Abstract
Cathode catalysts are the key factor in improving the electrochemical performance of lithium–oxygen (Li–O2) batteries via their promotion of the oxygen reduction and oxygen evolution reactions (ORR and OER). Generally, the catalytic performance of nanocrystals (NCs) toward ORR and OER depends on both composition and shape. Herein, we report the synthesis of polyhedral Au NCs enclosed by a variety of index facets: cubic gold (Au) NCs enclosed by {100} facets; truncated octahedral Au NCs enclosed by {100} and {110} facets; and trisoctahedral (TOH) Au NCs enclosed by 24 high-index {441} facets, as effective cathode catalysts for Li–O2 batteries. All Au NCs can significantly reduce the charge potential and have high reversible capacities. In particular, TOH Au NC catalysts demonstrated the lowest charge-discharge overpotential and the highest capacity of ~20 298 mA h g−1. The correlation between the different Au NC crystal planes and their electrochemical catalytic performances was revealed: high-index facets exhibit much higher catalytic activity than the low-index planes, as the high-index planes have a high surface energy because of their large density of atomic steps, ledges and kinks, which can provide a high density of reactive sites for catalytic reactions.
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Introduction
The lithium–oxygen (Li–O2) battery is currently the subject of much scientific investigation as the power source for electric vehicles because of its high energy density (2–3 kWh kg−1).1 Unlike the intercalation reactions of Li-ion batteries,2 the reaction mechanism in a Li–O2 cell involves an oxygen reduction reaction (ORR) in the discharge process and an oxygen evolution reaction (OER) in the charge process, during which, molecular O2 reacts reversibly with Li+ ions (Li++ O2+2e−↔Li2O2, with an equilibrium voltage of 2.96 V vs. Li).3 The performance of Li–O2 batteries is constrained by several serious issues, such as poor cycling stability,4 electrolyte instability,5 low-rate capability6 and low round-trip efficiencies,1 mainly resulting from the high overpotential on charge.7 Recently, it was found that the catalyst and the proper non-aqueous electrolyte are the key factors to address these problems.8 Therefore, various electrocatalysts, including carbons, metal oxides, metal nitrides and precious metals have been examined as the cathode catalysts in Li–O2 cells to lower the charge overpotential.9 It was reported that the use of catalysts can decrease the charge potential to ~3.8 from~4.2 V.10 It has been shown, however, that the theoretical overcharge potential for a Li2O2 film is only 0.2 V, if there are no limitations on charge transport through Li2O2 to the Li2O2-electrolyte interface.11 Therefore, it is possible to further lower the charge potential. Moreover, a fundamental understanding of how to resolve the high overpotential on charge and the mechanisms of both ORR and OER, respectively in non-aqueous electrolytes are important for developing Li–O2 batteries.
Anisotropy is one of the basic properties of crystals, and different facets of a single crystal may exhibit different physical and chemical properties. In the past decade, control of the shape of metallic nanostructures has attracted intensive interests, because it may provide an effective route for tuning the catalytic properties of metals.12 It has been widely recognized that high-index facets, having a high density of atomic steps, ledges, kinks and dangling bonds, usually exhibit much higher chemical-reaction activities.13, 14 For example, a single-crystal Pt tetrahexahedral nanocrystal (NC) is enclosed by 24 high-index facets such as {730}, {210} and/or {520} surfaces. These NCs exhibited much enhanced (up to 400%) catalytic activity compared with equivalent commercial Pt catalysts toward electro-oxidation of small organic fuels.14 Therefore, for the Li–O2 battery, synthesis of noble metal NCs bounded by high-index facets could have the potential of significantly improve the catalytic performance toward ORR and OER.
In 2012, it was reported that porous gold foil is a good catalyst for a reversible and higher-rate Li–O2 battery with a high reversibility.15 Herein, we report the controllable synthesis of polyhedral Au NCs with different shapes and crystal planes, including trisoctahedral (TOH) Au NCs enclosed by 24 high-index {441} facets, and their catalytic properties in Li–O2 batteries. Electrochemical testing shows that all Au NCs can significantly reduce the charge potential and have high reversible capacities. In particular, the electrodes with TOH Au NC catalysts demonstrated the lowest charge-discharge overpotential, and the highest reversible capacity of about 20 298 mA h g−1. It was found that the essential factor in promoting the ORR and OER in the Li–O2 battery is the surface crystal planes of the Au NCs. The ORR and OER are crystal plane-dependent processes. Furthermore, the correlation between the different Au NC crystal planes and their electrochemical catalytic performance was revealed via density function theory calculations and experimental investigations: high-index facets ({441}) exhibit much higher catalytic activity than low-index planes ({111} and {100}), because of their high surface energy, which can provide a high density of reactive sites for catalytic reactions.
Experimental Procedure
Synthesis and method
Materials
Hydrogen tetrachloroaurate (III) hydrate (HAuCl4·xH2O, Sigma-Aldrich,Castle Hill, NSW, Australia, ~50% Au), hexadecyltrimethylammonium chloride (CTAC, Sigma-Aldrich ⩾98%), hexadecyltrimethylammonium bromide (CTAB, Sigma-Aldrich ⩾99%), sodium borohydride (NaBH4, Sigma-Aldrich 99.99%) and L-ascorbic acid (Sigma-Aldrich ⩾99%) were used as received.
Synthesis
The polyhedral Au NCs were prepared following a seed-mediated synthesis method in aqueous solutions.16 In a typical synthesis, 87.5 μl of 20 mM HAuCl4 solution was added to 7 ml of 75 mM CTAB solution and then 0.6 ml of 10 mM NaBH4 solution was injected into the mixture. After vigorous shaking to form a brown seed solution, the solution was set aside for another 2 h to decompose the excess NaBH4. The seed solution was then diluted 100-fold with distilled water for further use. A seed growth solution was prepared by adding 25 μl of 20 mM HAuCl4 solution and 0.387 ml of 38.8 mM ascorbic acid into 12.1 ml of 16.5 mM CTAB solution. Then, 0.15 ml of the 100-fold diluted seed solution was added, and the mixture was left undisturbed overnight until the color of the solution changed to pink, indicating the growth of the Au NC seeds.
Cubic Au NCs were prepared by adding 0.125 ml of 20 mM HAuCl4 solution and 3.06 ml of 38.8 mM ascorbic acid solution to 9 ml of 22 mM CTAB solution. Thereafter, 6.5 ml of the Au NC seed solution was added, and the mixture was left undisturbed overnight.
For the preparation of truncated octahedral (T-OCT) Au NCs, 1.33 ml of the Au NC seed solution was added to 12.5 ml of a mixture containing 16 mM CTAB, 0.04 mM HAuCl4 and 1.2 mM ascorbic acid. The solution was left undisturbed overnight.
The TOH Au NCs were prepared in a similar manner to the cubic Au NCs except for the substitution of CTAC for CTAB at the same concentration.
Structural and physical characterization
The crystal structure and phase of the as-prepared materials were characterized by X-ray diffraction (XRD, Siemens D5000, Aubrey, TX, USA) using Cu Kα radiation. The morphology was analyzed by field emission scanning electron microscopy (FESEM, Zeiss Supra 55VP, Jena, Germany). The details of the structure were further characterized by transmission electron microscopy (TEM) and high-resolution TEM (HRTEM, JEOL JEM-2011, Tokyo, Japan). Selected area electron diffraction (SAED) patterns were recorded by a Gatan charge-coupled device camera in a digital format. Atom resolved HRTEM images were obtained by high-angle annular dark field scanning TEM (HAADF-STEM, JEOL JEM-ARM200F). The optical images were collected with a Canon EOS 660D camera. Raman spectra were measured using a Renishaw inVia Raman spectrometer system (New Mills, Wotton-under-Edge, Gloucestershire, UK) equipped with a Leica DMLB microscope (Wetzlar, Germany) and a 17 mW at 633 nm Renishaw helium neon laser source. Fourier-transform infrared (FTIR) spectra were recorded on a Nicolet Magna 6700 FT-IR spectrometer (Thermo Fisher, Scoresby, VIC, Australia) with 0.9 cm−1 standard optical resolution by using a KBr beam splitter.
Electrochemical testing
Swagelok-type cells were designed to investigate the charge and discharge properties and the cyclability in Li–O2 batteries, which consists of a stainless steel cylinder plunger to support a Li foil anode (thickness: 3 mm, diameter: 15 mm) and a special stainless steel tube to allow oxygen access to the back side of the cathode. The cathode electrodes were prepared as follows: catalyst slurry was first prepared by mixing the as-prepared catalysts (90 wt.%) with poly(tetrafluoroethylene) (10 wt.%) in isopropanol. The mixture was then coated on a glass fiber separator. The cathode film was punched into discs having a diameter of 14 mm and dried at 110 °C in a vacuum oven for 12 h. The typical loading of the air electrode was ~1 mg carbon per cm2. The load mass of each electrode is ~1.6 mg, and the corresponding load mass of Au NCs catalyst is ~0.64 mg, calculated based on the weight percentage of Au NCs in the electrode (40 wt.%, as determined by the thermogravimetric analysis). The cathode was placed on the separator, and a thin open 316 stainless steel mesh was placed on top to act as a current collector. The entire cell was gas-tight except for the stainless steel mesh window, which exposed the porous cathode to the O2 atmosphere. The Li–O2 cells were assembled in an Ar-filled glove box (Unilab, MBRAUN, Garching, Germany) with water and oxygen levels <0.1 p.p.m. A glass microfiber filter (Whatman, diameter: 21 mm) separator was used, soaked in an electrolyte consisting of 1 M LiNO3 (99.99%, Sigma-Aldrich) in dimethyl sulfoxide (anhydrous, >99.9%, Sigma-Aldrich). All measurements were conducted in 1 atm dry oxygen atmosphere to avoid any negative effects of humidity and CO2. Galvanostatic discharge-charge was conducted on a Neware battery testing system. The specific capacity was calculated based on the mass of Super-P (SP) carbon black in the cathode electrode. In order to investigate the charge and discharge products and the corresponding structural and morphological changes, the cells were charged and discharged to the required voltages, and then opened in the glove box. The active materials were removed from the electrodes and washed with dimethyl sulfoxide before being used for ex-situ XRD, SEM, TEM, Raman and FTIR analyses.
Computational methods
The calculations were performed based on the density function theory approach17 with the ABINIT software package (Louvain-la-Neuve, Belgium).18 The exchange-correlation energy function was represented by the local-density approximation, employing ultra-soft pseudopotential formalism.19 We used an energy cut-off of 350 eV. Different Monkhorst-Pack k-point sets were used. The maximum self-consistent field convergent tolerance was <2 × 10−6 eV per atom. All calculations were performed in reciprocal space. For the surface energy calculation, the surface region was modeled as a finite number of two-dimensional infinite planes formed by cutting the crystal along a particular Miller index (hkl) plane. In each plane, a two-dimensional cell represents every site in the plane. Following the approach of Tasker20, several of these cells in successive planes comprise the basic repeated unit that has the composition of the bulk crystal unit cell. The surface energy per unit area, Ehklsurface, of a particular surface is calculated from the difference between the energy of the surface block, Esurface block, and the energy of the same number of bulk ions, Ebulk, per unit area, A (cross-sectional), and thus
The variations in energy of the Li–O2 reactions on the different facets of the polyhedral Au NCs, EhklLi–O2 reaction, were calculated from the difference between the (hkl) surface energy, Ehklsurface, the energy of Li2O2 monomer in vacuum, ELi2O2, and the total energy of the interacting system of the (hkl) Au surface substrate and the supported (Li2O2)n cluster, per unit area, A (cross-sectional), and thus
For a slab model construction, enough layers were used, and the depths of the surface regions were chosen to be large enough to ensure full relaxation of the surface ions and convergence of the surface energy. In each case, the surface structures were fully relaxed until the total energy difference converged within 0.001 eV.
Results and discussion
Morphology and crystal structure characterization
The experimental methods involved in the preparation of Au NC seeds and the subsequent addition of an appropriate quantity of the Au NC seed solution to the aqueous growth solutions. Supplementary Figure S1 shows the typical morphology of the Au NC seeds, which consist of a uniform octahedral shape and homogenous size distribution with an edge-to-edge width ~50 nm, and an apex-to-apex length of around 60 nm. The TEM images (Supplementary Figure S2) further reveal their octahedral architecture and narrow size distribution. The morphologies of the polyhedral Au NCs, which were observed by FESEM, as shown in Figure 1, depend on the concentrations of the Au NC seeds and the surfactant (CTAB, CTAC), in addition to the reactants (HAuCl4 and ascorbic acid). It can be seen that under the interaction between the Au NC seeds, surfactant and reactants, the Au NCs vary in terms of their polyhedral shapes: in ~11 mM CTAB and 0.134 mM Au3+ ion solution, adjusted by 6.35 mM ascorbic acid, Au nanocubes with square outlines were formed (Figures 1a–c6). From Figures 1a and b, it is clearly observed that the as-prepared Au nanocubes are neatly arranged with uniform particle size (~65 nm). Figures 1c1, c3, c5 shows the outlines of individual cubic Au NCs viewed from different directions ([100], [110] and [111], respectively), which have been illustrated by the corresponding geometric models (Figures 1c2, c4, c6, respectively). When reduce the concentrations of Au3+ ions and Au NC seeds to one-third and increase the CTAB concentration, T-OCT Au NCs were obtained, as shown in Figures 1d–f6. The uniform T-OCT shape and particle size distribution are shown in Figures 1d and e. The average crystal size was estimated to be ~65 nm. The individual T-OCT Au NCs, shown in Figures 1f1, f3, f5, present a different polyhedral shape with multiple facets along different orientations ([100], [110] and [111]), which are illustrated by the models in Figures 1f2, f4, f6, respectively. On using CTAC to replace CTAB as the surfactant in a similar manner as for the synthesis of cubic Au NCs, Au NCs with a different morphology were achieved. The representative FESEM images shown in Figures 1g–i6 confirm that the majority of NCs (>95%) have a concave TOH architecture, which is an octahedron with each of its facets capped by a triangular pyramid.21 It is therefore a polyhedron enclosed by 24 high-index {hhl} (h>l>0) facets. The good agreement between the high-magnification FESEM images of the NCs in different orientations ([100], [110] and [111]) and the corresponding geometrical models of a trisoctahedron (Figures 1i1–i6) confirms the TOH geometry of the Au NCs. Obviously, all of the factors, including the Au NC seeds, the surfactant and the reactants, were found to be inter-dependent for preparing different polyhedral Au NCs. The monodispersion of the three different shaped Au NCs can be seen from the FESEM images at different magnifications in Supplementary Figure S3–S5.
Detailed crystal structure of the Au NCs was characterized by TEM analysis. Figure 2a shows a low-magnification TEM image of the cubic Au NCs. These nanocubes have almost perfectly sharp edges, corners and well-defined faces. Figures 2b1–b6 shows TEM images of individual cubic Au NCs viewed along the [100], [110] and [111] directions, respectively, as evidenced by the atomic models shown below each TEM image. The lattice-resolved HRTEM image collected from the Au NCs along the [100] direction clearly presents different crystal planes with a 90° corner angle, indicating their single crystalline feature (Figure 2c). A further atomic resolved HAADF-STEM image of the (100) surface illustrates the square arrangement of atoms (Figure 2d). The characteristic square spot array of its corresponding fast-Fourier transform (FFT) pattern can be indexed along the [100] zone axis of Au (Figure 2e), which confirms that the Au nanocubes are enclosed by {100} facets, as demonstrated by the simulated atomic arrangement of the Au (100) crystal plane (inset in Figure 2d). The regular atomic arrangement within the homogenous surface indicates its good crystallinity. The (020) and (011) crystal planes with lattice spacings of 0.20 and 0.288 nm, respectively, and an interfacial angle of 45° can be directly observed (Figure 2d). TEM images of T-OCT Au NCs are shown in Figures 2f–j. All the T-OCT Au NCs have well-defined facets, as shown in the low-magnification TEM image (Figure 2f). Figures 2g1–g6 shows the outlines of T-OCT Au NCs lying along different orientations (g1: [100], g3: [110] and g5: [111]). The corresponding atomic models of these T-OCT Au NCs (Figures 2g2, g4, g6) clearly present their profiles, proving that Au NCs are enclosed by 14 well-defined facets. Figure 2h shows a typical lattice-resolved HRTEM image of a T-OCT Au NC that lies flat along the [111] zone axis, obtained by directing the electron beam perpendicular to the upper face of the NC. It exhibits a hexagonal shape that lies partly out of frame, with a 120° corner angle, due to the special face-up direction. Figure 2i shows an atom-resolved HAADF-STEM image taken from Figure 2h, in which the and crystal planes with 0.144 nm d-spacing can be directly observed. Together with its corresponding indexed FFT pattern (Figure 2j), it confirms that the exposed facets should be {111}. The atomic resolved HAADF-STEM image further demonstrates the regular hexagonal atom arrangement of the Au {111} surfaces, which is consistent with the simulated atomic array of Au {111} facets (inset in Figure 2i).
TOH Au NCs bounded by high-index facets were formed at high yield. Figure 3a shows a typical low-magnification high-angle annular bright field TEM (HAABF-STEM) image of the monodisperse TOH Au NCs. The concave TOH outlines of individual Au NCs can be observed in the corresponding HAADF-STEM and secondary electron STEM images (Figures 3b and c). The oriented TOH Au NCs in the high-magnification HAADF-STEM images (where Figures 3d1, d3, d5 and d7) corresponds to the [100], [110], [111] and [441] orientations, respectively) are consistent with the geometrical models of a concave TOH (Figures 3d2, d4, d6 and d8), respectively) when viewed from different directions. The corresponding HAABF-STEM and secondary electron scanning TEM images are shown in Supplementary Figure S6 in the Supplementary Information. The white solid lines marked in Figures 3d1, d3, d5 were used to accentuate the edges and angles that form the outline of the triangular pyramids sitting on the octahedral facets. It can be seen from Figure 3d4, that when a TOH is viewed along the [110] direction, four edge-on facets can be projected, as indicated by the arrows.22 The Miller indices of the edge-on facets of a TOH can be determined through an analysis of the projection angles.23 The values of the three different angles, α, β and γ, corresponding to different Miller indices of a perfect TOH crystal, are given in Supplementary Table S1.16, 17 The angles of the projection have been measured and are marked in the Figure 3d3. By comparing the measured angles with the calculated values in Supplementary Table S1, we found that the TOH Au NCs were bounded by {441} facets. Figure 3e shows an atomic resolved HAADF-STEM image of a TOH Au NC taken along the [110] direction, as confirmed by its corresponding FFT pattern (top-left corner inset of Figure 3e), in which the (002) and crystal planes with 0.2 and 0.235 nm d-spacings, respectively, can be directly observed. The atom arrangement of {110} facets was also simulated by the model shown in the middle inset of Figure 3e. In this model, the projected {110} {111}, {221}, {331} and {441} crystal planes along the [110] direction can be observed directly. By comparison, only the projected {441} crystal plane can match the atomic arrangement on the edge of the atomic resolved HAADF-STEM image, which can confirm that the edge-on facet in Figure 3e is the (441) surface. Furthermore, it can be seen that the {441} crystal plane can be considered of as a combination of (110) terraces and a (001) step. When the {110} surface is rotated 10° along the [001] axis, the {441} facet is exposed, as shown in Supplementary Figure S6d2. With smaller d-spacings, the and crystal planes (0.144 and 0.099 nm, respectively) were observed in the atomic resolved HAADF-STEM image. Through the corresponding FFT pattern (Supplementary Figure S6d3), it can be confirmed that the exposed facets should be {441}, according to the indexed crystal plane spots.
Owing to the different crystal planes exposed by the three polyhedral Au NCs, different colors are presented when they are dispersed in an aqueous solution, as shown in Supplementary Figure S7. More TEM images in the Supplementary Information (Supplementary Figure S8-S10) show the uniform crystal size distribution and more morphological, surface and crystal structural information of the three different types of polyhedral Au NCs.
The Miller indices of high-index facets could also be identified from the atomic arrangement in the edge-on facets. High-index planes can be exhibited as ordered terrace-step structures, m(htktlt) × (hsksls), which means m atomic widths of (htktlt) terraces with a monatomic (hsksls) step.22 Accordingly, the {111}, {221}, {331} and {441} planes consist of 1, 2, 3 and 4 atomic widths of (110) terraces with one (001) step, respectively, as shown in Supplementary Figure S11a. The atomic models of {100}, {111} and {441} planes are shown in Supplementary Figures S11b, c1 and d1, respectively. Supplementary Figures S11c2 and d2 illustrates the {111} and {441} crystal planes projected from the zone axis, from which it can be clearly seen that the atomic arrangement of the {441} facets is periodically composed of four atomic widths of (110) terraces, followed by one atomic width of a (001) step, which is, a multiple height-stepped structure. These steps have been directly captured in the atomic resolved HAADF-STEM image (top-left corner inset of Figure 3e). The atomic model of the {441} facet has a high density of stepped surface atoms compared with the {111} facet.
Growth mechanisms
The formation of NCs with geometrical shapes is controlled by the reaction microenvironment.24 Selective ‘face-blocking’ and the reduction rate of the metal ions governs the growth kinetics. The former involves the selective adsorption of species in the growth solution onto specific crystallographic facets, hindering the access to these facets of the metal atoms that are being deposited, and on contrary, promoting the relative growth rates of other facets. The latter determines the speed at which the metal atoms are deposited.
Our reaction system contained three species that could act as the selective ‘face-blockers’, the reducing agent (ascorbic acid), the gold precursor (HAuCl4) and the capping agent (surfactant: CTAB or CTAC). The large cationic surfactant molecule CTA+ would play the pivotal role as a face-blocking agent in the formation of polyhedral Au NCs. It is believed that the shape of the fine Au seeds produced in the presence of CTAB is faceted with the most stable {111} facets, which are solvent-accessible.25 CTAB molecules appear to bind more strongly to the {100} than the {111} facets.26 Thus, lower CTAB concentration conditions favor the faster deposition of Au atoms onto the {111} facets, leading to their disappearance, and the formation of {100} facets, thereby producing cubic shapes. Under slightly higher CTAB concentrations, one could expect truncated polyhedra with both {100} and {111} faces.27 When CTAB was replaced by CTAC at the same concentration in the synthesis, TOH Au NCs bounded by {441} facets dominated in the final product. The difference between CTAB and CTAC is in the anions (Br− and Cl−). The competition between Cl− and CTA+ for adsorption on the gold NC surface could be the cause of the TOH morphology. As Cl− has a lower affinity to gold than Br−,28 Cl− would preferentially adsorb on the gold surface to create a negatively charged layer, where CTA+ could subsequently bind through electrostatic interactions.29 Pre-adsorbed Cl− cannot screen the selective adsorption of CTA+ on the high-index facets because of its lower affinity compared with Br−. Binding of the large [NMe3]+ head group of CTA+ (diameter=0.814 nm) and its associated long alkyl tail can be more easily accommodated on less closely packed high-index planes than on low-index planes.26, 30 This is because the Au atomic spacing of high-index planes is comparable to the size of the CTA+ head group.31 Therefore, when gold atoms reduced from the reaction mixture are deposited on the surface of a seed, CTA+ would selectively bind to the high-index facets, thereby preventing the latter from growing as fast as the others. With the deposition of more Au atoms, more high-index facets are created and protected by CTA+, while the low-index facets slowly disappear, facilitating the formation of TOH NCs.32 Besides the capping agent, an appropriate reduction rate is necessary to sustain the polyhedral shape. The concentration of the reducing agent (ascorbic acid) in the growth solution provides the means to alter the rate of generation of the Au atoms.32
Electrochemical performance of Au NCs@SP in Li–O2 cells
The electrocatalytic activities of three different polyhedral Au NCs catalysts loaded on carbon black (Super-P, SP) were examined in Li–O2 cells and compared with bare SP. The loaded Au NCs catalysts were around 40 wt.% as revealed by thermogravimetric analysis (Supplementary Figure S12). The galvanostatic charge-discharge measurements were carried out to evaluate the electrochemical performances in the voltage range of 2.0–4.3 V for Au NCs@SP and 2.0–4.6 V for bare SP at room temperature. Typical charge-discharge voltage profiles are shown in Figure 4a. The initial discharge capacities of the polyhedral Au NCs@SP electrodes are significantly higher than that of the bare SP electrode (8980 mA h g−1). Furthermore, the TOH@SP electrode achieved the highest discharge capacity, 20 298 mA h g−1, followed by the T-OCT Au NCs@SP and cubic Au NCs@SP electrodes (16 245 and 14 115 mA h g−1, respectively). The discharge plateau of the Au NCs@SP electrodes is slightly higher than that of the bare SP electrode (2.68 V) and shows an increasing tendency in the order of cubic Au NCs@SP<T-OCT Au NCs@SP<TOH Au NCs@SP, indicating that the polyhedral Au NCs have catalytic activity toward the ORR. In the charge process, significant differences in the charge plateau were observed between the polyhedral Au NCs@SP electrodes and the bare SP electrode (4.38 V for the bare SP electrode, <3.77 V for the polyhedral Au NCs@SP electrodes). The polyhedral Au NCs@SP electrodes show much lower charge plateaus than the bare SP electrode, illustrating the excellent catalytic activity toward the OER of the Au NC catalysts. The overpotential between the charge and discharge processes has been significant decreased by adding the polyhedral Au NC catalysts. The TOH Au NCs@SP electrode presents the lowest charge potential (3.68 V), followed by the T-OCT Au NCs@SP and cubic Au NCs@SP electrodes in order (3.72 and 3.76 V, respectively), suggesting that the different crystal planes of Au NCs have different catalytic activity toward the OER. When cycling the polyhedral Au NCs@SP electrodes at high current density (400 mA g−1), a similar tendency can be observed, as shown in Supplementary Figure S13. The TOH Au NCs@SP electrode also achieved the highest capacity, 14 593 mA h g−1, followed by the T-OCT Au NCs@SP and cubic Au NCs@SP electrodes (13 665 and 12 991 mA h g−1, respectively). Moreover, the TOH Au NCs@SP electrode demonstrated the lowest overpotential, 0.95 V (2.82 V for discharge potential, 3.77 V for the charge potential), as shown by the differential profiles of the charge-discharge curves (Supplementary Figure S13b). Moreover, the sharp reduction peaks during the cathodic process indicate the good catalytic activity of polyhedral Au NCs@SP electrodes toward the ORR, while the strong oxidation peaks in the anodic process indicate the good catalytic activity toward the OER. Furthermore, from the long cycle performance of full charge and discharge (Supplementary Figure S14), it can be seen that the TOH Au NCs@SP electrodes still maintain the high discharge capacity.
The electrochemical performance of polyhedral Au NCs@SP electrodes was further examined by restricting the capacity during cycling at various current densities. Supplementary Figure S15 shows the voltage profiles of polyhedral Au NCs@SP electrodes cycled at 200 mA g−1 with the capacities restricted to 1000 mA h g−1. It can be seen that all the polyhedral Au NCs@SP electrodes display a discharge plateau at about 2.8 V. Furthermore, the TOH Au NCs@SP electrode presents the lowest charge plateau, at 3.63 V, as revealed by the differential profiles (Supplementary Figure S16a). By comparison with the bare SP electrode, the TOH Au@SP electrode largely decreases the overpotential, as shown in Figure 4b. The low charge potentials of these polyhedral Au NCs@SP electrodes can be maintained at the tenth cycle, and the TOH Au NCs@SP always yields the lowest values compared with the T-OCT Au NCs@SP and cubic Au NCs@SP electrodes (Supplementary Figure S15). When the current density was increased to 500 mA g−1, the same trend was also observed (Supplementary Figure S16b). The TOH Au@SP electrode can sustain cycling for more than 30 cycles, while the bare SP electrode failed after 18 cycles, as shown in Figure 4c. Even when the current density was increased to 1000 mA g−1, the TOH Au NCs@SP electrode still presented much a lower charge plateau than the T-OCT Au NCs@SP and cubic Au NCs@SP electrodes (Supplementary Figure S16c). As confirmed by the differential profiles of the charge curves (Supplementary Figure S16d). These observations indicate that polyhedral Au NCs with different exposed crystal planes have different catalytic activity toward OER. In particular, the TOH Au NCs achieved the highest catalytic activity toward the OER.
To identify the charge and discharge products, we conducted ex-situ XRD, SEM and TEM measurements. As confirmed by the ex-situ XRD pattern (Supplementary Figure S17) of the TOH Au NCs@SP electrode, the main discharge products are Li2O2 (JCPDS Card No. 09-0355), with hexagonal symmetry (space group: . After being fully charged, the Li2O2 was totally decomposed, which was also confirmed from the ex-situ XRD patterns. The morphologies of the TOH Au NCs@SP electrode in the fully discharged and charged states were analysed by ex-situ FESEM and TEM (as shown in Figure 5). From Figure 5a, it can be seen that after being full discharged, the TOH Au NCs@SP electrode was covered with the discharge product Li2O2. For comparison, a FESEM image of the pristine TOH Au NCs@SP electrode is presented in Supplementary Figure S18. From the high magnification FESEM image (Figure 5b), it can be identified that the Li2O2 has toroid-like morphology with~500 nm particle size, which is similar to previously reported Li2O2 morphology.9, 33 The ex-situ TEM image shows that the Li2O2 features wrinkles (Figure 5c), which are composed of the Li2O2 NCs, and its corresponding SAED pattern can be well indexed as crystalline hexagonal Li2O2 (Figure 5d). When we fully charged the cell, all the discharge products completely disappeared (Figures 5e and f). The corresponding ex-situ TEM images of the charged electrode are shown in Figures 5g and h, along with TEM images of the amorphous carbon (SP) and well crystallized Au NCs after the cycling. The inset of Figure 5g shows the HRTEM image of the Au NC and SP; while the inset of Figure 5h is the SAED pattern, demonstrating the preservation of the crystalline features of the Au NCs after cycling. These results suggest the high reversibility of the TOH Au NCs@SP electrode. Similarly, the cubic Au NCs@SP and T-OCT Au NCs@SP electrodes also yielded the toroid-shaped Li2O2 discharge products, which could be completely oxidized and removed from the surface after the charging process, as shown in Supplementary Figures S19 and S20, respectively.
To confirm the main discharge products after long cycling, the fully discharged TOH Au NCs@SP electrodes after 20 cycles were investigated by ex-situ XRD, Raman and FTIR measurements. From the ex-situ XRD patterns (Supplementary Figure S21), it can be seen that the peaks at around 23°, 33°, 35°, 40° and 58° (as marked by the red solid circle) indicate the formation of Li2O2, while the peaks at around 21°, 30°, 32°, 37° and 53° (as marked by the black star) can be assigned to the by-product LiOH·H2O. Raman and FTIR measurements further confirmed the discharge products (as shown in Supplementary Figures S22 and S23, respectively). In the Raman spectrum, two main Raman shifts at 1320 and 1600 cm−1 correspond to the D-bond and G-bond of carbon. The Raman shifts at around 260, 787 and 2630 cm−1 prove the existence of Li2O2. The broad peak at 2919 cm−1 could be assigned to LiOH·H2O. From the FTIR spectrum, the formation of Li2O2 can be further identified by the peak at around 470 cm−1. The other peaks in the FTIR spectrum demonstrate the by-product LiOH·H2O, which could originate from trace moisture in the electrolyte.
Mechanism of Li2O2 formation
A possible mechanism for the Au NCs ORR/OER activity is shown in Scheme 1. As previously determined,33, 34 the O2 is first bound to the cathode surface via the oxygen vacancies, especially on the carbon defect sites and Au NC catalyst, followed by reduction to O2−. The stabilized superoxide ion could be combined via the dismutase reaction to form Li2O2.33 This mechanism is supported by the presence of large (~500 nm) uniform toroid-shaped Li2O2 particles formed on discharge. Additionally, as revealed by the TEM images, the large toroid-shaped Li2O2 particles are composed of aggregates of Li2O2 NCs. This provides evidence for proposing that the solvated LiO2 is initially formed when the ORR catalysis reaches a local high saturation concentration. The Li2O2 nucleates to create NCs because of its low solubility and is gradually deposited to form the observed ‘tortellini’ aggregate morphology.33
For the OER process on charge, it was proposed that the peroxide is decomposed into Li+ and O22− on the vacant catalyst sites first, and then stepwise oxidized to O2− and O2, which can be proved by the ex-situ SEM and TEM images. The catalyst stability was demonstrated after ten cycles, as evidenced by Supplementary Figure S24, where the toroids are obtained on the discharge process and completely disappear after the charge process.
The electrochemical performance of the polyhedral Au NCs@SP electrodes clearly demonstrates that the Au NCs with different exposed crystal planes have different effects on the catalytic activity toward the ORR and OER in the Li–O2 battery. In principle, the NCs’ properties are determined by the exposed crystal facets.35, 36 NCs that have particular exposed crystal planes with high-index facets could achieve improved chemical or physical performances, because high-index facets have high densities of atom steps, edges, kinks and dangling bonds, which usually have high chemical activity.37 Therefore, the surface properties are expected to play a key role in understanding the electrochemical behavior in Li–O2 systems. Obviously, the cubic Au NCs, T-OCT Au NCs and TOH Au NCs are enclosed by different facets ({100}, {111} and {441} crystal planes) with different arrangements of atoms, which may be responsible for the different ORR and OER performances.
To investigate the various catalytic activities of the polyhedral Au NCs, we conducted density function theory calculations on the different Au crystal planes and their interaction with the Li and O atoms. The relaxed surface energies and interaction energies with Li and O atoms of different Au crystal planes are listed in Table 1. The {100} crystal plane has the lowest surface energy of 1.32 J m−2, suggesting that it is the most stable facet. The {111} crystal planes show relatively higher surface energy (1.60 J m−2). The most active crystal planes for Au are the {441} facets, with the highest surface energy of 2.55 J m−2, which is almost twice that of the {100} crystal planes. The atomic arrangement of the Au {441} surface is composed of a periodic multiple height-stepped structure (as shown in Supplementary Figure S11),38 which could present high reactivity,39 resulting in the high surface energy. As for the interaction between different crystal planes of Au and the Li and O atoms, it can be observed that as the surface energy of the Au crystal planes increases, the interaction energy between the Au and the Li and O atoms decreases. The {441} crystal planes yield the lowest interaction energy (1.64 J m−2), while {100} crystal planes show the highest value (4.00 J m−2). Apparently, the {441} crystal planes show the highest activity because of their high surface energy, which can provide more reactive sites to facilitate the interaction with Li and O atoms, and therefore, they consume the lowest energy to accomplish the Li and O reactions. Recently, it was reported that the oxygen adsorption energy on the surface can significantly influence the Li+ oxygen reduction activity.40 The oxygen adsorption energy on the surface of the {441} crystal planes is lower than for the {100} and {111} crystal planes, which makes TOH Au NCs more active toward the OER, leading to an enhanced electrochemical performance. Similarly, cubic Au NCs and T-OCT Au NCs presented the gradually improved catalytic activity toward the ORR and OER because their exposed facets ({100} and {111}) have lower oxygen adsorption energy, which promotes a decrease in the discharge-charge overpotential.
Furthermore, the calculated densities of states for the {100}, {111} and {441} crystal planes of Au NCs clearly demonstrate their interaction with those of the Li and O atoms due to the overlapping densities of states curves (as shown in Figure 6). The corresponding electron density plots ((b), (d) and (f) in Figure 6), showing the electron distribution between each crystal plane and the Li and O atoms, confirm that the different crystal planes of Au NCs could provide varied reactive sites for the reaction between Li and O atoms. Among them, the {441} crystal planes present the largest amount of interaction sites with Li and O atoms (Figure 6f), which can be verified by the presence of more overlapping electron orbitals between Au, Li and O at the Fermi level (densities of states curve in Figure 6e), suggesting that they have the highest catalytic activity toward the Li and O reaction. The enhanced electrocatalytic activity of Au NCs with exposed high-index surfaces has also been demonstrated previously.14, 41 Therefore, the TOH Au NCs@SP electrode achieved the best electrochemical performance.
Catalysts play a critical role in increasing the discharge capacity and reducing the charge and discharge overpotential. It was reported that catalyst surface area is very important to affect electrochemical performances of Li–O2 battery,42 because the kinetics of most catalytic reactions are surface area dependent.43 The Super-P carbon has a high surface area, resulting in the faster reaction rates per gram of carbon and more active surface sites for Li2O2 deposition, which also benefit for the increase of discharge capacity.44
The homogenous distribution of catalyst nanoparticles is another reason for the improvement of catalytic effects, because the uniform Au NCs significantly decrease agglomeration and the small SP particles (~50 nm) provide an efficient surface for loading catalyst nanoparticles. From Figure 5, it can be seen that even after significant Li2O2 deposition, the original morphology of SP is well maintained. Au NCs are clearly visible in the ex-situ TEM image (Figure 5g), which expose with sufficient active surface for catalytic reactions.
Conclusion
In summary, we report the synthesis of polyhedral Au NCs with different exposed crystal planes: cubic Au NCs with {100} exposed facets, T-OCT Au NCs with {100} and {110} exposed facets, and TOH Au NCs with 24 high-index {441} exposed facets. As effective cathode catalysts for the Li–O2 batteries, the electrochemical testing shows that all the Au NCs can significantly reduce the charge overpotential via their effects on the OER and achieve high specific capacity, leading to enhanced electrochemical performances. In particular, the TOH Au NC catalysts demonstrated the lowest charge overpotential (~ 0.9 V) and the highest reversible capacity of about 20 298 mA h g−1. From the comparison of the catalytic performances of different Au NCs, it is revealed that the essential factor in promoting the ORR and OER of Au NCs is the surface crystal planes. The correlation between different Au NC crystal planes and their catalytic activity was established: {100}<{111}<{441}, which was verified by density function theory calculations and experimental investigations. As revealed by the ex-situ XRD, SEM and TEM measurements, we also proved that polyhedral Au NC catalysts can effectively decompose the discharge product Li2O2, facilitating the OER, leading to a high round-trip efficiency, and present superior cycling stability. This study demonstrates that Au NCs, especially with exposed high-index facets, could be effective cathode catalysts for high performance Li–O2 batteries.
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Acknowledgements
This original research was proudly supported by the Commonwealth of Australia through the Automotive Australia 2020 Cooperative Research Centre (AutoCRC). The authors acknowledge use of the facilities and the assistance of Dr Gilberto Casillas at the UOW Electron Microscopy Centre. The authors thank Dr Tania Silver for critical reading.
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Su, D., Dou, S. & Wang, G. Gold nanocrystals with variable index facets as highly effective cathode catalysts for lithium–oxygen batteries. NPG Asia Mater 7, e155 (2015). https://doi.org/10.1038/am.2014.130
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DOI: https://doi.org/10.1038/am.2014.130
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