispersion state of Pd and the excellent stability of the perovskite structure [9].

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2. Methods of perovskite synthesis

2.1. Solid-state reactions

In solid-state reactions, the raw materials and the final products are in the solid-state therefore nitrates, carbonates, oxides, and others can be mixed with the stoichiometric ratios. Perovskites can be synthesized via solid-state reactions by mixing carbonates or oxides of the A- and B-site metal ions corresponding to the perovskite formula ABO3 in the required proportion to obtain the final product with the desired composition. They are ball milling effectively in an appropriate milling media of acetone or isopropanol [11, 12]. Then the obtained product is dried at 100 °C and calcined in air at 600 °C for 4–8 h under heating/cooling rates of 2 °C/min. After that, the calcined samples are ground well and sieved. Then it was calcined again at 1300–1600 °C for 5–15 h under the heating/cooling rate of 2 °C/min to confirm the formation of single phase of perovskite. Again grinding and sieving was carried out for the calcined samples [11, 13, 14]. The synthesis of BaCeO3-based proton conductor perovskites [13] and BaCe0.95Yb0.05O3−δ [11] was achieved through the previous methodology using BaCO3, CeO2, and Yb2O3 as the starting materials and isopropanol as the milling media [10].

2.2. Gas phase preparations

Gas phase reaction or transport can be used for the deposition of perovskite films with a specific thickness and composition. Laser ablation [15], molecular beam epitaxy [16], dc sputtering [17], magnetron sputtering [18], electron beam evaporation [19], and thermal evaporation [20] techniques were developed for gas phase deposition. Gas phase deposition can be categorized into three types: (i) deposition at a low substrate temperature then postannealing at high temperature, (ii) deposition at an intermediate temperature of 873 to 1,073 K then postannealing treatment, and (iii) deposition at the crystallization temperature under suitable atmosphere. YBa2Cu3O7 films can be synthesized by the coevaporation of Y, Cu, and BaF2 then annealing at high temperatures in O2 atmosphere wet with water vapor to reduce the annealing time and substrate interaction [20].

2.3. Wet chemical methods (solution preparation)

These methods included the sol-gel preparation, coprecipitation of metal ions using precipitating agents like cyanide, oxalate, carbonate, citrate, hydroxide ions, etc., and thermal treatment [21], which resulted in a single-phase material with large surface area and high homogeneity. These methods presented good advantages such as lower temperature compared to the solid-state reactions, better homogeneity, greater flexibility in forming thin films, improved reactivity and new compositions and better control of stoichiometry, particle size, and purity. Therefore, they opened new directions for molecular architecture in the synthesis of perovskites. Solution methods were classified based on the means used for solvent removal. Two classes were identified: (i) precipitation followed by filtration, centrifugation, etc., for the separation of the solid and liquid phases and (ii) thermal treatment such as evaporation, sublimation, combustion, etc., for solvent removal. There are several factors must be taken in consideration in solution methods like solubility, solvent compatibility, cost, purity, toxicity, and choice of presumably inert anions [10].

2.3.1. Precipitation

2.3.1.1. Oxalate-based preparation

This method is built on the assimilation of oxalic acid with carbonates, hydroxides, or oxides producing metal oxalates, water, and carbon dioxide as products [22]. The solubility problem is minimized as the pH of the resulting solution is close to 7. An oxidizing atmosphere like oxygen was used during calcination to avoid the formation of carbide and carbon residues [23]. Clabaugh et al. utilized an aqueous chloride solution with oxalic acid to obtain unique and novel complex compound of BaTiO(C2O4)2 4H2O as a precursor for the preparation of finely divided and stoichiometric BaTiO3 [24].

2.3.1.2. Hydroxide-based preparation

This method is often used due to its low solubility and the possible variety of precipitation schemes. The sol-gel process can be used to produce a wide range of new materials and improve their properties. It presented some advantages over the other traditional methods like chemical homogeneity, low calcination temperature, room temperature deposition, and controlled hydrolysis for thin film formation. BaZrO3 powders in its pure crystalline form can be prepared by the precipitation in aqueous solution of high basicity [25]. LaCoO3 was prepared by the simultaneous oxidation and coprecipitation of a mixture containing equimolar amounts of La(III) and Co(II) nitrates producing a gel containing hydroxide then calcination at 600 °C [26].

2.3.1.3. Acetate-based preparation

Different perovskites were prepared by mixing acetate ions alone or together with nitrate ions with the metal ions salts. La1-xSrxCoO3 with x = 0, 0.2, 0.4, 0.6 [27] was prepared using acetate precursors then calcination at 1,123 K in air for 5 h. La1-xSrxCo1-yFeyO3 [28] was prepared using iron nitrate and strontium, cobalt, and lanthanum acetates then calcination at 1,123 K in air between 5 and 10 h.

2.3.1.4. Citrate-based preparation

Citrate precursors can be used and undergo several decomposition steps in the synthesis of perovskite [29]. These steps included the decomposition of citrate complexes and removal of CO32– and NO3¯ ions. LaCo0.4Fe0.6O3 can be prepared by this method, and the mechanism was investigated by thermogravimetry, XRD, and IR spectroscopy.

2.3.1.5. Cyanide-based preparation

Rare earth orthoferrites (REFeO3) and cobalt compounds (RECoO3) were prepared using cyanides complexes via thermal decomposition of the rare earth ferricyanide and cobalticyanide compounds [30]. LaFe(CN)6 6H2O, LaCo(CN)6 5H2O, and even ferrocyanides such as NH4LaFe(CN)6 5H2O are precipitated from the aqueous solution. This method presented some advantages like control of stoichiometry and low calcination temperature. The same method was used for the preparation of europium and other rare earth hexacyanoferrate compounds [31].

2.3.2. Thermal treatment

2.3.2.1. Freeze-drying

The freeze-drying method can be achieved through the following steps: (i) dissolution of the starting salts in the suitable solvent, water in most cases; (ii) freezing the solution very fast to keep its chemical homogeneity; (iii) freeze-drying the frozen solution to get the dehydrated salts without passing through the liquid phase; and (iv) decomposition of the dehydrated salts to give the desired perovskite powder. The rate of heat loss from the solution is the most important characteristic for the freezing step. This rate should be as high as possible to decrease the segregation of ice-salt. Also, in case of multicomponent solutions, the heat loss rate should be high to prevent the large-scale segregation of the cation components [10, 12, 21].

2.3.2.2. Plasma spray-drying

This method was applicable to various precursors, including gaseous, liquid, and solid materials. It was applied for the preparation of various ceramic, electronic, and catalytic materials. It presented many advantages in terms of economy, purity, particle size distribution, and reactivity. This method was achieved through two steps: (i) injection of the reactants and (ii) generation and interaction of the molten droplets (with substrate or with the previously generated droplets). The thick film of YBa2Cu3Ox covering large areas was prepared via this approach, and the optimum superconducting oxide phase was obtained by varying the preparation conditions like plasma parameters, substrate temperatures, and film postdeposition treatment [32].

2.3.2.3. Combustion

A redox reaction, which is thermally induced, occurs between the oxidant and fuel. A homogenous, highly reactive, and nanosized powder was prepared by this method. When compared with the other traditional methods, a single-phase perovskite powder can be obtained at lower calcination temperatures or shorter reaction times. One of the most popular solution combustion methods is citrate/nitrate combustion, where citric acid is the fuel and metal nitrates are used as the source of metal and oxidant. It is similar to the Pechini process “sol-gel combustion method” to a large extent, but in citrate/nitrate combustion, ethylene glycol or other polyhydroxy alcohols are not used. In addition, in citrate/nitrate combustion, the nitrates are not eliminated in the form of NOx, but they remain in the mixture with the metal-citrate complex facilitating the auto-combustion. Iron, cobalt, and cerium-perovskite can be prepared via citrate/nitrate combustion synthesis [12, 33]. In addition, uniform nanopowder of La0.6Sr0.4CoO3−δ was prepared by the combined citrate–EDTA method, where the precursor solution was made of metal nitrates, citric acid, and EDTA under controlled pH with ammonia [34]. La0.8Sr0.2Co0.2Fe0.8O3−δ [35] and Sr- or Ce-doped La1−xMxCrO3 catalysts [36] were prepared by citrate/nitrate combustion method. Furthermore, the Pechini “citrate gel” process includes two stages: (i) a complex was formed between the metal ions and citric acid, then (ii) the produced complex was polyesterified with ethylene glycol to maintain the metal salt solution in a gel in a homogenous state. This approach presented some advantages like high purity, minimized segregation, and good monitoring of the resulting perovskite composition. LaMnO3 [37, 38], LaCoO3 [3941], and LaNiO3 [42] were prepared by citric acid gel process producing nanophasic thin films [10].

2.3.2.4. Microwave synthesis

The microwave irradiation process (MIP), evolving from microwave sintering, was applied widely in food drying, inorganic/organic synthesis, plasma chemistry, and microwave-induced catalysis. MIP showed fascinating advantages: (i) fast reaction rate, (ii) regular heating, and (iii) efficient and clean energy. The microwave preparations were achieved in domestic microwave oven at frequency of 2.45 GHz with 1 kW as the maximum output power. Dielectric materials absorbed microwave energy converted directly into heat energy through the polarization and dielectric loss in the interior of materials [43]. The energy efficiency reached 80–90% which is much higher than the conventional routes. MIP was recently utilized to prepare perovskites nanomaterials reducing both the high temperature of calcination (higher than 700 °C) and long time (greater than 3 h) required for pretreatment or sintering [10]. GaAlO3 and LaCrO3 perovskites with ferroelectric, superconductive, high-temperature ionic conductive and magnetic ordering properties, faster lattice diffusion, and grain size with smaller size were prepared in MIP [4447]. CaTiO3 powders prepared in MIP presented a fast structural ordering than powders dealt in ordinary furnace [48]. Hydrothermal conventional and dielectric heating were utilized to prepare La–Ce–Mn–O catalysts. Hydrothermal MIP leads to formation of La1−xCexMnO3+εCeO2 (x + ε = 0.2) with enhanced catalytic activity [49] while using the conventional heating methods lead to formation of LaMnO3 + CeO2. Moreover, nanosized single-phase perovskite-type LaFeO3 [50], SmFeO3, NdFeO3, GdFeO3, barium iron niobate powders [51], KNbO3 [52], PbWO4 [53], CaMoO4 [54] and MWO4 (M: Ca, Ni) [55], strontium hexaferrite [56], and SrRuO3 [57] were prepared in MIP showing finer particles, higher specific surface areas and shorter time for synthesis of single crystalline powders.

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3. Doping of perovskites

The different properties of perovskites and their catalytic activity are highly affected by the method of synthesis, conditions of calcination (time, atmosphere, fuel, temperature, etc.), and A- and/or B-site substitutions. The catalytic activity of the perovskite is highly affected by partial or total substitutions on A- and/or B-site cations because of the oxidation state modification, the variation of the chemical state of the elements at A- and/or B-site, the generation of oxygen vacancies, the mobility of oxygen lattice, and the formation of structural defects [5860]. The powerful bond between the B-site metal ions and the oxygen ions can be used to determine the basic characters of perovskites, and as a result, the B-site cation is responsible for the perovskite catalytic activity [61, 62]. Therefore, partial substitution of B-site cation with other metals M in AB1-yMyO3 will display the properties of both metals: the main metal B and the dopant one M [62]. On the other hand, the cation A can stabilize the unusual oxidation states of B-site cations by the controlled formation of crystal lattice vacancies, which lead to different catalytic performances [61].

Upon doping A- and/or B-sites in ABO3 perovskite oxides, the catalytic activity, ionic and electronic conductivity, and flexible physical and chemical properties can be altered for utilization in various applications [6366]. Different cations with different sizes and charges can be hosted in the A- and B-sites of these perovskites; thus, many studies can be performed to utilize doped perovskites in various applications. Multiple cationic substitutions can be accepted in the stable perovskite lattice provided that Goldschmidt tolerance factor ranged between 0.75 and 1 and electroneutrality are preserved [59, 67, 68]. Therefore, variable amounts of different structural and electronic lattice defects can be accommodated in the perovskite structure as a result of their nonstoichiometry. This will further affect the activity of the perovskite and stabilize the unusual valence states of different metal ions [61, 67]. Some physical characteristics of perovskite-type oxides seriously associated with structural characters were affected greatly by the structural deformations from the ideal cubic structure of the perovskite [69].

The type of the metal ion at the B-sites and their partial substitutions can be used to determine the catalytic activity of perovskites. The substitution of B-site metal ion with various metal ions M in the doped perovskite AB1-yMyO3 showed a vast spectrum for the alteration of the catalytic and physical properties of the prepared perovskite [64, 67]. There is an effective synergism between the crystal lattice of the perovskite and the metal ions dissolved in the lattice upon doping. This synergism resulted in enhanced redox reaction and better catalytic activity of the prepared perovskite [70]. As well, a dramatic change in the transport and magnetic properties of the ABO3 perovskite can be achieved upon doping the B-site due to an ionic valence effect and/or an ionic size effect [64]. Furthermore, upon doping the B-site in ABO3 perovskites with transition metals especially noble metals, the stability of the perovskite was improved and the catalytic activity was enhanced greatly [71]. In addition, the incorporation of two different B ions with appropriate various charge and size may be altered the simple perovskite structure. If the two ions in B-site were used with equimolar amounts, the resulted perovskite can be represented as AB0.5B′0.5O3 with unit cell appearing as doubled along the three axes. In addition, if B and B′ have different charges, there is a slight shift of the oxygen toward the highly charged ion in the ordered structure although the octahedral symmetry of B and B′ cations is maintained [5]. Different B-sites doped perovskites were mentioned in the literature showing enhanced catalytic properties like LaNixCo1-xO3 [72], LaB0.9Pd0.1O3 [73], LaMn1−xPdxO3 [74], BaFe1−xYxO3−δ [75], BaFe0.85Cu0.15O3−δ [76], LaNi1-xFexO3 [77], LaFe0.95-xCoxPd0.05O3 [78] and LaCo0.95Pd0.05O3 [79]. On the other hand, (La1-xSrx)yMnOδ [80], La1-xCexGaO3, La1-xPrxGaO3 and La1-xNdxGaO3 [81], La1-xCaxMnO3 [82], La1-xNaxMnO3+δ, La1-xCaxMnO3+δ [83], (Ba0.93Fe0.07)TiO3 [84], La1-xSrxNiO3, and La1-xSrxMnO3 [85] are examples of A-site doped perovskites.

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4. Characterization of perovskites

X-ray powder diffraction (XRD) can be used to differentiate the different phases of the prepared perovskites. Single-crystal XRD is another analysis used to characterize the structure of the perovskite. Thermal stability of the prepared perovskites can be tested using thermal analysis techniques like TGA, DTA, and DSC. On the other hand, scanning (SEM) and transmission (TEM) electron microscopies can be utilized to identify the different morphological and surface characteristics of the prepared perovskites. Also, BET can be utilized for surface area measurement. In addition, Fourier transform infrared spectroscopy (FTIR) and X-ray photoelectron spectroscopy (XPS) can be used to completely identify the formed phases [10, 8688].

4.1. XRD

XRD can be used for the phase identification and the relative percents of different phases of the prepared materials. Also, some structural parameters like particle size, lattice parameters (a, b, and c), lattice volume, and theoretical density can be calculated from the XRD data. Also, XRD can be used to optimize the preparation conditions of the different perovskites [3, 8789]. Galal et al. prepared SrPdO3 by citrate/nitrate combustion method at different pH values; 2, 7, and 10 at calcination temperature 750 °C for 3 h and the XRD patterns of these samples were shown in Figure 3A. The XRD data were compared with the ICCD card of SrPdO3 (card number 00-025-0908). For pH 2, the experimental data and the theoretical one are well matched and supported the formation of the primary orthorhombic perovskite phase of SrPdO3 (the major diffraction peak 110) and the appearance of secondary phase SrPd3O4 (210). Only SrPd3O4 phase appeared in case of samples prepared at pH 7 and 10 as (110) peak disappeared. Therefore, pH 2 was the optimal pH for SrPdO3 preparation. Also, the type of fuel (citric acid, urea, and glycine) used in the preparation of SrPdO3 can be optimized using XRD (Figure 3B). SrPdO3 was the primary phase in all cases but with different percents of SrPdO3 (110) with respect to SrPd3O4 (210). The high percent was in case of urea and the small one in case of citric acid. Some structural parameters were calculated and summarized in Table 3 with good matching with theoretical data.

Figure 3.

XRD patterns of SrPdO3 prepared by combustion method at different pH values (A) and different fuels (B). Miller indices (h, l,k) are written in black line for SrPdO3, red line for SrPd3O4 and the symbol (*) for SrCl2. 6H2O [89].

Lattice
Structure
Particle
Size (nm)
Lattice
Parameters
(A˚)
Lattice
Volume
(˚A3)
Theoretical
density
(g/cm3)
Standard
SrPdO3
(ICCD card; 00-025-0908)
Orthorhombic a = 3.977
b = 3.530
c = 12.82
179.98 4.47
citrate-nitrate method Orthorhombic 34.0 a = 3.983
b = 3.541
c = 12.80
180.59 4.45
urea-nitrate method Orthorhombic 45.4 a = 3.954
b = 3.563
c = 12.82
180.63 4.45
glycine-nitrate method Orthorhombic 25.7 a = 3.972
b = 3.527
c = 12.83
179.69 4.47

Table 3.

Structural parameters calculated from XRD data [89].

4.2. SEM and TEM

SEM and TEM can be used to study the morphology and surface characteristics of the perovskite nanomaterials. The preparation conditions, synthesis method, type of A- and B-site metal ions, and doping A- and/or B-sites affected greatly the SEM of the prepared perovskites [8894]. Galal et al. prepared LaNiO3, LaCoO3, LaFeO3, and LaMnO3 by the microwave-assisted citrate method at 720 W as operating power for 30 min under microwave irradiation. The SEM images for the different perovskites were shown in Figure 4 presenting different morphologies depending on the kind of metal ion at B-site, respectively. LaNiO3 showed compact surface with high degree of ordering while LaCoO3 and LaMnO3 showed spherical grains agglomerations with smaller grain size in case of LaMnO3. LaFeO3 showed dissimilar morphology with a porous surface containing particles with bonelike shape. In addition, LaFeO3 presented greater electrocatalytic activity toward hydrogen evolution reaction compared to other types of perovskites [90].

Furthermore, the high-resolution TEM (HRTEM) can be used to show the different morphologies and particle characteristics of the different perovskites [86, 88, 95]. HRTEM images for LaNiO3, LaCoO3, LaFeO3, and LaMnO3 by the microwave-assisted citrate method were shown in Figure 5, respectively. The HRTEM images clearly showed orthorhombic phase with high crystallinity in case of LaFeO3, while HRTEM images of LaNiO3, LaCoO3, and LaMnO3 showed hexagonal distorted rhombohedral phases. The diffraction patterns obtained via HRTEM for the different perovskites were comparable with the XRD data [86, 95].

Figure 4.

SEM micrographs of (A) LaNiO3, (B) LaCoO3, (C) LaFeO3 and (D) LaMnO3 prepared by the microwave-assisted citrate method at 720 W for 30 min, with a magnification of 35,000 times [90].

Figure 5.

HRTEM micrographs of (A) LaNiO3, (B) LaCoO3, (C) LaFeO3 and (D) LaMnO3 prepared by the microwave-assisted citrate method at 720Wfor 30 min [86].

4.3. BET

The electrochemical performance and electrocatalytic activity of the perovskites are greatly associated with the specific surface area of the materials; therefore, it is necessary to measure the specific surface area of the prepared materials. The surface area values of different perovskites can be measured by Brunauer–Emmett–Teller (BET) nitrogen adsorption. The preparation conditions, synthesis method, type of A- and B-site metals, and presence of different dopants can greatly affect the surface area of the prepared perovskites [86, 87, 95]. Biniwale et al. prepared LaFeO3 via different methods, namely, sol-gel, combustion, and coprecipitation and measured the corresponding surface area and the average pore diameter of the prepared perovskites. The order of decreasing the surface area of the prepared LaFeO3 was sol-gel (16.5 m2 g–1) > combustion (9.3 m2 g–1) > coprecipitation method (5.4 m2 g–1). The order of increasing the average pore diameter of the prepared LaFeO3 was sol-gel (119 °A) < coprecipitation method (140 °A) < combustion (205 °A). Sol-gel and combustion methods resulted in porous surface with internal pores contributing to higher surface area, while coprecipitation method resulted in less internal pores and lower surface area due to longer calcination time [87].

4.4. Thermal analysis

Thermal analysis can be utilized to identify the thermal stability and the decomposition temperature of the prepared perovskites. The optimum calcination temperature of any perovskite can be identified using thermal analysis [88, 96, 97]. Galal et al. prepared SrPdO3 for the first time, and its optimum calcination temperature was investigated using TGA and DTG of the citrate complex of Sr and Pd (Figure 6A). The breakdown of the citrate complex occurs at ~330 °C through a smooth weight loss step. SrPdO3 formation was achieved at ~750 °C through a sharp weight loss step [96].

Figure 6.

(A) TG spectrum of Sr and Pd mixed citrate complex, heating rate was 10 °C min−1 [27] and (B) FTIR spectra for LaFeO3 synthesized using (a) co-precipitation method, (b) combustion method and (c) sol–gel method [87].

4.5. FTIR

The chemical bonding and chemical structure of the prepared perovskites can be investigated via FTIR. The FTIR can give structural confirmation similar to that obtained via XRD [87, 97100]. Biniwale et al. prepared LaFeO3 via different methods: sol-gel, combustion, and coprecipitation, and the FTIR for them was shown in Figure 6B [87]. The FTIR of LaFeO3 showed an absorption band at 558 cm–1 related to the stretching vibration mode of Fe-O. Another band appeared at 430 cm–1 was related to the deformation vibration mode of O-Fe-O. LaFeO3 prepared via coprecipitation method showed a sharp band at 3609 cm–1, which is related to La-O in lanthanum oxide. In case of the other two methods, the band at 3600 cm–1 disappeared indicating the formation of relatively pure perovskite phase. Other bands appeared at 1360 and 1480 cm–1, indicating other phases in case of coprecipitation method. As a result and as mentioned in literature, the absorption peak around 558 cm–1 was related to the stretching modes of metallic oxygen bond [87, 97100].

4.6. XPS

The surface compositions of the various components of the prepared perovskites can be identified via XPS [101106]. Lee et al. prepared La0.9FeO3 and LaFeO3 samples and identify their structural composition via XPS analysis [102]. Figure 7 showed the XPS spectra of La (3d), Fe (2p), and O (1s) in La0.9FeO3 and LaFeO3 samples. The binding energy of La (3d5/2) was 833.5 eV and 833.8 eV in case of LaFeO3 and La0.9FeO3, respectively, corresponding to the La3+ ions in the form of oxide. By contrast, the binding energy of Fe (2p3/2) was 710.2 eV for both samples corresponding to Fe3+ ions in the form of oxide. The Fe (2p) XPS signal cannot distinguish between Fe3+ and Fe4+. The XPS signal of O (1s) was divided into two peaks in case of La0.9FeO3 appearing at 529.9 and 532.1 eV. While for LaFeO3, O (1s) XPS signal was divided into three peaks appearing at 529.4, 531.9, and 534.4 eV. The O (1s) binding energy values at 529.9 and 529.4 eV in both samples are attributed to lattice oxygen species. The peaks at 532.1 and 531.9 eV are ascribed to the chemisorbed oxygen species as OH¯ or O¯. The chemisorbed oxygen species appeared at binding energy higher than that of lattice oxygen species by 2.1–2.5 eV. The peak appeared at 534.4 eV in case of LaFeO3 was ascribed to the adsorbed water species associated with the surface lanthanum oxide which is highly hygroscopic [102].

Figure 7.

XPS spectra of La(3d), Fe(2p) and O(1s) in La0.9FeO3 and LaFeO3 samples [102].

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5. Applications of perovskites

Inorganic perovskite-type oxides exhibited attractive physical and chemical characteristics such as electronic conductivity, electrically active structure, the oxide ions mobility through the crystal lattice, variations on the content of the oxygen, thermal and chemical stability, and supermagnetic, photocatalytic, thermoelectric, and dielectric properties. They are fascinating nanomaterials for wide applications in catalysis, fuel cells, and electrochemical sensing. The catalytic activity of these oxides is higher than that of many transition metals compounds and even some precious metal oxides.

Nanoperovskites are recently utilized in electrochemical sensing of alcohols, gases, amino acids, acetone, glucose, H2O2, and neurotransmitters exhibiting good selectivity, sensitivity, unique long-term stability, excellent reproducibility, and anti-interference ability. Moreover, they have been utilized as catalysts in oxygen reduction and hydrogen evolution reactions exhibiting high electrocatalytic activity, lower activation energy, and high electron transfer kinetics. In addition, some perovskites are promising candidates for the development of effective anodic catalysts for direct fuel cells showing high catalytic performance.

5.1. Sensors and biosensors

5.1.1. Gas sensors

There are a number of requirements that the materials utilized as gas sensors must satisfy, namely, good resemblance with the target gases, manufacturability, hydrothermal stability, convenient electronic structure, resistance to poisoning, and adaptation with existing technologies. There is a wide variety of materials that can be used as gas sensors like semiconductors, namely, SnO2, In2O3, and WO3, and perovskite oxides, namely, LaFeO3 and SrTiO3. Perovskite oxides are fascinating materials as gas sensors due to their perfect thermal stability, ideal band gap “3–4 eV,” and difference in size between the cations of A- and B-sites, allowing different dopants addition for controlling semiconducting properties and their catalytic properties. Perovskites including titanates, ferrites, and cobaltates were utilized as gas sensors for detecting CO, NO2, methanol, ethanol, and hydrocarbons [107110]. LaCoO3 prepared via high-energy ball milling exhibited the highest amount of grain boundaries, the best CO gas sensing properties, and the smallest crystallite size of 11 nm compared to that prepared via solid-state and sol-gel reactions. The maximum response ratio increased to 26% in case of milling method with maximum response ratio temperature of 125 °C compared to 7% and 17% in case of solid-state reaction and sol-gel method. In addition, the specific surface area increased greatly from 4 m2 g–1 to 66 m2 g–1 by extra milling step, and the mobility of the oxygen was enhanced by growing the extra milling step and surface area [107]. A summary of various perovskite oxides for different gas sensing was given in Table 4.

Perovskite Sensing for Response
ratio %
Oxide type Reference
LaCoO3 CO 75% for 100 ppm CO in dry air at 125 ◦C p-type [107]
La0.9Ce0.1CoO3 CO 240 % with respect to 100ppm
CO in air
p-type [108]
NdFe1–xCoxO3 CO 1215% at 170 ºC for 0.03% CO gas When x<0.3; p-type conduction behavior, when x > 0.3; n-type. [109]
La0.8Pb0.2Fe0.8Cu0.2O3 CO Not reported p-type [111]
La0.8Pb0.2FeO3 methanol 146.6 at 230 ◦C for 400 ppm methanol p-type [112]
LaFeO3 ethanol Not reported p-type [113]
LaMg0.1Fe0.9O3 ethanol Not reported p-type [114]
SrFeO3 ethanol Not reported p-type [115]
SmFe0.9Mg0.1O3 ethanol Not reported p-type [116]
LaMnO3 ethanol Not reported Not reported [117]
La0.875Ba0.125FeO3 ethanol sensitivity to 500 ppm ethanol is 58 at 170 °C p-type [118]
CaxLa1-xFeO3 ethanol Not reported Not reported [119]
LaCo0.1Fe0.9O3 ethanol Not reported p-type [120]
LaFeO3 ethanol Not reported p-type [121]
La1−xPbxFeO3 ethanol 80% for 100 ppm in a
wide temperature range of 140–240 ◦C
x = 0.30; p-type,
x = 0.32–0.50; n-type
[122]
LaFeO3 and SmFeO3 NO2, CO Not reported p-type [123]
LaFeO3 NO2 Not reported Not reported [124]
LaFeO3 NOx Not reported Not reported [125]
SrTi1−xFexO3−δ hydrocarbons Not reported p-type [126]
LnFeO3 (Ln = La, Nd and Sm) hydrocarbons Not reported p-type [127]

Table 4.

A summary of different perovskites for gas sensing.

5.1.2. Glucose sensor

It is very important to analytically determine H2O2 and glucose in many fields like food, clinic, and pharmaceutical analyses. H2O2 is considered one of the most important oxidizing agents in chemical and food industries. Glucose is a fundamental metabolite for most of the living organisms and for the clinical examination of diabetes mellitus, a worldwide health problem. As a result, it is very important to construct biosensors for the sensitive determination of H2O2 and glucose [128137]. Different types of enzymatic glucose sensors were constructed and used in the literature exhibiting the advantages of simplicity and sensitivity. However, enzymatic glucose sensors suffered from the lack of stability and the difficult procedures required for the effective immobilization of enzyme on the electrode surface. The lack of enzyme stability was attributed to its intrinsic nature because the enzyme activity was highly affected by poisonous chemicals, pH, temperature, humidity, etc. As a result, most attention was given for sensitive, simple, stable, and selective nonenzymatic glucose sensor. Different novel materials were proposed for the electrocatalytic oxidation of glucose like noble nanometals, nanoalloys, metal oxides, and inorganic perovskite oxides. Inorganic perovskite oxides as nanomaterials exhibited fascinating properties for glucose sensing like ferroelectricity, superconductivity, charge ordering, high thermopower, good biocompatibility, catalytic activity, and the ability of the perovskite structure to accommodate different metallic ions [128137]. Zhen Zhang et al. utilized carbon paste electrode modified with Co0.4Fe0.6LaO3 as a promising nonenzymatic H2O2 and glucose sensor. This sensor displayed perfect electrocatalytic activity toward H2O2 and glucose oxidation in alkaline medium due to the presence of large amount of active sites in the modifier. The linear dynamic range for H2O2 at this surface was 0.01 to 800 μM with low detection limit of 2.0 nM. For glucose, two ranges were obtained from 0.05 to 5 μM and from 5 to 500 μM with detection limit of 10 nM. The proposed sensor exhibited rapid response, excellent long-term stability, and anti-interference ability toward ascorbic acid, uric acid, and dopamine [132]. Furthermore, Atta et al. have recently modified SrPdO3 perovskite with a film of gold nanoparticles to be utilized as a nonenzymatic voltammetric glucose sensor. The studied sensor exhibited high electrocatalytic activity toward glucose oxidation exploring the effective synergism between SrPdO3 and gold nanoparticles. SrPdO3 perovskite facilitated the charge transfer process and acted as an effective supporting substrate for gold nanoparticles. The catalytic activity of SrPdO3 was attributed to the deficiency of the surface for oxygen which resulted in enhanced intrinsic reactivity toward glucose oxidation. Another reason for the catalytic activity of SrPdO3 was the matrix effect induced by the stable crystal structure of the perovskite where there is a homogenous distribution of Pd4+ cations in the inert matrix of the perovskite during the reaction. This nanocomposite showed good performance toward glucose sensing in terms of highly reproducible response, high sensitivity, wide linearity, low detection limit, good selectivity, long-term stability, and applicability in real urine samples and blood serum [137]. A summary of different types of perovskites used for enzymatic and nonenzymatic H2O2 and glucose sensing was given in Table 5, exhibiting high sensitivity, wide linear range, low detection limit, anti-interference ability, applicability in real samples, and long-term stability.

Perovskite Sensing for Sensor type Detection limit Sensitivity Reference
graphite/SrPdO3/Aunano glucose Non-enzymatic 10.1 μmol L-1 422.30 μA/
mmolL-1
[137]
LaTiO3-Ag0.1 glucose Non-enzymatic 2.50 × 10−9 M 7.80 × 102
µA mM−1cm−2
[128]
LaNi0.5Ti0.5O3/CoFe2O4 H2O2 Non-enzymatic 23 nM 3.21 µA µM−1 cm−2 [129]
LaNi0.6Co0.4O3 H2O2 and glucose Non-enzymatic 1 nM H2O2
8 nM glucose
1812.84 µA mM−1 cm−2 for H2O2 and 643.0 µA mM−1 cm−2 for glucose [130]
CPE–La0.66Sr0.33MnO3–GOx (glucose oxidase) glucose Enzymatic Not reported 158.1 µAmol−1 L [131]
Co0.4Fe0.6LaO3 H2O2 and glucose Non-enzymatic 2 nM H2O2 and
10 nM glucose
Not reported [132]
LaTiO3–Ag0.2 glucose Non-enzymatic 2.1×10−7 M 784.14
µA mM−1 cm−2
[133]
LaNi0.5Ti0.5O3–NiFe2O4 glucose Enzymatic 0.04 mM Not reported [134]
La0.6Ca0.4Ni0.7Fe0.3O3 H2O2 Non-enzymatic Not reported Not reported [135]
La0.5Sr0.5CoO3-δ H2O2 Non-enzymatic Not reported Not reported [136]
La0.7Sr0.3NiO3 /chitosan/GCE H2O2 Enzymatic 9.0×10-8 mol/L Not reported [138]
LaNiO3 H2O2 and glucose Non-enzymatic 33.9 nM H2O2 Not reported [139]

Table 5.

A summary of different perovskites for H2O2 and glucose sensing.

5.1.3. Neurotransmitters sensor

Dopamine (DA) is an essential catecholamine neurotransmitter that exists in the mammalian central nervous system. The depletion of DA can lead to Parkinson’s disease; therefore, its determination is very crucial. The interference of ascorbic acid (AA) and uric acid (UA) with DA is the major problem in DA detection [89, 140143]. Therefore, it is very important to present a modified surface which can be sensitively and selectively detect DA even in presence of high concentration of AA and UA. Atta et al. presented carbon paste electrode modified with SrPdO3 (CpE/SrPdO3) as a promising electrochemical DA sensor in biological fluids with unique long-term stability and low detection limit of 9.3 nmol L−1. CpE/SrPdO3 can simultaneously detect DA in the presence of high concentrations of AA and UA and can successfully detect DA in human urine samples with excellent recovery results in terms of selectivity, accuracy, precision, and detection limit. The proposed sensor showed high sensitivity, good selectivity, and anti-interference ability [89]. Moreover, higher response toward DA oxidation was achieved at CpE/SrPdO3 compared to electrodeposited palladium nanoparticles modified CpE (CpE/Pd) with equivalent loading of Pd4+ salt. The higher catalytic activity at CpE/SrPdO3 was explained in terms of the oxygen–surface interaction between the oxygen atoms of the hydroxyl groups and the transition element in the perovskite. One characteristic of perovskite is the deficiency of its surface for oxygen. As a result, the “dihydroxy”-oxygen adsorb onto perovskite surface with the formation of a “moderate” bond between oxygen atoms and the transition element in the oxide [89]. Furthermore, the descriptor that controls the catalytic process in perovskites is the type of transition metal in the perovskite, which is related to the number of occupied d orbital states of a specific symmetry, for example, of the active metal. This is associated with the surface ability to bond oxygen on the basis of the calculations of the density functional theory. Therefore, the oxygen adsorption energy represented a perfect descriptor for the oxidation of DA at CpE/SrPdO3. A summary of different perovskites used for neurotransmitters sensing was given in Table 6.

Perovskite Sensing for Linear dynamic range Detection limit (nM) Reference
LaFeO3 microspheres made up of nanospheres DA 2 ×10-8 – 1.6 × 10-6 M 59 [140]
CpE/SrPdO3 DA 7 – 70 µmol L−1 9.3 [89]
Graphite/SrPdO3 L-dopa
EP, NE, DA, DOPAC and ST
0.6 – 9 μmol L−1 1.63 [141]
LaFeO3 nanostructure dendrites DA 8.2 × 10−8 – 1.6 × 10−7 M 62 [142]
LaFeO3 nanoparticles DA 1.5×10−7 – 8.0×10−4 M 30 [143]

Table 6.

A summary of different perovskites for neurotransmitters sensing.

5.2. Solid oxide fuel cells

Fuel cells have come into view as efficient alternatives to combustion engines due to their potential to minimize the environmental influence of the use of fossil fuels. A fuel cell uses certain type of chemical fuel as its energy source, and there is a direct transformation of chemical energy into electrical energy like a battery. Fuel cells are attractive because of their great efficiency, modular and distributed nature, low emissions, zero noise pollution, and role in any future hydrogen fuel economy. There are several types of fuel cells depending on operating temperature, fuel type, electrolyte type, and mobile ions. Polymer electrolyte membrane fuel cells, molten carbonate, phosphoric acid or alkali fuel cells, and solid oxide fuel cell are the most common examples of fuel cells [144]. Table 7 contained some fuel cells types and some selected features [144]. Here we will concern on solid oxide fuel cells. Solid oxide fuel cells (SOFCs), based on conducting electrolyte in the form of an oxide-ion, can generate electricity and heat and they are considered as energy-saving, environment-friendly, and effective energy conversion devices. SOFCs exhibited several features compared to the other types of fuel cells like high-energy conversion efficiency, cheap materials, low sensitivity to the fuel impurities, low pollution emissions, environmental compatibility, and excellent fuel flexibility [145160]. Figure 8 showed the working principle of a solid oxide fuel cell [157]. The high temperature of SOFC operation resulted in the difficult choice of the proper materials and the decreased cell durability. Thus, providing materials for SOFCs with good performance at intermediate temperatures (500–800 °C) is very essential so that the cell cost and the startup and shut down time can be reduced and its long-term stability can be improved [148, 155]. Perovskite oxides exhibited fascinating properties like good electrical conductivity similar to that of metals, high ionic conductivity, and perfect mixed ionic and electronic conductivity. Depending on the differences in the electrical conductive characteristics of perovskites, they are chosen as an effective component in SOFC [9]. In addition, mixed-conduction perovskite oxides possess beneficial electrochemical reaction; structural, thermal, and chemical stabilities; high electrical conductivity; high catalytic activity toward the oxygen reduction; and ideal mixed electronic and ionic conductivities to be used as effective component for intermediate temperatures SOFC (IT-SOFC) [147160]. Shao and Haile utilized Ba0.5Sr0.5Co0.8Fe0.2O3-δ as an effective cathode for intermediate SOFC with the fuel of humidified H2 and the cathode gas of air. This cathode exhibited 1010 and 402 mW cm–2 as the maximum power density at 600 and 500 °C, respectively [145]. On the other hand, Goodenough reported the use of double perovskite Sr2MgMnMoO6-δ as an anode material for SOFC with dry methane as the fuel and 438 mW cm–2 as the maximum power density at 800 °C. This anode material showed long-term stability, stability in reducing atmosphere, tolerance to sulfur, and characteristic of oxygen deficiency [161]. Table 8 contained a summary of different perovskites used as anode and cathode for SOFC illustrating the fuel type, the operating temperature, and the maximum power density.

Figure 8.

Schematic diagram showing the working principle of a solid oxide fuel cell [157].

Type Temperature °C Fuel Electrolyte Mobile ion
PEM: polymer electrolyte membrane or proton exchange membrane 70–110 H2, methane Sulphonated polymer (Nafion) (H2O)nH+
AFC: Alkali fuel cell 100–250 H2 Aqueous KOH OH¯
PAFC: Phosphoric acid fuel cell 150–250 H2 H3PO4 H+
MCFC: Molten carbonate fuel cell 500–700 Hydrocarbons, CO (Na, K)2CO3 CO3 2-
SOFC: Solid oxide fuel cell 700–1000 Hydrocarbons, CO (Zr, Y)O2-δ O2-

Table 7.

Fuel cell types and selected features [144].

Perovskite Anode/cathode in the cell Fuel used Operating temperature °C Maximum power density
mW cm-2
Reference
Ba0.5Sr0.5Co0.8Fe0.2O3-δ Cathode Humidified H2 (~3% H2O) 600
500
1010
402
[145]
Ba0.5Sr0.5Co0.2Fe0.8O3-δ Cathode Humidified H2 800 266 [147]
La0.7Sr0.3Co0.5Fe0.5O3 Cathode Not reported Not reported Not reported [148]
La0.6Sr0.4Fe0.8Co0.2O3 Cathode glycerol 800 Not reported [149]
LaBaCuFeO5+x Cathode Humidified H2 700
550
327
105
[150]
LaBaCuCoO5+x Cathode Humidified H2 700
550
432
171
[150]
Y0.8Ca0.2BaCoFeO5+δ Cathode Humidified H2 650 426 [151]
NdFeO3 anode sulfur vapor or SO2 620
650
0.154
0.265
[153]
Sm0.5Sr0.5CoO3-δ cathode Not reported 700 936 [158]
Sr2Fe1.4Mo0.6O6−ı cathode H2 or methanol Not reported Not reported [159]
La0.75Sr0.25Cr0.5Mn0.5O3 anode methane Not reported Not reported [162]
Sr2MgMnMoO6-δ anode dry methane 800 438 [161]
La0.8Sr0.2Cr0.97V0.03O3 anode dry methane 800 Not reported [163]

Table 8.

A summary of different perovskites for SOFC.

5.3. Catalyst

Perovskite oxides can be widely used as catalyst in modern chemical industry, exhibiting appropriate solid-state, surface, and morphological properties [6]. Several perovskites exhibited enhanced catalytic activity toward different reactions like hydrogen evolution and oxygen evolution and reduction reactions [9].

5.3.1. Hydrogen evolution reaction

Because of the advantages of high heat of combustion, abundant sources, and no pollution, hydrogen is considered as an ideal fuel. Hydrogen evolution reaction (HER) is a fascinating reaction in the renewable energy field. This reaction is very important in (i) metal electrodeposition and corrosion in acids, (ii) storage of energy through production of hydrogen, and (iii) as the hydrogen oxidation reaction reverse in low-temperature fuel cells. One of the most studied reactions in electrochemistry is the electrocatalysis in HER. The material used for HER should have (i) intrinsic electrocatalytic activity, (ii) considerable active surface area per unit volume, and (iii) good stability. To reduce the cost of electrolytic HER, the overpotential required for the operation of the electrolyzer at considerable current densities should be reduced. The overpotential reduction can be achieved through the electrode active surface area enhancement or by the selection of electrode materials of high catalytic activity. The steps of the reaction in acidic solutions are as follows:

M + H3O++eMHads+ H2OE1
MHads+ H3O++eH2+ M + H2OE2
MHads+ MHadsH2+ 2ME3

The first step in HER is the proton discharge (volume reaction, Eq. (1)), which is followed by electrodesorption step (Heyrovsky reaction, Eq. (2)) or proton recombination step, physical desorption, (Tafel reaction, Eq. (3)) [93]. Galal et al. confirmed the high catalytic activity of different perovskite oxides toward hydrogen evolution reaction [9094, 96]. LnFeO3 perovskites (Ln= Gd, La, Sm, and Nd) were prepared by the microwave assistant-citrate method, and single-phase perovskites were formed with uniform distribution of small average particle size. Tafel and electrochemical impedance measurements were used to study the catalytic activity of LnFeO3 toward HER showing the effect of the type of the lanthanide ion on HER and the partial substitution effect at the La-site in La1-ySmyFeO3. The order of decreasing the catalytic activity toward HER was NdFeO3 > LaFeO3 > SmFeO3 > GdFeO3 based on activation energies calculations and the strength of Fe-O bond, which is related to A-type metal ion. Furthermore, the order of decreasing the catalytic activity in case of doped samples was La0.75Sm0.25FeO3 > La0.5Sm0.5FeO3 > La0.25Sm0.75FeO3 > LaFeO3 > SmFeO3 displaying greater catalytic activity of ternary perovskites compared to that of binary ones [94]. On the other hand, Galal et al. prepared SrPdO3 by the citrate method for the first time showing enhanced catalytic activity toward HER up to 100 times with respect to the unmodified surface with 27.9 kJ mol−1 as the calculated activation energy. The rate-determining step was the hydrogen adsorption on the catalyst and the order of the reaction at the catalyst surface was 0.86 [96]. Table 9 contained a summary of different perovskites used as catalysts for HER with the values of exchange current density at constant overpotential, activation energy, reaction order, and the rate-determining step.

Perovskite Exchange current density
j/ μA.cm-2
Activation energy
kJ mol-1
Reaction order Rate determining step Reference
NdFeO3 -107.82 24.68 0.72 adsorption of hydrogen on the catalyst [94]
LaFeO3 -367.37 41.15 0.37 adsorption of hydrogen on the catalyst [94]
SmFeO3 -147.23 57.89 0.41 adsorption of hydrogen on the catalyst [94]
GdFeO3 -451.86 81.37 0.72 adsorption of hydrogen on the catalyst [94]
La0.75Sm0.25FeO3 Not reported Not reported Not reported adsorption of hydrogen on the catalyst [94]
SrPdO3 −946.3 27.9 0.86 adsorption
of hydrogen on the catalyst
[96]
LaFeO3 −105.6 51.61 0.37 adsorption of hydrogen [90]
LaCoO3 −348.9 45.37 0.74 adsorption of hydrogen [90]
LaNiO3 −158.5 41.15 0.94 adsorption of hydrogen [90]
LaMnO3 −41.9 55.05 0.87 adsorption of hydrogen [90]
SrRuO3 (microwave) −5326.0 6.67 1.14 adsorption of hydrogen [92]
SrRuO3 (sol-combustion) −425.5 49.45 0.98 adsorption of hydrogen [92]
SrRuO3 (coprecipitation) −298.0 86.32 0.88 adsorption of hydrogen [92]
CaRuO3 (coprecipitation) -1064.9 42.60 0.94 adsorption of hydrogen [93]
BaRuO3 (coprecipitation) -3687.2 17.68 1.03 adsorption of hydrogen [93]

Table 9.

A summary of different perovskites for HER catalysis.

5.3.2. Oxygen reduction and oxygen evolution reactions

Oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) are considered one of the most important electrode reactions in many industrial processes like fuel cells, metal electrowinning, water electrolysis, electro-organic synthesis, cathodic protection, and rechargeable metal air batteries [95, 164166]. Platinum-based catalysts and precious metal oxides are the most common catalysts for ORR or OER, but they are expensive and scarce. Therefore, it is very important to develop other catalysts for ORR or OER. Mixed metal perovskite oxides of transition and rare earth metals are promising low-cost alternatives to precious metal catalysts for both ORR and OER [165]. Perovskite oxide exhibited unique electronic and magnetic properties, defective structure, and good cation ordering resulting in disorder-free channels of oxygen vacancies and enhanced mobility of oxygen ions [164]. Some perovskite oxides were reported as electrocatalysts for ORR and OER and summarized in Table 10 [95, 164166]. Ruizhi Yang et al. prepared Ba0.5Sr0.5Co0.8Fe0.2O3 by sol-gel method and utilized it as ORR or OER catalyst in basic medium of KOH. The proposed catalyst exhibited higher catalytic activity toward OER than the unmodified electrode [164]. Furthermore, Galal et al. prepared LaFeO3 by microwave-assisted citrate method and studied its catalytic activity toward OER in acid medium of HClO4. LaFeO3 exhibited greater electrocatalytic activity toward OER by about 100-folds compared to the unmodified electrode. The current density at 1.5 V increased from 3.6 × 10−5 in case of unmodified electrode to 1.2 × 10−3 A/cm2 in case of modified one. The calculated activation energy was 20 kJ/mol, which is much lower than that reported for other iron compounds and even some precious metal oxides like RuO2. This was attributed to the matrix effect induced by the stable crystal structure of the perovskite [95]. In addition, La0.6Ca0.4CoO3, prepared by the sol-gel method, showed high catalytic activity and relative stability toward oxygen electrochemistry in basic medium of KOH. La0.6Ca0.4CoO3 exhibited single-phase perovskite structure, high conductivity, and large surface area [165, 166].

Perovskite Medium Exchange current density
mA.cm-2
Activation energy
kJ mol-1
Reaction order Rate determining step Reference
LaFeO3 HClO4 1.24×10−5 20.13 0.82 Difficult to be determined [95]
Ba0.5Sr0.5Co0.8Fe0.2O3 KOH Not reported Not reported Not reported Not reported [164]
La0.6Ca0.4CoO3 KOH Not reported Not reported Not reported Not reported [165]
La1-xCaxCoO3 series
(0 < x < 0.6)
KOH Not reported Not reported Not reported Not reported [166]

Table 10.

A summary of different perovskites for ORR or OER catalysis.

5.4. Solar cells

Solar energy is a green source of energy that can be used instead of energy sources based on fossil fuels. Solar radiation can be directly converted into electrical energy in a suitable way creating various applications for solar energy. Solar energy can be efficiently converted into electricity using photovoltaic solar cells based on silicon. The obvious disadvantage of silicon-based solar cell is the high price of electricity generated from it so that there is a potential need to develop solar cell with low cost. Recently, attention was paid to solar cells based on organic/inorganic solid-state methylammonium lead halide (CH3NH3PbX3, X=Br, I) hybrid perovskite. This type of solar cells presented effective points such as a conversion efficiency of about 20%; its cost is lower than that of conventional silicon solar cells and the availability of the raw materials. These 3D organometal halide perovskite exhibited excellent intrinsic properties for photovoltaic applications like excellent stability, appropriate band gap (~1.55 eV), high absorption coefficient (1.5 × 104 cm–1 at 550 nm), long hole-electron diffusion length (~100 nm for CH3NH3PbI3 and ~1 μm for CH3NH3PbI3-xClx), high carrier mobility and transport, charge carriers with small effective mass, low temperature of processing, and easy processing steps [167179]. Figure 9A showed the structure of ABX3 perovskite (X = oxygen, carbon, nitrogen or halogen), where A and B cations are placed in a cubo-octahedral and an octahedral site, respectively. A is usually divalent and B is tetravalent when O2– anion is used. On the other hand, Figure 9B showed the structure of CH3NH3PbI3 halide perovskite where the A-site is occupied by CH3NH3+ (organic component) and B-site cation is occupied by Pb2+. As indicated by the example, halide perovskites contain monovalent and divalent cations in A- and B-sites, respectively, to maintain electrical neutrality [169, 171]. Like oxide perovskite, the tolerance factor of halide perovskite should be as close to one to maintain a stable and symmetrical crystal structure [169].

Figure 9.

(a) ABX3 perovskite structure showing BX6 octahedral and larger A cation occupied in cubo-octahedral site. (b) Unit cell of cubic CH3NH3PbI3 perovskite [171].

The quality of the perovskite film is very crucial for solar cells. Several methods have been used to form perovskite films with high quality such as single step solution method, vapor assistant solution process, sequential deposition of inorganic and organic precursor, and coevaporation of the precursors [167]. CH3NH3PbI3 perovskite film was prepared with high quality by adding small amounts of N-methyl-2-pyrrolidone and a mixture of g-butyrolactone and dimethylsulfoxide via a solution method. A power conversion efficiency of 11.77% with fill factor of 80.52% was obtained based on the structure of ITO/PEDOT:PSS (poly(3,4-ethylenedioxythiophene):polystyrenesulfonate)/perovskite/ PCBM (fullerene-derivative phenyl-C61-butyric acid methyl ester)/Ca/Al under one sun illumination (100 mW cm–2) [167]. Table 11 contained a summary of different models based on perovskites used for solar cells applications with the values of power conversion efficiency, fill factor, method of perovskite formation, solar cell composition, cost, and stability.

Solar cell composition Perovskite formation Power conversion efficiency Fill factor Cost Stability Reference
ITO/PEDOT:PSS/
CH3NH3PbI3 perovskite/
PCBM/Ca/Al
Solution method 11.77 % 80.52 % low highly stable [167]
conducting polymer (poly-aniline) CH3NH3PbI3 perovskite Solution method 21 % Not reported low Not reported [168]
Mesoporous TiO2/CH3NH3PbI3/
graphite paste
Solution method 1.11 % 44.5 % low slightly stable [174]
Ti foil/TiO2 nanotubes (TNTs) with organic– inorganic halide perovskite absorber “CH3NH3PbI3” and transparent carbon nanotube electrode Solution method 8.31 % 64 % low highly stable [175]
ITO/conductive-polymer/CH3NH3PbI3/C60/BCP/Ag Solution method 16.5 % 75 % low highly stable [177]
glass/ITO/RGO/CH3NH3PbI3/PC61BM/bathocuproine (BCP)/Ag Solution method 10.8 % 71.6 % low highly stable [179]

Table 11.

A summary of different models based perovskites for Solar cells applications

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6. Conclusions

Inorganic perovskite-type oxides are excellent nanomaterials for wide applications in catalysis, fuel cells, and electrochemical sensing, exhibiting attractive physical and chemical characteristics. They showed electronic conductivity, electrically active structure, the oxide ions mobility through the crystal lattice, variations on the content of the oxygen, thermal and chemical stability and supermagnetic, photocatalytic, thermoelectric, and dielectric properties. Nanoperovskites have been utilized as catalysts in oxygen reduction and hydrogen evolution reactions exhibiting high electrocatalytic activity, lower activation energy and high electron transfer kinetics. In addition, some perovskites are promising candidates for the development of effective anodic catalysts for direct fuel cells showing high catalytic performance. Moreover, they are recently utilized in electrochemical sensing of alcohols, gases, glucose, H2O2, and neurotransmitters. They can enhance the catalytic performance in terms of unique long-term stability, sensitivity, excellent reproducibility, selectivity, and anti-interference ability. In addition, organometallic halide perovskites exhibited efficient intrinsic properties to be utilized as a photovoltaic solar cell with good stability and high efficiency.

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Acknowledgments

The authors would like to acknowledge the financial support from Cairo University through the Vice President Office for Research Funds.

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Written By

Nada F. Atta, Ahmed Galal and Ekram H. El-Ads

Submitted: 31 March 2015 Reviewed: 18 August 2015 Published: 03 February 2016