4.1. The Optimization of Supports
The utilization of supports is one of the most key factors for affecting the durability of Pt-based catalysts. Generally, enhancing the graphitization can efficiently improve the chemical and thermal stability of carbon supports, presenting several advanced carbon supports including carbon nanofibers, carbon nanotubes, ordered mesoporous carbon spheres and carbon nano-onions, etc. [
93,
94,
95]. Nevertheless, highly graphitized carbon compromises the specific surface area, porous structure and anchoring sites, challenging the uniform dispersion of Pt-based catalysts, which is unfavorable for the improvement in electrocatalytic activity and durability. To address this issue, it is necessary to introduce functional groups and defect sites through proper surface modifications such as heteroatoms do**, oxidation treatment and polymer modification, aiming at boosting the interaction between the Pt-based nanocrystals and carbon supports [
95,
96,
97,
98]. In this respect, a 3D N-doped porous graphitic carbon, produced from the carbonization of a 3D polymer hydrogel with the assistance of Mn, was presented as a highly durable and active support to load Pt nanoparticles (Pt/PGC) (
Figure 3a) [
98]. In this synthesis, the introduction of Mn salts endowed the polymer hydrogel-derived carbon with high graphitization, alleviating the loss of nitrogen do** and the reduction in the surface area caused by the traditional high temperature. Due to the do** of electronegative N atoms, the electronic state of the carbon support was optimized to generate stronger binding between the Pt atoms and bridge sites adjacent to the N dopant compared with the pristine carbon matrix (
Figure 3b). Therefore, as-optimized Pt/PGC showed an enhanced ORR electrocatalysis compared with other carbon-supported Pt catalysts, especially in terms of durability. Especially, the advantages of such catalysts in the MEA system are more obvious, reflecting the fact that the voltage loss at a current density of 1.5 A cm
−2 of the MEA, with Pt/PGC as the cathodic catalyst, is only 9 mV after 5000 potential cycles (
Figure 3c). In contrast, the MEA with Pt/TEC10V20E (Vulcan support) showed a more serious attenuation under the similar operation conditions (
Figure 3d). In addition to the enhanced durability, the graphitization and porous structure of PGC supports also balance the ORR activity of Pt catalysts.
Compared with traditional carbon supports, supports embedded with single atoms are more appealing as stable supports to load Pt-based materials. The introduction of single atoms into carbon materials can not only provide a strong interaction between the supports and active metals, but also optimize the adsorption behavior of active Pt-based catalysts, enhancing the ORR performance [
99,
100,
101]. To this end, Shao’s group improved the durability of Pt nanoparticles by using the Fe- and N-codoped carbon (Fe–N–C) [
102]. In acidic and alkaline media, the retention rate of ECSAs for the Pt/Fe–N–C catalyst during the potential cycles is much better than that of commercial Pt/C, and the dissolution rate of Pt in Pt/Fe–N–C is three times lower than that of Pt/C. In this catalysis, Fe–N–C supports can provide strong and stable support for Pt nanoparticles, and the formation of oxides can be reduced by adjusting the electronic structure. A strong metal-support interaction and low metal dissolution rate, as well as the highly stable supports are dominant in the remarkable enhancement of Pt/Fe–N–C durability. Therefore, the selection of carbon supports represents a typical strategy for achieving the ultradurable Pt-based catalysis for PEMFCs.
In order to avoid the corrosion of carbon materials, several noncarbon supports with a strong chemical and structural stability have been proposed. For instance, by using mesoporous TiO
2 as the support, Pt/TiO
2 catalysts with a high anticorrosive ability were prepared to enhance the ORR durability [
103]. However, metal oxide supports are not a long-term choice due to their poor conductivity and low specific surface area. Therefore, the composites of carbon and metal oxides become potential candidates for promising supports to load Pt-based catalysts to enhance the durability [
104]. In the case of metal compound supports, transition metal nitrides and carbides have also been widely spread around as highly stable support materials, including TiN, WC, CrN and MoN, etc. Very recently, as a kind of emerging 2D transition metal carbide, MXene has been considered as a novel support to load Pt catalysts that can achieve high ORR activity and durability, which is because of the fact that MXene features a unique 2D structure, metallic conductivity, large surface area, abundant surface functional group and high electrochemical stability [
105,
106].
4.2. Heteroatom-Doped Alloys
Do** engineering is a common strategy for regulating the electronic structures of Pt-based nanocrystals by introducing a small number of foreign atoms into nanocrystals in the form of interstitial or substitution atoms. The do** of heteroatoms can usually inhibit the dissolution of alloying metals, so that alloying metals can play a role in regulating the electronic structure to maintain the activity during the whole test process [
107,
108]. In addition, this strategy can also maintain the special shape of anisotropic nanocrystals during electrocatalysis [
109,
110]. More importantly, in terms of the enhanced activity, the do** of heteroatoms can not only adjust the energy band structure to enhance the catalytic activity and selectivity, but also optimize the surface energy of catalysts and control the binding strength towards reaction intermediates to accelerate the reaction kinetics [
111,
112,
113]. Therefore, do** engineering has been considered as one of the most efficient methods to improve the electrocatalytic performance, not only in terms of durability, but also activity. Moreover, dopants can sometimes participate in the growth of nanocrystals and change the growth mechanism of nanocrystals, inducing the nanocrystals with controllable shapes or phases [
114,
115,
116].
In light of the fact that the do** of heteroatoms can boost the activity and durability of Pt-based nanocrystals, various transition metals have been introduced into Pt-based alloy catalysts. In this case, a series of transition metals (V, Cr, Mn, Fe, Co, Mo, W and Re) were surface doped into carbon-supported Pt
3Ni octahedra to improve the ORR performance of Pt
3Ni octahedra [
117]. Among these well-designed doped catalysts, Mo-doped Pt
3Ni octahedra showed the highest ORR specific activity of 10.3 mA cm
−2 and a mass activity of 6.98 A mg
Pt−1, much higher than those of undoped counterparts. More importantly, after Mo atom do**, the durability of the octahedra was also significantly improved, which can be confirmed by the fact that the specific activity of Mo-doped Pt
3Ni octahedra was only attenuated by 6.2% after 8000 cycles, while that of Pt
3Ni octahedra was decreased by 33%. The post-test characterizations showed that the loss of Ni atoms in Pt
3Ni was serious during the ORR electrocatalysis, while this phenomenon was obviously weakened after do** Mo atoms. In addition, the shape of the Mo-doped Pt
3Ni octahedra was well maintained after ORR durability tests, while the undoped octahedra became more spherical. Density functional theory (DFT) calculations revealed that Mo atoms tended to enhance the ORR performance by locating nearing the subsurface of the nanocrystal edge in vacuum and the surface vertex/edge sites under oxidation conditions.
The above research stimulated a series of works to explore the role of do** elements in improving the ORR activity and durability of catalysts. In view of the enhanced ORR performance of 1D Pt-based nanostructures compared with the 0D counterparts, Rh atoms were doped into ultrathin Pt nanowires with an average diameter of 1.3 ± 0.3 nm (
Figure 4a) [
118]. At 0.9 V (vs. RHE), the ORR specific and mass activities of Rh-doped Pt nanowires are 1.63 mA cm
−2 and 1.41 A mg
Pt−1, respectively, 1.2 and 1.6 times higher than those of pure Pt nanowires, respectively. More importantly, after 10,000 continuous cycles, the activity retention of Rh-doped Pt nanowires was 90.8%, much higher than that of Pt nanowires (80.5%), confirming that the durability had been significantly improved after Rh-do** (
Figure 4b). The unique 1D anisotropic structure and the introduction of a small number of Rh atoms were the dominant reasons for the enhanced durability. In this respect, the incorporation of Rh atoms can suppress the dissolution of Pt atoms through preferentially sacrificing Rh atoms during long-term electrocatalytic tests, which can be confirmed by the fact that the atomic ratio of Pt/Rh was significantly decreased after 10,000 cycles, while Pt nanowires showed an obvious dissolution under the similar conditions. DFT calculations revealed that the vacancy formation energy of Pt atoms in Rh-doped Pt models was obviously higher than in those without Rh atom do**, verifying that the enhanced durability can be achieved by improving the oxidation resistance of Pt atoms (
Figure 4c). Similar observations were also found in Rh-doped Pt-based alloy systems [
40,
119]. Long-term durability tests made the shape of PtNi octahedral nanoparticles more spherical, while Rh do** can well maintain the octahedral shape, thus improving the ORR durability (
Figure 4d) [
119]. In terms of the PtNi nanowires, apart from maintaining the basic shape, the introduction of Rh atoms can substantially slow down the leaching of Ni atoms from nanowires [
40]. Note that Rh atoms can further boost the vacancy formation energy of Ni atoms to reduce the leaching of Ni atoms from PtNiRh, on the basis of increasing the vacancy formation energy of Pt atoms.
It has been found that Ga atoms have a similar effect to the Rh atoms in terms of boosting the durability of Pt-based catalysts. Taking Ga-doped PtNi octahedral nanoparticles as an example, the do** of Ga atoms dramatically enhanced the ORR durability of PtNi octahedral nanoparticles, confirmed by the significantly improved activity retention after 30,000 cycles [
120]. This conclusion was also reflected by the decreased ECSA of Ga-PtNi, decreased from 49 to 44 m
2 g
Pt−1, while that of PtNi was more obvious (28 m
2 g
Pt−1), because a small amount of surface Ga do** can effectively hinder the dissolution of Pt and Ni atoms from PtNi nanoparticles and the collapse of the preferred octahedral shape. Additionally, lavender-like Ga-doped Pt
3Co nanowires were rationally designed to further elucidate the key role of Ga atom do** in improving the ORR durability of Pt-based alloy catalysts (
Figure 5a) [
114]. The increase in the Ga atom content not only made the surface of the nanowires denser and denser, but also significantly improved the ORR durability of the nanowires. Among all kinds of nanowires, the half-wave potential of 8% Ga-doped Pt
3Co nanowires only decayed by 4 mV after 20,000 cycles, and the retention of the specific and mass activity was as high as 89.3% and 95.3%, respectively (
Figure 5b). However, excessive Ga do** reduced the catalytic activity of Pt
3Co nanowires, putting forward a balance between the activity and durability by presenting an optimized idea. In this system, the decrease in the surface energy caused by Ga atom do** explained the enhanced durability of Pt
3Co nanowires (
Figure 5c).
A strong metal bond can be formed by combining W atoms with Pt metal, which is extremely stable in an acidic environment, thus providing a new idea for W do** to enhance the ORR durability of Pt-based alloy catalysts [
121,
122]. To this end, W atoms served as an adhesive to stabilize the dissolution of transition metals from PtCu-based alloys (
Figure 5d) [
123]. After 30,000 durability tests, as-optimized Pt
2CuW
0.25 showed the lowest activity losses of 4.1% and 10.5% towards mass and specific activities, respectively, much superior to those of Pt
2Cu catalysts (
Figure 5e). The enhanced durability of Pt
2CuW
0.25 mainly originated from the raised vacancy formation energy of Pt atoms caused by the stronger bonding between W and Pt/Cu atoms, leading to structural stability during the electrocatalytic tests (
Figure 5f). This work presented a reasonable design to enhance the electrocatalytic durability by using high melting point metals to maintain the thermodynamic stability of Pt-based alloys. In addition, other high melting point metals can also act as dopants to improve the electrocatalytic durability, including Au, Ir and Re atoms, etc. [
124,
125,
126]. Especially for the early transition metals, it has been found that alloying with Pt has been regarded as an efficient strategy to improve ORR performance [
127]. Huang’s group further introduced Re atoms into ternary PtNiGa ultrafine nanowires to construct a novel ORR catalyst with excellent activity, long-term stability and high atomic utilization [
128]. The mass activity of as-optimized Re-doped PtNiGa nanowires was 19.6 times higher than that of commercial Pt/C, and the mass activity was only attenuated by 10.6% after 20,000 cycles. The optimal electronic structure of Re-doped PtNiGa nanowires caused the weakened binding strength towards oxygen-containing intermediates and elevated the dissolution potential, thus boosting the ORR activity and stability. More importantly, this catalyst also exhibited excellent performance as a cathode catalyst in the MEA tests, with a peak power density of 961 mW cm
−2 and a current density decrease of only 4.9% after a discharge voltage of 0.75 V for 100 h.
Figure 5.
Enhancing ORR durability of Pt-based catalysts by other metal atom do**. (
a) Representative TEM image and the corresponding schematic illustration of 4% Ga-doped Pt
3Co nanowires. (
b) ORR polarization curves of 8% Ga-doped Pt
3Co nanowires before and after different potential cycles. (
c) Surface energy and Δ
E0 of the pure Pt, Pt
3Co and Ga-doped Pt
3Co (111) surfaces (the insets are the corresponding computational models, and the gray, blue and green spheres represent Pt, Co and Ga atoms, respectively). Reprinted with permission from Ref. [
114]. Copyright 2020 ACS. (
d) Representative HRTEM image of Pt
2CuW
0.25 nanoparticles. (
e) ORR polarization curves of Pt
2CuW
0.25 nanoparticles before and after different potential cycles (
inset is the partial enlargement). (
f) Structures of Pt vacancies formed on different sites of the PtCu (111) or PtCuW (111) surfaces and the corresponding Δ
Evac values (the yellow circles are the locations of the vacancies, the Pt, Cu and W atoms are shown in dark blue, orange and light blue). Reprinted with permission from Ref. [
123]. Copyright 2020 Wiley.
Figure 5.
Enhancing ORR durability of Pt-based catalysts by other metal atom do**. (
a) Representative TEM image and the corresponding schematic illustration of 4% Ga-doped Pt
3Co nanowires. (
b) ORR polarization curves of 8% Ga-doped Pt
3Co nanowires before and after different potential cycles. (
c) Surface energy and Δ
E0 of the pure Pt, Pt
3Co and Ga-doped Pt
3Co (111) surfaces (the insets are the corresponding computational models, and the gray, blue and green spheres represent Pt, Co and Ga atoms, respectively). Reprinted with permission from Ref. [
114]. Copyright 2020 ACS. (
d) Representative HRTEM image of Pt
2CuW
0.25 nanoparticles. (
e) ORR polarization curves of Pt
2CuW
0.25 nanoparticles before and after different potential cycles (
inset is the partial enlargement). (
f) Structures of Pt vacancies formed on different sites of the PtCu (111) or PtCuW (111) surfaces and the corresponding Δ
Evac values (the yellow circles are the locations of the vacancies, the Pt, Cu and W atoms are shown in dark blue, orange and light blue). Reprinted with permission from Ref. [
123]. Copyright 2020 Wiley.
In addition to the transition metal do** engineering, the designs of light element do** are also of great interest for stabilizing the dissolution of Pt and transition metals during the long-term ORR cycles, such as F, H, N, P and B [
129,
130]. Among these light element-doped Pt-based alloys, light elements tend to occupy the largest available gap position to form interstitial alloys rather than substitute alloys. In contrast to traditional alloys, such interstitial alloys maintain the lattice structure of the original alloy to the greatest extent, which can optimize the electronic structure of surface-active sites through strong orbital hybridization, thus enhancing the activity and durability of the catalysts. B atoms have been interstitially doped into 3 nm Pt nanoparticles with a do** amount of 6.6% to improve the ORR activity and durability of Pt nanoparticles [
131]. Due to the do** of interstitial B atoms, the half-wave potential was only decreased by 5 mV after 10,000 cycles, superior to that of pure Pt nanoparticles, with a decreased half-wave potential of 23 mV. In addition, under H
2-O
2 fuel cell conditions, the MEA with B-doped Pt nanoparticles as cathodic catalysts showed a smaller attenuation in the power density compared with that based on Pt nanoparticles. Theoretical calculations indicated that the downshift of the
d-band center caused by the interstitial do** of B atoms suppressed the oxidative disruption of surface Pt atoms, thus enhancing the ORR durability.
4.3. Core/Shell Structures
Since only the surface atoms of the catalysts can contact the electrolyte to participate in the reactions, Pt-based core/shell structures with a high Pt utilization have been widely developed, especially those with low-cost cores and a thin layer of catalytically active shells [
132,
133,
134]. Generally, the cores will not take part directly in electrocatalysis,
yet they play an indispensable role in affecting the performance of the active shells through the potential strain and/or ligand effects. In the case of the mismatched lattice between the core and shell, the strain effect becomes more obvious compared with solid solution alloy counterparts, which is significantly important for regulating the electrocatalytic performance [
135,
136]. More importantly, the overlayers on cores can also improve the durability by inhibiting the loss of transition metals in the overall core/shell catalysts.
The core/shell structures with a Pt monolayer are the most classical catalysts to mitigate the drawbacks of traditional alloy catalysts, which can provide ultralow Pt loading and ultrahigh Pt utilization, as well as the possibility of optimizing the catalytic performance by the interactions between the overlayers and metal or alloy cores [
137]. Sasaki et al. designed a kind of highly durable ORR electrocatalyst composed of Pt monolayers on PdAu alloy nanoparticles (Pt
ML/PdAu) (
Figure 6a) [
138]. After testing for as long as 100,000 cycles under fuel cells, as-designed Pt
ML/PdAu showed an attenuation of ~8% in terms of its mass activity, much more excellent than those of Pt
ML/Pd and commercial Pt/C (
Figure 6b). The introduction of Au atoms into the core made the Pt monolayer significantly tolerant, thus showing a high durability towards ORR electrocatalysis and being very promising for the practical fuel cells. Driven by these unique core/shell structures with Pt monolayers, the catalysts with a Pt-skin structure were further presented to inhibit the dissolution of transition metals internally [
139,
140]. By replacing the Cu atoms in three surface layers of the AuCu intermetallics by Pt atoms, a Pt skin on a AuCu intermetallic catalyst can be elaborately designed, which can maximize the Pt utilization to enhance ORR activity and durability (
Figure 6c) [
141]. The theoretical calculations showed that the Pt-skin structure composed of a 1.5 Pt-skin layer on a AuCu (111) substrate can display a weakened oxygen affinity compared with that on Pt (111), thus contributing to more favorable ORR electrocatalysis (
Figure 6d). In fact, most Pt-based catalysts prepared by annealing or activated under acidic conditions are likely to form a Pt-skin surface, which is generally caused by atomic segregation under high temperature and the loss of surface transition metals [
57,
140,
142]. In this part, we only discuss the elaborate Pt-skin core/shell catalysts, while neglecting the spontaneously formed Pt-skin structures.
Beyond core/shell catalysts with Pt-skin layers, several new attempts were further presented to optimize the ORR performance of Pt-based core/shell catalysts, including do** foreign atoms into cores, adjusting the thickness of shells, tuning the composition of the core and/or shell and morphology-controlled core/shell structures [
143,
144]. In terms of do** engineering, anion do** has been regarded as an efficient strategy to enhance the ORR activity and durability. This is because of the fact that the do** of anions can not only provide the optimal strain fields for surface Pt atoms, but also form chemically stable cores by reacting with selected elements. For example, a high-pressure nitriding strategy was conducted to adjust the do** amount of N atoms in PtCo core/shell nanoparticles, aiming at maintaining the electrochemical surface area to further improve the ORR stability (
Figure 6e) [
145]. Compared with commercial Pt/C, the mass activity and durability of N-PtCo core/shell catalysts were enhanced by two times and five times, respectively. After 180,000 cycles, the mass activity of N-PtCo core/shell catalysts can still retain 80% of the initial activity, and the core/shell structure can be well maintained after 1,000,000 cycles. In this system, the higher concentration of N atoms in core/shell nanoparticles is more favorable through optimizing the oxygen binding energy on the Pt surface and preventing the dissolution of Pt/Co atoms.
Figure 6.
Enhancing ORR durability of Pt-based catalysts by core/shell nanoparticles. (
a) HAADF-STEM image and the corresponding line-scan result of carbon-supported Pt
ML/Pd
9Au
1 nanoparticles. (
b) The mass activities of the Pt
ML/Pd
9Au
1, Pt
ML/Pd and Pt/C catalysts after different potential cycles. Reprinted with permission from Ref. [
138]. Copyright 2012 Springer Nature. (
c) The specific and mass activities of Pt-skin AuCu and Pt nanoparticles. (
d) Oxygen adsorption energy (Δ
EO) for AuCu(111) surfaces covered with different thicknesses of Pt skin and Pt (111) surface. Reprinted with permission from Ref. [
141]. Copyright 2014 ACS. (
e) The normalized ECSA values of PtCo core/shell nanoparticles with different do** amount of N atoms after different potential cycles (insets are the corresponding atomic models). Reprinted with permission from Ref. [
145]. Copyright 2021 ACS.
Figure 6.
Enhancing ORR durability of Pt-based catalysts by core/shell nanoparticles. (
a) HAADF-STEM image and the corresponding line-scan result of carbon-supported Pt
ML/Pd
9Au
1 nanoparticles. (
b) The mass activities of the Pt
ML/Pd
9Au
1, Pt
ML/Pd and Pt/C catalysts after different potential cycles. Reprinted with permission from Ref. [
138]. Copyright 2012 Springer Nature. (
c) The specific and mass activities of Pt-skin AuCu and Pt nanoparticles. (
d) Oxygen adsorption energy (Δ
EO) for AuCu(111) surfaces covered with different thicknesses of Pt skin and Pt (111) surface. Reprinted with permission from Ref. [
141]. Copyright 2014 ACS. (
e) The normalized ECSA values of PtCo core/shell nanoparticles with different do** amount of N atoms after different potential cycles (insets are the corresponding atomic models). Reprinted with permission from Ref. [
145]. Copyright 2021 ACS.
Strain and ligand engineering are the most common effects in core/shell structure catalysts, which can optimize the catalytic activity by regulating the electronic structure of surface atoms [
146,
147,
148]. In fact, when the shell thickness is less than three atomic layers, the ligand and strain effect jointly dominate the electrocatalytic performance, while the ligand effect disappears beyond three atomic layers [
135,
149]. Note that the bifunctional effect will be reflected in the core/shell catalysts with the further increase in shell thickness. Hence, the shell thickness plays an important role in enhancing the ORR activity and durability of core/shell catalysts, and the optimized thickness of Pt layers required to obtain the optimal performance may depend on the properties of the cores. In order to search the optimal Pt-layer thickness for ORR electrocatalysis, DFT calculations were conducted to study the influence of Pt-layer thickness on various L1
0-PtM (M = V, Cr, Fe, Co, Ni and Cu) catalysts on the oxygen binding energy [
150]. It was found that the oxygen binding energy decreased with the increase in Pt-shell thickness, leading to the improved catalytic performance, making the Pt–M catalyst with three Pt layers display a better ORR activity than those with one or two Pt layers. Experimentally, Pt layers were deposited on the corners and (100) terraces of the Pd nanocubes (Pt
corner/Pd
NC and Pt
terrace/Pd
NC), and the corrosion kinetics were further studied using in situ transmission electron microscopy (TEM) [
132]. The corners of Pt
corner/Pd
NC were protected by Pt layers, inhibiting the etching of the overall particles, thus boosting the durability of the catalysts. However, the Pt
terrace/Pd
NC exhibited a preferential dissolution at the corner of Pd
NC to show a low catalytic durability during ORR tests.
Constructing the Pt-based alloy shells on the cores is another effective strategy to reduce the cost of Pt-based core/shell catalysts and further improve the ORR activity and durability. Combining the Au cores and PtCo-based shells, the ORR durability was significantly improved, which was mainly due to the strong electronic interaction of subsurface segregated Au atoms [
151]. The well-designed Au-core@Co-interlayer@PtCoAu-shell multilayer structure showed the specific activity of 1.730 mA cm
−2 and mass activity of 0.692 A mg
Pt−1, 7.0 and 4.0 times higher than those of commercial Pt/C catalysts, respectively. More importantly, the activity loss for the multilayered catalyst was only 6.14% while that of the commercial Pt/C exceeded 35%. Therefore, the alloy shell can also overcome the problem of composition loss by optimizing the electronic structure of surface Pt atoms and finely designing the composition distribution to enhance the electrocatalytic durability.
Considering that the multidimensional structures can provide a strong interaction with supports to induce the well’s structural stability, the Pt-based core/shell structures with an anisotropic morphology will be the ideal platforms to obtain excellent ORR durability [
152,
153,
154]. Although segregated Pt-skin structures are extraordinarily active towards ORR electrocatalysis, this is difficult to achieve on the surface of nanocrystals with high-index facets [
88,
142,
155]. To address this challenge, Guo et al. achieved the highly active and stable Pt-skin surface with high-index facets via annealing the presynthesized Pt
3Fe zigzag-like nanowires under H
2/Ar environments (
Figure 7a–c) [
142]. The unique nanowire morphology and Pt-skin surface enable as-prepared Pt-skin Pt
3Fe nanowires to have an extremely high ORR mass activity of 2.11 A mg
Pt−1 and specific activity of 4.34 mA cm
−2. More importantly, high-index facets enclosed Pt-skin Pt
3Fe nanowires were also electrochemically stable under harsh electrocatalytic conditions with a little mass activity decay of 24.6%,
yet the pristine Pt
3Fe nanowires showed serious activity decay, especially after a long-term cycle (
Figure 7d,e). The optimal oxygen adsorption energy induced by the combination of a strong ligand and strain effect dominated the enhanced ORR performance, revealed by the density functional theory calculations (
Figure 7f). In addition, the Pt-skin Pt
3Fe nanowires also showed a high resistance to morphological and structural transformations during ORR electrocatalysis, and can protect favorable Fe atoms from being dissolved, thus maintaining a high activity under operating conditions. This strategy can further extended into PtCo zigzag-like nanowires, which showed a Pt-skin surface with high-index facets and high electrocatalytic performance [
156]. Recently, the mesoporous Pt/Pt-skin Pt
3Ni core/shell framework nanowires were designed to finely integrate the anisotropic advantages of 3D porous nanoframes and 1D nanowires (
Figure 7g) [
157]. This catalyst was composed of 1D ultrafine Pt nanowires (~3 nm) and mesoporous Pt-skin Pt
3Ni framework (
Figure 7h), which has displayed excellent ORR activity and durability, as well as ultrahigh Pt atom utilizations. Surprisingly, the well-designed Pt/Pt-skin Pt
3Ni core/shell framework nanowires exhibited an ultradurable stability, with the activity less than 3% after continuous 50,000 cycles (
Figure 7i).
Two-dimensional Pt-based core/shell nanocrystals are also ideal catalyst models to achieve highly durable ORR electrocatalysis. A typical example is the biaxially strained PtPb/Pt core/shell nanoplates synthesized using a one-step wet-chemical method [
158]. The PtPb/Pt core/shell nanoplates showed a side length of about 16 nm and a thickness of 4.5 ± 0.6 nm, where two different interfaces, the (010) PtPb//(110) Pt interface between PtPb core and edge Pt shell and the (001) PtPb//(110) Pt interface between PtPb core and top (bottom) Pt shell, exist. The top Pt layer was completely connected with the PtPb core, resulting in a tensile strain of 7.5% along [100]
Pt and a compressive strain of 11% along [01-1]
Pt. On the other hand, in the edge Pt layer, the [001] direction of Pt was completely restricted, resulting in a 7.5% tensile strain and very small compressive strain along [110]
Pt. In this catalytic system, a compressive strain can weaken the Pt–O binding energy on the surface of Pt (111) and promote the ORR activity. The tensile strain was beneficial for optimizing the low-coordination atoms with strong Pt–O bonds to enhance the ORR properties. Therefore, the resulting biaxial strain effect made the PtPb/Pt core/shell nanoplates show a much better ORR catalytic activity and durability than the commercial Pt/C and PtPb nanoparticles.
4.4. Intermetallics
Over the past decade, Pt-based intermetallics have been extensively studied as electrocatalysts for fuel cell devices, which is due to their lower negative entropy and stronger electronic interaction between different atoms [
159,
160,
161]. In light of the strong
d-orbital interaction between different atoms originated from the sufficient atomic acquaintance within an alternated distribution, the promoted ligand effect and obviously downshifted
d-band center have been observed on various Pt-based intermetallics [
162,
163,
164]. The regulation of the electronic structure enables the optimized adsorption/desorption towards oxygenated intermediates, thus contributing to the enhanced ORR electrocatalysis. In addition, the different lattice compressive strains will be caused by the highly spaced atoms with different radii, further optimizing the energy band structure of nanocrystals. More importantly, in terms of durability, the excessive corrosion under harsh ORR conditions can be prevented by the close combination of alloying elements originated from the intrinsic ordered structure and strong atomic interaction of intermetallics, thus endowing Pt-based intermetallics with a high ORR durability.
Owing to the unique structural characteristics of intermetallics, the significantly enhanced ORR activity and durability have been observed on various Pt-based intermetallic nanocrystals [
140,
165,
166,
167,
168,
169]. For instance, the core/shell L1
0-CoPt/Pt nanoparticles with an intermetallic structure showed a higher ORR activity and durability than the disordered counterparts [
168]. The intermetallic CoPt/Pt nanoparticles were synthesized via annealing the cashew-like CoPt nanoparticles at 650 °C (
Figure 8a). In this structure, the core exhibited alternative layers of Pt and Co atoms, and the shell was 2–3 atoms thick of Pt, thus providing a stronger ability to protect the acidic etching of Co atoms (
Figure 8b). As a result, a high mass activity of 0.56 A mg
Pt−1 and excellent durability with a negligible activity loss after 30,000 cycles can be achieved on the intermetallic CoPt/Pt nanoparticles (
Figure 8c), while the disordered A1-CoPt nanoparticles showed a 41% drop in the mass activity under the same cycle conditions. Note that the cashew-like shapes cannot be well maintained despite the conversion from a disordered to intermetallic L1
0 structure, because of the unavoidable nanocrystal aggregation induced by Ostwald ripening under high-temperature conditions. Therefore, the rational selection of synthetic methods to avoid sintering and aggregation is vital for further optimizing the ORR performance through limiting the particle sizes and narrowing the size distributions.
Several typical strategies have been presented to avoid the agglomeration during annealing treatment, such as shell-protected annealing [
170], oxide-driven atomic ordering [
167,
171], matrix protection methods [
172], and nanoconfinement strategies [
173,
174,
175], etc. Herein, we take two typical examples to clarify the size control of these methods and the significance towards the enhanced electrocatalytic performance. The first one is to anneal Pt nanoparticles encapsulated in a ZnO matrix at 600 °C for 2 h under a H
2/Ar atmosphere to achieve the ordering of PtZn intermetallic nanoparticles, after which the excess ZnO matrix was removed through acidic treatment (
Figure 8d) [
176]. The ZnO matrix can not only be partially reduced to Zn atoms to interdiffuse with Pt atoms to form intermetallics, but also prevent the further sintering and agglomeration of nanoparticles during annealing processes. The biaxial strain of Pt shells with 3.9% compression along the <011> and <101> directions and 2.23% tension along the <110> direction was achieved on PtZn intermetallic nanoparticles (
Figure 8e,f), thus leading to an optimal oxygen adsorption energy (
Figure 8g). The biaxially strained PtZn intermetallic nanoparticles displayed a high mass activity of 1.02 A mg
Pt−1 and a specific activity of 1.68 mA cm
−2, as well as excellent durability with a negligible activity attenuation after 10,000 cycles (
Figure 8h). In contrast, the disordered PtZn nanoparticles suffered from severe degradation with a downshifted half-wave potential of 15 mV.
Figure 8.
Enhancing ORR durability of Pt-based catalysts by intermetallic nanoparticles. (
a) Representative TEM image and (
b) structural illustration of core/shell L1
0-CoPt/Pt nanoparticles. (the silver color atom is Pt and the blue color atom is Co) (
c) ORR polarization curves of core/shell L1
0-CoPt/Pt nanoparticles before and after different potential cycles. Reprinted with permission from Ref. [
168]. Copyright 2019 Elsevier. (
d) Schematic illustration of the synthesis of L1
0-PtZn/Pt nanoparticles. (
e) Schematic illustration of biaxial strain between L1
0-PtZn core and A1-Pt shell. (
f) Simulation model of 3 nm L1
0-PtZn/Pt
3L nanoparticle and strain distribution on the (111) surface of the L1
0-PtZn/Pt nanoparticle. (
g) Δ
EO of compressive strain on the Pt (111) surfaces. (
h) ORR polarization curves of L1
0-PtZn and A1-PtZn nanoparticles before and after 10,000 cycles. Reprinted with permission from Ref. [
176]. Copyright 2020 Wiley.
Figure 8.
Enhancing ORR durability of Pt-based catalysts by intermetallic nanoparticles. (
a) Representative TEM image and (
b) structural illustration of core/shell L1
0-CoPt/Pt nanoparticles. (the silver color atom is Pt and the blue color atom is Co) (
c) ORR polarization curves of core/shell L1
0-CoPt/Pt nanoparticles before and after different potential cycles. Reprinted with permission from Ref. [
168]. Copyright 2019 Elsevier. (
d) Schematic illustration of the synthesis of L1
0-PtZn/Pt nanoparticles. (
e) Schematic illustration of biaxial strain between L1
0-PtZn core and A1-Pt shell. (
f) Simulation model of 3 nm L1
0-PtZn/Pt
3L nanoparticle and strain distribution on the (111) surface of the L1
0-PtZn/Pt nanoparticle. (
g) Δ
EO of compressive strain on the Pt (111) surfaces. (
h) ORR polarization curves of L1
0-PtZn and A1-PtZn nanoparticles before and after 10,000 cycles. Reprinted with permission from Ref. [
176]. Copyright 2020 Wiley.
In addition, Liang et al. presented a sulfur-anchoring strategy for achieving the strong interaction between Pt and S atoms in the carbon matrix to suppress the sintering of nanoparticles even at annealing temperatures up to 1000 °C, thus being a promising method to prepare small-sized Pt-based intermetallic nanoparticles [
177]. In light of the advantages of the sulfur-anchoring approach, a Pt-based intermetallic (PtM, Pt
3M and PtM
3) library can be constructed, demonstrating the possibility of the general synthesis of small-sized intermetallic nanoparticles by esca** from the trouble of simultaneously accelerated interparticle sintering dynamics and the intraparticle atomic order dynamics with the increased temperature. The optimized intermetallic PtCo nanoparticles showed the highest ORR activity among the prepared Pt-based intermetallics, and their potential application in practical H
2-air fuel cells with an ultralow Pt loading of 0.02 mg
Pt cm
−2 and a maximum power density of 1.08 W cm
−2. To this end, transforming disordered nanocrystals into ordered intermetallics has been considered as a promising way to improve the ORR activity and durability of Pt-based catalysts.
Pt-based ternary intermetallics constructed by introducing an additional element into Pt-based ternary systems seem to be a long-awaited answer to further improve the catalytic durability. Through synthesizing a series of L1
0-PtMCo (M = Mn, Fe, Ni, Cu and Zn) nanoparticles, the optimal position of the theoretical volcano plot was successfully achieved due to the anisotropic strain levels on distorted Pt (111) surfaces [
178]. Among various PtMCo intermetallic nanoparticles, the L1
0-PtNiCo nanoparticles showed the highest ORR activity of 3.1 A mg
Pt−1 and 9.3 mA cm
−2. In terms of durability, the mass activity loss of L1
0-PtNiCo nanoparticles was only 15.9% after 30,000 cycles, demonstrating the enhanced ORR performance on ordered Pt-based ternary systems.
Shape-controlled synthesis of intermetallics has always been a research hotspot but has only displayed limited success. This is mainly because of the fact that the necessary annealing conditions will break and coarsen the pristine nanocrystals, thus necessitating the robust initial structures or relatively low annealing temperatures. In this case, a shell-protected annealing strategy may be an efficient strategy to maintain the initial anisotropic structures when using the robust nanocrystals as precursors [
179,
180,
181]. Taking the PtFeIr nanowire as an example, the use of SiO
2 shells can alleviated the breakage, aggregation and sintering of initial nanowires during annealing (
Figure 9a) [
179]. Without the protection of SiO
2, PtFeIr nanowires will be transformed into nanoparticles under such a harsh annealing environment. However, such an ordered phase transformation with negligible shape change is still highly dependent on the robust thermally stable precursors, confirmed by the fact that the SiO
2-protected PtFe nanowires would be broken into nanoparticles under the same annealing conditions. This is because that the existence of Ir with a high melting point was beneficial for the maintenance of 1D nanostructures by improving the thermal stability of nanowires. Combining the advantages of ordered intermetallics and 1D nanostructures, as-prepared ordered PtFeIr nanowires show a high ORR activity, with a specific activity of 2.40 mA cm
−2 and a mass activity of 2.03 A mg
Pt−1, as well as the minimum activity loss after 10,000 cycles (
Figure 9b).
An important method for controlling the anisotropic morphology of nanocrystals is template method, which has been extended to the preparation of intermetallic nanocrystals. The template method can be further divided into the soft-template method and hard-template method. The former mainly uses ordered aggregates formed by amphiphilic molecules as soft templates to control the shape of nanocrystals. To this end, various Pt-based intermetallic nanoplates have been synthesized by using the reasonably selected surfactants, including PtPb, PtBi and nanoplates [
158,
182]. In addition, the hard-template method can be used to construct the mesoporous materials via introducing the metal precursors into the hard-template channels. The subsequent roasting and template removal make the corresponding mesoporous materials become possible. The KIT-6 templates have been used to create various Pt-based intermetallic mesoporous nanocrystals [
183]. A typical example is the preparation of ordered mesoporous intermetallic Ga–Pt (
meso-i-Ga–Pt) nanoparticles through synergizing the anion induction and concurrent template methods (
Figure 9c) [
184]. As-prepared
meso-i-Ga-Pt nanoparticles presented a uniform and monodisperse polyhedron-like morphology, and the mesoporous channels run through the whole nanoparticles in an inversed double-gyroid structure (
Figure 9d). Benefiting from the unique structures of
meso-i-Ga
1Pt
1 nanoparticles, a high ORR mass activity of 66.7 A g
Pt−1 can be achieved in 0.1 M KOH, much higher than those of
meso-
i-Ga
3Pt
5,
meso-Pt and commercial Pt/C. In addition, after 15,000 cycles, the activity decline was only 47%, and the basic structures could be well maintained, indicating the excellent durability of
meso-i-Ga
1Pt
1 nanoparticles (
Figure 9e). The surface electronic structure analysis and DFT calculations revealed that the high ORR performance of
meso-i-Ga
1Pt
1 was mainly caused by the arrangement of chiral atoms and the abundance of exposed Pt sites, which is beneficial to the optimization of the adsorption/desorption towards reactants and the optimal Gibbs free energy of ORR electrocatalysis (
Figure 9f,g).
Figure 9.
Enhancing ORR durability of Pt-based catalysts by intermetallic nanostructures with anisotropic morphologies. (
a) Schematic illustration for the synthesis of
fct-PtFeIr nanowires through the silica-protected strategy. (
b) The mass activities of
fct-PtFeIr nanowires,
fcc-PtFeIr nanowires and commercial Pt/C catalysts before and after 10,000 cycles. Reprinted with permission from Ref. [
179]. Copyright 2022 Wiley. (
c) Schematic illustration for the synthesis of ordered
meso-i-Ga-Pt nanoparticles with precisely controlled intermetallic phases induced by different Ga salts (NO
3− and I
−). (
d) Representative HAADF-STEM image and the corresponding elemental map**s of ordered
meso-i-Ga-Pt nanoparticle. (
e) ORR polarization curves of ordered
meso-i-Ga-Pt nanoparticles before and after different potential cycles. (
f) Configurations of adsorbed intermediates (*OOH, *O and *OH) ordered
meso-i-Ga-Pt nanoparticles. (
g) ORR pathways for
meso-i-Ga
1Pt
1,
meso-i-Ga
3Pt
5 and
meso-Pt nanoparticles summarized at U = 0 V and 1.23 V. Reprinted with permission from Ref. [
184]. Copyright 2023 Wiley.
Figure 9.
Enhancing ORR durability of Pt-based catalysts by intermetallic nanostructures with anisotropic morphologies. (
a) Schematic illustration for the synthesis of
fct-PtFeIr nanowires through the silica-protected strategy. (
b) The mass activities of
fct-PtFeIr nanowires,
fcc-PtFeIr nanowires and commercial Pt/C catalysts before and after 10,000 cycles. Reprinted with permission from Ref. [
179]. Copyright 2022 Wiley. (
c) Schematic illustration for the synthesis of ordered
meso-i-Ga-Pt nanoparticles with precisely controlled intermetallic phases induced by different Ga salts (NO
3− and I
−). (
d) Representative HAADF-STEM image and the corresponding elemental map**s of ordered
meso-i-Ga-Pt nanoparticle. (
e) ORR polarization curves of ordered
meso-i-Ga-Pt nanoparticles before and after different potential cycles. (
f) Configurations of adsorbed intermediates (*OOH, *O and *OH) ordered
meso-i-Ga-Pt nanoparticles. (
g) ORR pathways for
meso-i-Ga
1Pt
1,
meso-i-Ga
3Pt
5 and
meso-Pt nanoparticles summarized at U = 0 V and 1.23 V. Reprinted with permission from Ref. [
184]. Copyright 2023 Wiley.
It has been found that the ORR performance of Pt-based intermetallics is also highly dependent on the ordering degree [
168,
185,
186]. Generally, the ORR activity and stability will be enhanced with the increase in the ordering degree [
185,
187]. However, most reported Pt-based intermetallic electrocatalysts tend to show a low ordering degree, challenging the further enhancement of ORR activity and durability. In order to obtain highly ordered PtCo-based intermetallics, Liang’s group presented a low-melting-point metal (M = Ga, Pb, Sb and Cu) do** strategy to boost the ordering degree (
Figure 10a) [
188]. Owing to the decreased atom diffusion energy barrier caused by the low-melting-point metal do**, the ordering degree of the M-doped PtCo intermetallics increases with the decrease in the melting point of M (
Figure 10b). The optimized Ga-doped PtCo intermetallics not only showed superior ORR performance in a half-cell environment, but they can also be used as high-efficient cathodic catalysts for the practical fuel cells. A high mass activity of 1.07 A mg
Pt−1 at 0.9 V in H
2-O
2 fuel cells and a peak power density of 1.05 W cm
−2 in H
2-air fuel cells can be achieved, far exceeding the US Department of Energy (DOE) 2025 target (
Figure 10c). Due to the high ordering degree, the Ga-doped PtCo intermetallics cathode still maintained a high mass activity of 0.88 A mg
Pt−1 with an attenuation of 17.8%. This work not only put forward an effective strategy to regulate the ordering degree of intermetallics, but also highlighted the importance of foreign metal do** in intermetallics for boosting the catalytic performance.
In the case of do** engineering, a small number of W, Ga and Zn atoms was introduced into the PtCo intermetallic nanoparticles derived from the core/shell Pt/CoO
x nanoparticles [
71]. The introduction of the third metals was achieved via simply mixing the appropriate amounts of third metal precursors with Co precursors during the synthesis process (
Figure 10d). Among all kinds of metal-doped PtCo intermetallics, W-doped PtCo intermetallic nanoparticles showed the highest ORR mass activity of 2.21 A mg
Pt−1 and specific activity of 3.60 mA cm
−2, as well as the negligible activity loss after 10,000 cycles under both room temperature and 60 °C (
Figure 10e,f). In light of the superior activity and durability of the W-doped PtCo intermetallic nanoparticles, the nanoparticles can be served as cathodic catalysts for fuel cells, which can achieve an initial mass activity of 0.57 A mg
Pt−1 and only a 70% activity loss after 50,000 cycles (
Figure 10g). In this system, the desired compressive strain and reduced surface energy of Pt surface caused by W atom do** in an ordered intermetallic structure are the dominant reasons for high activity and durability (
Figure 10h).
As discussed in the previous section, the core/shell nanocrystals have shown the improved electrocatalysis through the adjustable electronic structure of the surface environment caused by the potential strain and ligand effect. During the thermal treatment process, as the common preparation strategy for intermetallics, it is easy to form a Pt-skin shell, which is mainly due to the migration of metal atoms under a high-temperature environment [
167,
178]. The favorable compressive strain can be generated by the thin shells, thus achieving the shift down of the
d-band center to enhance the electrocatalytic performance. In addition, the unique electrocatalytic properties can be further generated by deliberately designing Pt-based intermetallics with core/shell structures, which mainly derives from the difference of core or shell with intermetallic structures [
189,
190]. A noteworthy catalyst platform is one where both the core and shell are replaced by different intermetallics [
189]. The PtBi intermetallic shells that were 2–3 ordered layers thick were covered on annealed carbon-supported FePt intermetallic nanoparticles. The intermetallic FePt/PtBi core/shell nanoparticles can be obtained with the shortened Pt–Pt bond, which can greatly alleviate the adverse effect of the interlayer tensile strain effect induced by the large Bi atoms for ORR electrocatalysis. As a result, a 0.39 eV remission of oxygen adsorption was achieved compared to crude Pt (111) and a 10-times enhancement of specific activity than commercial Pt/C catalyst was obtained. Moreover, after 30,000 cycles, the mass activity retention of FePt@PtBi core/shell nanoparticles was as high as 82%, while those of PtFeBi and FePt nanoparticles were 36% and 37%, respectively. To this end, the indispensable role of biaxial and even multiaxial strain from different zone axis directions caused by the unique intermetallic nanocrystals is highly appealing for enhancing ORR electrocatalysis.
4.5. High-Entropy Alloys
Due to the ability to continuously adjust the surface electronic structure of alloy catalysts, high-entropy alloys have attracted increasing attention in electrocatalysis. This can break through the barrier where the adsorption energy of traditional alloys towards oxygen-containing intermediates cannot approach the vertex of the volcanic curve [
191,
192]. In particular, the core effects, including high-entropy, lattice distortion, sluggish diffusion and cocktail effect, also endow the high-entropy alloys with high structural stability, thus becoming kind of ideal candidate catalysts for ultradurable electrocatalysis [
193]. Generally, the Sabatier theory has indicated that a desired catalyst should show the optimal bonding strength towards oxygen-containing intermediates, which has been widely reflected on various single metals or binary alloys [
45,
194,
195]. Nevertheless, the traditional methods, including the
d-band model and generalized coordination number model, etc., for associating adsorption energy cannot be extended to the complex high-entropy alloys [
196,
197]. To this end, Rossmeisl et al. developed a simple model to build the linear regression models via calculating the adsorption energies of *OH and *O on the IrPdPtRhRu (111) surface (
Figure 11a,b) [
198]. The ORR performance can be maximized through adjusting the whole compositions of high-entropy alloys, and the adsorption energies near to the apex of the volcano curve can be achieved on the optimized Ir
0.102Pd
0.320Pt
0.093Rh
0.196Ru
0.289. Afterwards, they further simplified the performance optimization of high-entropy alloys by combining the dynamic simulations and DFT calculations with Bayesian optimization [
199]. Therefore, the feasibility of high-entropy alloys in fuel cell-related electrocatalysis has been theoretically demonstrated by these studies.
However, high-entropy alloys are traditionally prepared through top-down methods, creating the bulk materials with very few active sites [
200]. In order to make the high-entropy alloys meet the electrocatalysis, reducing the size is an inevitable trend to guarantee catalytic reaction occurrence. In light of the near-continuum distribution of the relevant adsorption energies, PtPdFeCoNi nanoparticles showed a positive-shifted ORR polarization curve compared with that of commercial Pt/C, with a positive half-wave potential of 0.920 V [
201]. The lattice distortion effect and sluggish diffusion effect also endowed PtPdFeCoNi nanoparticles with a high mass activity of 1.23 A mg
Pt−1 and specific activity of 1.80 mA cm
−2. This is not only superior to the commercial Pt/C, but also higher than that of low-entropy counterparts (PtCo nanoparticles). Furthermore, an anchoring-carbonization strategy was presented to embed Pt-based high-entropy alloys with sizes below 3 nm onto the pore walls of ordered mesoporous carbon (
Figure 11c) [
202]. The method was highly general and can be extended to the synthesis of a series of Pt-based ultrasmall high-entropy alloys, including senary PtFeCoNiCuZn, septenary PtRuIrFeCoNiCu, octonary PtRuIrFeCoNiCuZn and denary PtRuIrRhFeCoNiCuZnSn nanoparticles. As-prepared senary PtFeCoNiCuZn high-entropy alloy nanoparticles showed a higher ORR activity than those of low- and medium-entropy counterparts, demonstrating the enhanced electrocatalysis of high-entropy alloys (
Figure 11d). In addition, such ultrasmall high-entropy alloys also exhibited a superior durability than that of commercial Pt/C catalysts, implying that the high-entropy alloys may be a promising model for ultradurable electrocatalysis.
Figure 11.
Enhancing ORR durability of Pt-based catalysts by high-entropy alloys. (
a) Full span of predicted adsorption energies of (
a) *OH and (
b) *O based on DFT calculations (each color represents an individual binding site). Reprinted with permission from Ref. [
198]. Copyright 2019 Elsevier. (
c) Representative HAADF-STEM image of porous carbon-supported PtFeCoNiCuZn high-entropy alloy nanoparticles. (
d) ORR polarization curves of porous carbon-supported PtFeCoNiCuZn high-entropy alloy nanoparticles and the medium- and low-entropy counterparts and commercial Pt/C catalysts. Reprinted with permission from Ref. [
202]. Copyright 2022 Wiley.
Figure 11.
Enhancing ORR durability of Pt-based catalysts by high-entropy alloys. (
a) Full span of predicted adsorption energies of (
a) *OH and (
b) *O based on DFT calculations (each color represents an individual binding site). Reprinted with permission from Ref. [
198]. Copyright 2019 Elsevier. (
c) Representative HAADF-STEM image of porous carbon-supported PtFeCoNiCuZn high-entropy alloy nanoparticles. (
d) ORR polarization curves of porous carbon-supported PtFeCoNiCuZn high-entropy alloy nanoparticles and the medium- and low-entropy counterparts and commercial Pt/C catalysts. Reprinted with permission from Ref. [
202]. Copyright 2022 Wiley.
Morphological regulation has been regarded as an efficient method to enhance ORR electrocatalysis, while the high-entropy alloys with anisotropic shapes are still difficult to synthesize in view of their harsh preparation conditions. Recently, several strategies have been presented to address this problem, such as the wet-chemical methods via introducing appropriate cap** agents or strong reductants [
203,
204], the use of templates to control the anisotropic growth of multimetal nanocrystals [
205] and the combination of auto-combustion and low-temperature reduction methods [
206]. To obtain high-performance, high-entropy alloy-based ORR electrocatalysts, Guo, et al. used Ag nanowires as the templates to achieve the construction of ultrathin 2D high-entropy alloy subnanometer ribbons with a thickness of ~0.8 nm (
Figure 12a,b) [
207]. Several elements were uniformly distributed in the subnanometer ribbons, demonstrating the successfully formation of high-entropy alloys (
Figure 12c). Note that this is the thinnest high-entropy alloy so far, and this method can be used to synthesize various high-entropy alloy subnanometer ribbons containing five to eight noble metal elements, such as senary PtPdIrRuAuAg, septenary PtPdIrRuAuRhAg and octonary HEA PtPdIrRuAuRhOsAg subnanometer ribbons. They demonstrated that the formation of high-entropy alloy subnanometer ribbons mainly involved the galvanic exchange pathway and co-reduction process during the wet-chemical synthesis, as well as the dealloying strategy realized the 2D structural evolution of the high-entropy alloy subnanometer ribbons (
Figure 12d). In alkaline conditions, the ORR mass activity of the optimized quinary PtPdIrRuAg subnanometer ribbons was 21.0 times higher than that of commercial Pt/C (
Figure 12e). After 10,000 potential cycles, there was almost no change in the ORR polarization curves of the PtPdIrRuAg, and over 30,000 potential cycles, the mass activities of PtPdIrRuAg were still as high as 2.42 A mg
Pt−1 and 0.95 A mg
PGMs−1, and their quinary high-entropy alloy phase and porous 2D structures can be well maintained (
Figure 12f,g), confirming the advantages of high-entropy alloys with anisotropic structures.
It has been found that the electrocatalytic behavior can be affected by the atomic ordering structures, which has been further extended into high-entropy alloy systems. Combining the advantages of high-entropy and ordered intermetallic structures, high-entropy intermetallics have been presented to serve as highly stable catalysts for ORR electrocatalysis [
187,
208]. However, the formation of high-entropy intermetallics not only needs to overcome the mutual solubility of various elements, but also needs to cross the energy barrier of disorder-to-order phase transition, challenging more severe synthesis problems of high-entropy intermetallics. In order to overcome this difficulty, ** new support materials to strengthen the interaction between active metals and supports. The corrosion of carbon is still the dominant reason why most catalysts cannot be reproduced in practical fuel cells, especially at such a large current. Although some strategies have been developed to improve the stability of traditional support materials, it is still difficult to meet the needs of long-term operation. Therefore, the development of new corrosion-resistant supports may provide an insightful scientific basis for the further commercialization of fuel cells in the future.
(2) Develo** the new catalyst systems to further eliminate the effect of poor durability of Pt-based catalysts. Although a large number of strategies have been reported to address the poor durability of Pt-based catalysts during the long-term ORR cycles, the influencing factors have not been thoroughly eliminated. For example, despite the loss of alloying metals in the ORR process which can be effectively reduced by the do** of a third metal, there will still be a leaching phenomenon, which still decreases the durability. Therefore, the development of new routes to further improve durability, especially focusing on the combination of reported strategies, will be necessary in the future.
(3) Establishing the relationship between the catalysts structure and ORR durability through in situ and ex situ characterizations. The rapid development of (sub)-nanomaterials has stimulated the requirement of more advanced characterizations. In terms of ultradurable Pt-based ORR catalysts, it is important to characterize the structure more accurately. Particularly, it is meaningful to reveal the structural evolution of the catalysts during the long-term ORR tests through in situ or ex situ characterizations. For example, using in situ synchrotron radiation technologies to reveal the change of metal bond length in Pt-based catalysts during ORR processes may help us to better understand the essence of catalyst durability enhancement. These advanced characterization techniques may guide us to design more effective catalysts.
(4) The application of ultradurable Pt-based catalysts in practical fuel cells. Most of catalysts have shown excellent catalytic performance under the condition of half-cell, but they are rarely used in practical fuel cells. This is mainly due to the fact that the harsh operating environment of proton exchange membrane fuel cells makes Pt-based catalysts more unstable. Therefore, it is very important to explore the attenuation behavior of these ultradurable catalysts in practical fuel cells and develop catalysts suitable for long-term durability and practical fuel cells. In addition, the decay behavior of catalysts under working conditions may be different from that under half-cell conditions, so understanding the evolution of catalyst structure under working conditions will also be a research trend in this field in the future.
In summary, it has been shown that the designs of ultradurable ORR catalysts have clearly contributed to the fast development of PEMFCs, and it has been believed that this is a research frontier in the material science community and will open up new possibilities to obtain more efficient catalysts for advanced energy conversion devices in terms of long-term operation conditions.