Synthesis of NiMn-LDH Nanosheet@Ni3S2 Nanorod Hybrid Structures for Supercapacitor Electrode Materials with Ultrahigh Specific Capacitance

One of the key challenges for pseudocapacitive electrode materials with highly effective capacitance output and future practical applications is how to rationally construct hierarchical and ordered hybrid nanoarchitecture through the simple process. Herein, we design and synthesize a novel NiMn-layered double hydroxide nanosheet@Ni3S2 nanorod hybrid array supported on porous nickel foam via a one-pot hydrothermal method. Benefited from the ultrathin and rough nature, the well-defined porous structure of the hybrid array, as well as the synergetic effect between NiMn-layered double hydroxide nanosheets and Ni3S2 nanorods, the as-fabricated hybrid array-based electrode exhibits an ultrahigh specific capacitance of 2703 F g−1 at 3 A g−1. Moreover, the asymmetric supercapacitor with this hybrid array as a positive electrode and wood-derived activated carbon as a negative electrode demonstrates high energy density (57 Wh Kg−1 at 738 W Kg−1) and very good electrochemical cycling stability.

Development of highly efficient energy storage devices is urgently needed to meet the increasing requirement for electrical energy supply in daily life. As one of the most promising types of energy storage devices, supercapacitors (SCs) have been applied in the fields of back-up power systems, portable electronics, telecommunications, vehicles, and so on, for storing the intermittent electrical energy [1][2][3] . As the key contributor of energy storage of SCs, electrode materials strongly affect the development of SCs, thereby are attracting considerable research interests [3][4][5][6][7][8] . Pseudocapacitive metal oxides/hydroxides (e.g., MnO 2 , NiO, Ni(OH) 2 , Co 3 O 4 , Co(OH) 2 , NiCo 2 O 4 ) have been extensively built for use in supercapacitors over the past decades, due to their high energy densities and specific capacitances obtained through fast and reversible faradaic reactions [9][10][11][12][13][14][15][16] . Recently, transitional metallic layered double hydroxides (LDHs), such as NiAl-LDH, NiCo-LDH, and NiMn-LDH, have attracted much attention in supercapacitor electrode materials, owing to their low cost, tunable compositions, layered structures, and potential high electrochemical activities [17][18][19][20][21] . In most cases, however, their unoptimized micro-nanostructure and poor conductivity may lead to insufficient electrolyte access and sluggish charge separation, which in turn hinder the capacitance output of these LDHs 22,23 . Two elegant strategies have been proposed recently to work out the above problems: One is to build up an integrated hierarchical architecture via self-assembling LDHs onto specific carbon backbones such as carbon nanotubes, graphene, in which carbon skeletons can not only contribute certain electric double-layer capacitance but also improve the dispersion and electron transport of LDHs, and hence to realize the sufficient utilization of LDHs active materials 17,18,20 . For instance, the NiAl-LDH/reduced graphene oxide superlattice prepared by self-assembly at an atomic scale exhibited two times higher capacity versus pristine NiAl-LDH when used as the active materials for alkaline hybrid supercapacitor 20 . Another strategy is spectrum in Fig. 1a shows the presence of O, S, Mn and Ni elements in the as-prepared hybrid materials, except for the C and Al elements from the conductive adhesive carbon tape coated on scanning electron microscope (SEM) aluminum sample holder. The middle line in Fig. 1b demonstrates the typical X-ray diffraction (XRD) pattern of the sample obtained with urea plus thiourea as anion sources. Except for the three sharp peaks originating from the Ni foam substrate, the sample has five well-defined diffraction peaks located at 2θ values of 10.9, 22.1, 34.0, 38.0, and 59.5°, which can be successfully indexed to (003), (006), (012), (015) and (110) plane reflections of hydrotalcite-like LDH phase with an average interplanar spacing (d 003 ) of 8.11 Å 30,31 , indicating NiMn-LDH structure. In addition, this sample also displays three weaker peaks at 21.5, 31.0, and 55.2°, corresponding to the (101), (110) and (122) plane reflections of Ni 3 S 2 (JCPDS 44-1418). Thus, the sample obtained with urea plus thiourea as anion sources should be composed of NiMn-LDH and Ni 3 S 2 . The full X-ray photoelectron spectroscopy (XPS) spectrum further proves the basic element composition of as-obtained hybrid material, Ni, Mn, O, and S elements (Supplementary Figure S1a middle line). In Ni 2p XPS spectrum of hybrid material, two shakeup satellites (indicated as "Sat. ") close to two spin-orbit doublets at 873.1 and 855.5 eV are here given as Ni 2p 1/2 and Ni 2p 3/2 signals (Fig. 1c) , respectively, suggesting the existence of Ni 2+ state [32][33][34] . The Mn 2p XPS spectrum displays Mn 2p 3/2 and Mn 2p 1/2 spin-orbit peaks at 642.0 and 653.0 eV (Fig. 1d), indicating the appearance of Mn 3+ in as-obtained sample 32 . In the S 2p XPS spectrum (Fig. 1e), the peaks at 162.0 and 163.8 eV with the addition of a satellite peak at 168.6 eV can be assigned to S signal in Ni 3 S 2 phase 35 . Moreover, the Raman spectrum of as-prepared hybrid material (Figure S1b) displays three peaks at 345, 543 and 1040 cm −1 , which can be assigned to the characteristic bands of Ni 3 S 2 , the metal-oxygen-metal (M-O-M) bonds of NiMn-LDH, and the CO 3 2in the interlayers of NiMn-LDH, repectively 36,37 . All these results indicate that the NiMn-LDH@Ni 3 S 2 hybrid structure has been indeed formed. In addition, Fig. 1b and Figure S1c also compare the XRD patterns of the samples supported on Ni foam obtained with thiourea (upper line), urea plus thiourea (middle line) and urea (lower line) as anion sources, respectively. Based on these XRD patterns, the sample prepared with pure thiourea as the anion source is identified as a composite material composed of α-Ni(OH) 2 (JCPDS 38-0715), β-Ni(OH) 2 (JCPDS 14-0117), and Ni 3 S 2 (JCPDS 44-1418). The absence of Mn may be attributed to the Mn element embed into the crystal lattice of nickel-based phases. Meanwhile, the sample synthesized with individual urea as the anion source is found to be pure NiMn-LDH. These results suggest that both urea and thiourea play important roles in the synthesis of NiMn-LDH@Ni 3 S 2 hybrid arrays. Furthermore, Fig. 1f displays the XRD patterns of the samples supported on Ni foam prepared with individual manganese ions (upper line), nickel-manganese ions (middle line) and pure nickel ions (lower line), respectively. Without Ni 2+ addition, the as-synthesized product can be identified as a mixture of Mn(OH) 2 (JCPDS 18-0787) and MnO 2 (JCPDS 42-1316) phases by XRD pattern, while the sample prepared without Mn 2+ was found to be composed of β-Ni(OH) 2 (JCPDS 14-0117) and Ni 3 S 2 (JCPDS 44-1418) phases. Figure 2a shows that the nickel foam skeletons are uniformly covered with hierarchically structured materials, which can be further confirmed by SEM elemental mappings (Supplementary Figure S2a). This product contains two parts. (i) The white aggregates on the surface seem to be composed of short nanorods with the diameter of 6-20 nm ( Figure S2b). Based on the EDX spectrum and elemental mappings of a typical aggregate ( Figures S2c,d), it can be deduced that its main ingredient should be Ni 3 S 2 . (ii) The main active materials covering on the nickel skeleton are identified as vertically aligned nanosheets with the thickness of around 10 nm as indicated by the inset of Fig. 2a. Notably, these nanosheets are in the form of interlocked arrays with obvious space among adjacent nanosheets. Interestingly, the SEM image at higher-magnification reveals that there also exist some short nanorods attached to the surfaces of nanosheets (Fig. 2b). And most nanorods have been merged into nanosheets as the skeleton of nanosheets, producing rough surfaces.
Typical TEM images further manifest the as-obtained hybrid arrays contain nearly transparent ultrathin nanosheets and well-dispersed nanorods ( Fig. 2c and Supplementary Figure S3a (122) crystal planes of Ni 3 S 2 and (006) and (110) crystal planes of NiMn-LDH can be clearly observed in the inset of Fig. 2c. Meanwhile, two sets of orderly arranged spots with hexagonal-like symmetry is found in the SAED pattern of typical nanorod (the inset of Supplementary Figure S3b), which can be ascribed to the reflections from (110) and (122) crystal planes of Ni 3 S 2 . The lattice fringes with average interplanar spacing of 0.26 and 0.29 nm in the high-resolution TEM (HRTEM) image of hybrid material correspond well to the (012) plane of NiMn-LDH and the (110) plane of Ni 3 S 2 , respectively (Fig. 2d). These results further prove that the nanosheets in hybrid structures should be NiMn-LDH, while the nanorods that coexist with nanosheets are Ni 3 S 2 . In addition, the powder of this hybrid structure is found to have a BET surface area of 56.6 m 2 g −1 and an average pore diameter of 15.8 nm, respectively (Supplementary Figure S4). This novel NiMn-LDH nanosheet@Ni 3 S 2 nanorod hybrid arrays have not been reported based on the best of our knowledge, and are expected to have excellent electrochemical activity.
Formation mechanism of hybrid structures. Since the NiMn-LDH phase is dominant indicated by the XRD pattern (middle line of Fig. 1b), the hybrid structures probably form based on a mechanism similar to the preferentially oriented growth of LDH nanosheets described in our and others' previous reports 19,38 . As illustrated by the step a-b-c-d in Fig. 3, at 90 o C processing temperature, Ni 2+ and Mn 2+ first react with OH − ions to produce nickel and manganese hydroxides, which precipitate and grow into the primary particles. These primary particles rapidly aggregate into chains which partly deposit on the surface of the nickel substrate to become the aggregation cores. As the other primary particles continue to aggregate, an olation reaction occurs between these particles due to the random dispersion of nickel and manganese hydroxide primary particles. And then they begin to crystallize and grow along the c-axis, gradually forming NiMn-LDH nanosheets 39,40 . In the SEM image of the   Figure S5a), very small nanosheets are found to have formed. Moreover, the high-magnification image displays that these small sheets should origin from the chain-like aggregates on the nickel substrate ( Figure S5b). After 1 h, the as-obtained intermediate product is identified as some interlaced nanosheets with medium size and poor orientation ( Figure S5c). The orientation of nanosheets is improved after 4 h of reaction, and the sheet size increases visibly ( Figure S5d). These results well support the proposed formation mechanism above. Until this stage, only NiMn-LDH nanosheets form, that is confirmed by the XRD result of this intermediate product (Supplementary Figure S6a). Because the solubility constant (K sp ) of Mn(OH) 2 is three orders higher than that of Ni(OH) 2 41 , thus the ratio of Ni to Mn (16.1:1) in the formed NiMn-LDH is far higher than the initial feeding ratio (2.0:1). In addition, owing to lower solubility of Ni 3 S 2 , the S 2− ions released by the hydrolysis of thiourea further react with outer surfaces of NiMn-LDH nanosheets to produce Ni 3 S 2 particles at 110 o C reaction temperature. Because there isn't obvious difference in the solubility between manganese hydroxide and sulfide, very few Mn 2+ ions in the formed LDH can combine with S 2− ions to synthesize manganese sulfide 41 . As the progress of reaction, these Ni 3 S 2 particles begin to aggregate, crystallize, and form Ni 3 S 2 nanorods attached to Ni-Mn LDH nanosheets. This mechanism is also well confirmed by the SEM observation results. In the SEM image of the intermediate product prepared by a reaction of 90 o C for 4 h plus 110 o C for 3 h, only a small amount of nanorods are visible on the surface of nanosheets, yet the amount and size of nanorods obviously increase in the final product ( Figures S5e,f). If no thiourea was added (Fig. 3, step a-b-e), the final product is pure NiMn-LDH nanosheets (Supplementary Figure S7a), without Ni 3 S 2 nanorods due to the lack of S 2− ions. When only thiourea was employed as anion source (Fig. 3, step a-b-f), both OH − and S 2− ions can be produced. However, because the concentration of OH − ions is relatively low, some of the formed hydroxides turn into sulfides immediately without adequately oriented growth, thereby leading to a high ratio of Ni 3 S 2 and a poor orientation of formed nanosheets, which are found to be curled, and partial pore structures are blocked ( Figure S7b).
The effect of Ni:Mn feeding mole ratios. Figure 4 further shows the morphology of the as-obtained hybrid structures as a function of the feeding mole ratios of Ni:Mn. Without Ni 2+ , the active material grown on the Ni foam is found to be Mn(OH) 2 /MnO 2 nanosheets with a mean sheet thickness of 18 nm (Fig. 4a), and some large square particles with the size above 1 μm on the surfaces of nanosheet array (Supplementary Figure S8a). With the addition of Ni 2+ , the mean thickness of the hybrid nanosheets decreases to 15 nm, at a Ni:Mn ratio of 0.3:0.75 (Fig. 4b), and some nanorods appeared in addition to aggregated square particles ( Figure S8b). As the ratio of Ni:Mn increases from 0.4:0.65, 0.5:0.55, 0.6:0.45, to 0.7:0.35, more Ni 2+ are embedded into hybrid nanosheets, and the mean thickness of the hybrid nanosheets decreases to 14, 12, 11, and 10 nm, respectively (Figs 2b and 4c,e). More importantly, incorporation of Ni can induce the growth of Ni 3 S 2 nanorods to cause the formation of nanosheet@nanorod hybrid arrays. However, with the further increase of Ni:Mn ratio, nanosheet structures trend to degrade, and nanorod products begin to be dominant (Fig. 4f,g). In addition, the white structures on the hybrid array surfaces gradually evolve into nanorods, as the Ni:Mn ratio increases (Figures S8c,g). Once no Mn 2+ added, only the aggregation of β-Ni(OH) 2 /Ni 3 S 2 nanorods can be observed (Fig. 4h). Therefore, only the coexistence of Ni 2+ and Mn 2+ can induce active material to form LDH phase with the well-defined nanosheet structure. Moreover, under the current preparation process, the incorporation of Mn 2+ can depress the excessive sulfidation of NiMn-LDH nanosheets by preventing contact between Ni 2+ and S 2− to some degree, thereby avoiding the formation of pure nanorods. Thus, the nanosheet@nanorod hybrid structure can be maintained. Figure [42][43][44] , indicating the strong pseudocapacitive nature of these electrodes. Because the specific capacitance (C s ) is proportional to the average area of a CV curve, the comparison of CV curves, as shown in Fig. 5a, further indicates that the hybrid array-based electrode possesses a significantly higher C s than pure NiMn-LDH-and Mn-doped α-Ni(OH) 2 /β-Ni(OH) 2 / Ni 3 S 2 -based electrodes 45 . This can be attributed to the unique morphology of the NiMn-LDH nanosheet@Ni 3 S 2 nanorod hybrid electrode, especially the interconnected porous structure, ultrathin nanosheets, and pretty rough surfaces can provide more active sites for efficient exposure to electrolyte for better electrochemical reactions. Furthermore, the NiMn-LDH@Ni 3 S 2 hybrid electrode also exhibits lower equivalent series resistance (R s , the real axis intercept in Fig. 5b), implying better electron transportation from active material to the current collector.

Electrochemical properties of hybrid electrodes.
The galvanostatic charge-discharge curves of the NiMn-LDH@Ni 3 S 2 hybrid array-based electrode at different current densities show strong pseudocapacitive behavior (Fig. 5c). The comparison in C s based on charge-discharge curves illustrates that the as-prepared NiMn-LDH@Ni 3 S 2 electrode has nearly increased by 60% in specific capacitances compared to pure NiMn-LDH and Mn-doped α-Ni(OH) 2 /β-Ni(OH) 2 /Ni 3 S 2 electrodes (Fig. 5d). These results indicate that the incorporation of Ni 3 S 2 into NiMn-LDH can improve the micro-nanostructure and electron transportation, and thereby significantly enhance the capacitance output.
The heating process during preparation of the hybrid array also influences the electrochemical properties of the electrodes because it impacts the morphological control of the hybrid structures as follows: When the two-step heating process of 90 o C for 4 h plus 110 o C for 10 h was replaced by a one-step heating process of 90 o C for 14 h during the whole hydrothermal reaction, only aggregated micro-rods consisting of an enormous number of short nanorods were observed (Supplementary Figures S9a,b). When the reaction was executed under a higher temperature of 110 o C for 14 h, the excessive sulfidation of hydroxides also resulted in the formation of pure SciEnTiFic REPORtS | (2018) 8:5246 | DOI:10.1038/s41598-018-23642-6 nanorod aggregates, but these nanorods appeared to be longer (Figures S9c,d). Accordingly, the NiMn-LDH@ Ni 3 S 2 hybrid array-electrode prepared with a heating process of 90 o C for 4 h plus 110 o C for 10 h exhibits much larger CV curve area and higher specific capacitances than the electrodes from the heating processes of 90 o C for 14 h or 110 o C for 14 h, as shown in Fig. 6a,b. Figure 6c compares the CV curves of Mn(OH) 2 /MnO 2 , β-Ni(OH) 2 /Ni 3 S 2 , and NiMn-LDH@Ni 3 S 2 electrodes to study the effect of Ni 2+ and Mn 2+ . It can be seen that the CV area of the NiMn-LDH@Ni 3 S 2 hybrid array-based electrode is larger than those of the Mn(OH) 2 /MnO 2 electrode obtained without Ni 2+ and the β-Ni(OH) 2 /Ni 3 S 2 electrode, indicating that the coexistence of Ni 2+ and Mn 2+ supports the active material to obtain better electrochemical performances. Figure 6d displays the specific capacitances of hybrid electrodes prepared at different Ni:Mn feeding mole ratios. As more Ni 2+ becomes embedded, C s increases. However, too high ratio of Ni:Mn, e.g., 0.8:0.25, causes a decrease in C s . This C s variation tendency corresponds to the morphological evolution of hybrid structures as shown in Fig. 4. The nanosheet@nanorod hybrid array formed at a ratio of 0.7:0.35 Ni:Mn   exhibits the highest C s values, with 2703, 2494, 2408, 2290, 2201, 2021, and 1847 F g −1 at current densities of 3, 5, 6, 8, 10, 15, and 20 A g −1 , respectively, in which the highest C s (2703 F g −1 at 3 A g −1 ) is significantly higher than those of most reported NiMn-LDH-and Ni 3 S 2 -based active materials (Supplementary Table S1). Such high specific capacitance is attributed to the unique composition and structure features of the NiMn-LDH@Ni 3 S 2 hybrid arrays we present here: (i) There is a synergetic effect between NiMn-LDH and Ni 3 S 2 . On the one hand, relatively high electronic conductivity of Ni 3 S 2 nanorods can enhance the electron transport of NiMn-LDH nanosheets 27,28 . In addition to being illustrated by the EIS result in Fig. 5b, this point is also supported by the following evidence. Compared with those of pure NiMn-LDH ( Figures S1d-e lower lines), the Ni 2p and Mn 2p peaks in the XPS spectra ( Figures S1d,e middle lines) of NiMn-LDH@Ni 3 S 2 have obvious position shifts, confirming the existence of strong electron interactions between NiMn-LDH and Ni 3 S 2 37,46 . On the other hand, highly hydroxylated surfaces of LDH nanosheets can improve the wetting ability of Ni 3 S 2 nanorods to electrolyte; (ii) The rough surfaces and well-defined porous structure of the nanosheet@nanorod hybrid arrays allow better exposure of active sites and easier electrolyte access; (iii) The direct growth on nickel foam can avoid the electrical resistance of the binder to promote fast electron transport to current collector.
Based on the obtainable C s values and the reported calculation method 47 Electrochemical properties of NiMn-LDH@Ni 3 S 2 //AC asymmetric supercapacitors. In order to provide a suitable negative material for the NiMn-LDH@Ni 3 S 2 electrode to construct an asymmetric supercapacitor, we also prepared a wood-derived activated carbon (AC) and investigated its morphology, pore structure, and capacitive performances. This AC owns irregular sharp and visible pore structures (Supplementary Figure S10a), and its BET surface area and average pore diameter can reach up to 701 m 2 g −1 and 3.1 nm, respectively ( Figures S10b-c). When served as electrode active materials, the as-obtained AC exhibits excellent electric double-layer capacitance property within −1.0 to 0.0 V ( Figure S10d). The C s of AC-electrode can be calculated from its galvanostatic charge-discharge curves ( Figure S10e) and reach up to 364 F g −1 at 0.2 A g −1 (Figure S10f), which is comparable to those of the previously reported activated carbons (236-400 F g −1 ) 50-54 . Owing to the excellent capacitance properties of the as-obtained NiMn-LDH@Ni 3 S 2 (within 0.0−0.5 V) and AC (within −1.0-0.0 V), an asymmetric supercapacitor (NiMn-LDH@Ni 3 S 2 //AC) were successfully fabricated with NiMn-LDH@ Ni 3 S 2 and AC as the positive and negative electrode materials, respectively, as illustrated in Fig. 7a. The comparison of CV curves in Fig. 7b indicates the as-fabricated asymmetric supercapacitor exhibits good supercapacitive behavior within different voltage windows. However, the CV profile displays obvious deformation within 0-1.8 V window, implying poor stability of electrode materials in this state. Thus, a moderate electrochemical window of 0−1.6 V was employed to investigate the capacitive performances of as-obtained asymmetric supercapacitor. Figure 7c,d demonstrate that this asymmetric supercapacitor benefits from double contribution of electric double-layer capacitance and pseudocapacitance. Its energy densities can be calculated to be 57, 41, 31, 26, and 22 Wh Kg −1 at the average power densities of 738, 1367, 1830, 2231, and 2564 W Kg −1 , respectively, as shown in Fig. 7e, from its galvanostatic charge-discharge curves (Fig. 7d). The highest energy density of the asymmetric supercapacitor can be found to be 57 Wh Kg −1 at the average power density of 738 W Kg −1 . At a high power density of 2564 W Kg −1 , the energy density can still remain 22 Wh Kg −1 . The obtainable maximum energy density has surpassed those of most previously reported NiMn-LDH-and Ni 3 S 2 -based asymmetric supercapacitors (Supplementary Table S2). It is generally known that the electrochemical stability is crucial for commercial energy storage device. Thus, the galvanostatic charge-discharge measurement was also employed to evaluate the cycling stability of the as-fabricated asymmetric supercapacitor. As shown in Fig. 7f, the specific capacitance of the as-obtained asymmetric supercapacitor experiences a rapid decline in the initial 700 cycles, possibly due to the flaking off of Ni 3 S 2 white aggregates attached to the outer surfaces of the NiMn-LDH@Ni 3 S 2 electrode (Fig. 2a). Then its C s increases gradually up to 89% of its initial value, which should be attributed to the full activation of electrode meterials. After that, the C s decreases again. After 4500 cycles, about 79% of its original capacitance can be retained, which is comparable to some previously reported similar asymmetric supercapacitors (Table S2). The SEM images of the NiMn-LDH@Ni 3 S 2 electrode after this cycling stability test display that the nanosheet array is preserved (Supplementary Figure S11). However, most surface aggregates have fallen off, and it's hard to find Ni 3 S 2 nanorods on the surface of NiMn-LDH nanosheets, possibly due to an irreversible conversion from Ni 3 S 2 to nickel hydroxides after a long-term electrochemical redox reaction in the alkaline electrolyte 36 . These should be the main reasons for the C s attenuation. Furthermore, after a few initial cycles, the Coulombic efficiency can maintain about 99% during 4500 cycles, indicating good electrochemical stability of the NiMn-LDH@Ni 3 S 2 //AC asymmetric supercapacitor. After charged for only 30 seconds, two NiMn-LDH@Ni 3 S 2 //AC coin cell asymmetric supercapacitors (19.1 mg active materials) successfully powered a 3 V electronic timer for at least 2 minutes, as displayed in Fig. 7g. These results indicate that the as-prepared NiMn-LDH nanosheet@Ni 3 S 2 nanorod hybrid array can be considered as a promising candidate for fabrication of practical supercapacitors.

Conclusions
In summary, a novel NiMn-LDH nanosheet@Ni 3 S 2 nanorod hybrid array supported on the three-dimensional porous nickel foam has been successfully fabricated using a facile solvothermal co-deposition method involving a two-step heating process and urea plus thiourea as anion sources. Due to the ultrathin and rough nature, the well-defined porous structure of the hybrid array, and the synergetic effect between NiMn-LDH nanosheets and Ni 3 S 2 nanorods, the electrode based on this novel hybrid array exhibits ultrahigh specific capacitance (2703 F g −1 ), which is significantly higher than those of most reported NiMn-LDH-and Ni 3 S 2 -based active materials. And its asymmetric supercapacitor also displays satisfactory energy density (57 Wh Kg −1 at 738 W Kg −1 ), which is considerably superior to those of most previously reported asymmetric supercapacitors based on NiMn-LDH or Ni 3 S 2 , suggesting that the NiMn-LDH nanosheet@Ni 3 S 2 nanorod hybrid array we present here is a very promising for fabrication of high-performance supercapacitors. This method we present here could be extended to fabricate other LDH/metal sulfide hybrid materials with high electrochemical activity.

Methods
Fabrication of Hybrid Materials. In a typical process, the commercial Ni foam was pre-washed successively with acetone, 2 M HCl solution, deionized water, and absolute ethanol, each for 15 min, to ensure a clean surface. The cleaned nickel foam was then immersed in a 100 mL Teflon autoclave with a homogeneous solution of Ni(NO 3 ) 2 ·6H 2 O (0.7 mmol), Mn(NO 3 ) 2 (0.35 mmol), urea (0.063 g), thiourea (0.08 g), H 2 O (40 mL) and absolute ethanol (30 mL), followed by heating the autoclave in an oven at 90 o C for 4 h and subsequently 110 o C for 10 h. Here, urea and thiourea were used as anion sources to produce OH − and S 2− ions by hydrolysis. After cooled down to room temperature, the Ni foam was washed with deionized and absolute ethanol for three times, respectively. Then, it was dried at 60 o C to remove the absorbed solvents. For the sake of comparison, the hybrid materials with pure urea or individual thiourea as anion source, or different heating processes, or different Ni:Mn feeding mole ratios were also fabricated using the similar procedure. The mass of the hybrid material on Ni foam was determined by subtracting the weight before deposition from the weight after deposition. The loading density of active materials was about 2 mg cm −2 for all electrodes.
Synthesis of Wood-Derived Activated Carbon (AC). Polar wood sawdust (in a corundum crucible) was first pyrolyzed under N 2 atmosphere at high temperature by applying a tube furnace to prepare wood-derived carbon. The wood sawdust was heated to 200 o C at the heating ramp rate of 3 o C min −1 and held at this temperature for 1 h to remove moisture. The sample was then heated to 900 o C at about 3 o C min −1 and held at this temperature for 1 h to remove volatile organics and to carbonize solid residues, and then cooled to room temperature, to producing brown-black wood-derived carbon. The as-obtained sample was thoroughly washed with 1 mol L −1 HCl to remove soluble inorganic salts and then washed with distilled water and absolute ethanol to neutral followed by drying in a vacuum oven at 100 o C overnight. Subsequently, this powder was thoroughly mixed with KOH solution (10 mol L −1 ) (carbon/KOH, 1:4 by weight ratio) under 100 o C for several hours to produce a black jelly-like slurry, which was then treated by the same pyrolysis process. 2 mol L −1 HCl was added to the as-obtained sample to neutralize excess alkali, and then washed with distilled water and absolute ethanol, respectively. By this process the wood-derived activated carbon (AC) was obtained after drying in a vacuum oven at 100 o C overnight.
Fabrication of AC electrodes. A mixture of AC, 15 wt% of acetylene black (as an electrical conductor), 5 wt% of polytetrafluorene-ethylene (as a binder), and a small amount of water was prepared by milling to produce a homogeneous paste. This paste was then pressed onto nickel foam current-collectors to produce the AC electrode.
Characterization. The morphologies were observed by scanning electron microscopy (SEM, SU8000, Hitachi). The selected-area electron diffraction (SAED) pattern and transmission electron microscope (TEM) images were obtained on a FEI Tecnai G2 F20 S-TWIN field emission microscope. The crystalline structure was characterized by X-ray diffraction (XRD) patterns recorded in a PANalytical X'pert X-ray diffractometer with Cu Kα radiation. X-ray photoelectron spectroscopy (XPS, Thermo ESCALAB 250XI) and Energy-dispersive X-ray spectroscopy (EDX, TSL, AMETEK) measurements were employed to investigate the elemental compositions of the samples. An automated adsorption apparatus (BELSORP-max) was used to analyze the surface characteristics of the samples.
Electrochemical measurement. The electrochemical properties of the as-obtained hybrid material-and the AC-based electrodes were investigated under a three-electrode cell configuration at 25 o C in 1 M KOH. The nickel foam supporting hybrid structures acted as the working electrodes, which were soaked in a 1 M KOH solution and degassed in a vacuum for 5 h before the electrochemical test. Platinum foil and a saturated calomel electrode (SCE) were used as the counter and reference electrodes, respectively. The electrochemical properties of asymmetric supercapacitor were investigated under a two-electrode cell configuration with NiMn-LDH@ Ni 3 S 2 and AC as the positive and negative electrode materials, respectively, in 1 M KOH electrolyte solution. The cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS) measurements were conducted on a CHI 660E electrochemical workstation (Shanghai CH Instrument Company, China). The galvanostatic charge-discharge tests were carried out on a Land test system (LAND CT2001A, China). The C s , energy and power densities were calculated based on the total mass of active materials.