1. Introduction
In recent years, supercapacitors (SCs) have attracted widespread research attention as energy storage technologies. Due to their numerous advantages, such as long cycle life, high power density, and rapid charge-discharge capability, advanced energy storage and conversion systems using SC devices are being actively studied as substitutes for rechargeable batteries [
1,
2]. Specifically, designs of battery-type electrode materials for high power and energy density have been used to attain the apparent merits of both supercapacitors and rechargeable batteries. Thus, the development of advanced electroactive materials is the critical issue in achieving high performance energy storage systems [
3,
4].
Among the various key parameters that can be used to enhance electrochemical performance, considerable research efforts have been devoted to finding new and advanced materials and unique structures for SC electrodes [
5,
6,
7,
8,
9]. First, improvements in ion/electron diffusion have enhanced the electrochemical performance. It is well known that the unique structural feature of enhanced surface area of electroactive materials is the key to achieving superior electrochemical performance [
10,
11,
12]. According to the energy storage mechanism of battery-type supercapacitors, electrochemical ion/charges can be faradaically stored through fast and reversible redox reactions at the interface of electroactive materials and electrolyte. According to this mechanism, the enlarged surface area of electroactive materials is the crucial factor to facilitate the charge storage in battery-type electrodes [
13,
14]. In hybrid supercapacitors (HSCs), battery-type materials such as NiO and Co
3O
4 [
15,
16,
17,
18] exhibit higher electrochemical performance than those of pseudocapacitive materials (i.e., RuO
2) [
19,
20]; this higher capacity may provide abundant activation sites and thereby enhance the charge storage performance. In order to achieve the goal of high-performance, we studied numerous hybrid or composite materials, including pseudo-materials such as conducting polymers. Conducting polymers include polyaniline, poly [3,4-ethylenedioxythiophene], polypyrrole, and polythiophene, which have been highly studied because of their low cost, environmental stability, and high electrical conductivity. In comparison with other electrode materials, conductive polymers attracted much attention due to their good flexibility, easy processing, and the polymer film thickness and composition could be attained with good control [
9]. Furthermore, with the insertion and release of charged ions in the charging and discharging conditions, the expansion and contraction of conducting polymers will be under the action of charges and ions. This process often leads to the degradation of the cycle stability performance of the electrode material [
1,
2]. Taking the above problems into consideration, the design of proper electrode materials has been regarded as a feasible solution.
Moreover, numerous studies have been conducted on earth-abundant elements such as transition metal nitrides [
21,
22], sulfides [
23,
24], oxides [
25], and hydroxides [
26]. Among them, earth-abundant iron hydroxides are promising electroactive materials for SC electrodes. The characteristics of low cost, natural abundance, environmental benignity, and high activity in alkaline media favor its wide application. However, the poor conductivity (10
−5 S/cm) of iron hydroxide hinders its practical application to supercapacitors [
27]. Thus, various research efforts have been suggested to improve the conductivity, including tuning of the electronic structure, morphological optimization, composition, and interface engineering, all of which have been reported to increase the activation sites for charge storage [
28,
29]. Due to their multiple valence states and the various structures of their compounds, vanadium oxides have been extensively studied as favorable alternatives to HSCs. Even better than single-component vanadium oxides, iron vanadate hydroxide, which has richer redox chemical kinetics, can be utilized with multiple metal ions [
30,
31]. Iron vanadate hydroxide as an electrode for HSCs shows interfacial effects and enhanced ion/electronic conductivity, which are known to improve the electrochemical activity.
The rational design of electrode materials via a simple and favorable approach is vital for the fabrication of highly efficient electrochemical energy storage devices. In this regard, the nanoscale size of iron vanadate hydroxide allows the formation of larger exposed active sites, shortening the ion diffusion path compared with that of its bulk counterparts. In the past, numerous studies have reported that nano-size vanadates achieved better electrochemical performance than bulk electrodes in HSCs [
32,
33]. Various preparation methods of nanoscale-sized materials, including hydrothermal, electrospinning, and wet chemical methods, have been developed for the synthesis of vanadates with diverse morphologies. For instance, Ni
3V
2O
8@Co
3V
2O
8 composite [
34], Ni
3V
2O
8/GO composite [
35], 3D Co
3V
2O
8 with porous rose-like structure [
36], and Ni
3V
2O
8/NiO nanocomposite [
37] have been prepared for use as electrode materials to obtain superior electrochemical performance in the field of SCs.
A rational design and facile synthetic process for vanadate-based binary metal oxides/hydroxides are thus favorable approaches to enhancing supercapacitor performance. Herein, the electrochemical performance of unique hierarchical FeV hydroxide structures decorated over nano/micro-sandpaper substrates is reported for the first time. The entire synthesis was carried out using a simple and viable electrochemical deposition (ECD) technique. As a result, nano-flakes/nano-spheres of Fe-V layered double hydroxides (LDHs) were hierarchically grown on Ni-sputtered sandpaper substrate. By tuning the unique surface morphology, these novel nanostructures on conductive sandpaper supported large amounts of electrolyte ion diffusion, resulting in enhanced electrochemical performance and high-rate capability. For the efficient decoration of Fe-V on the sandpaper substrate, optimization of Fe-V nanostructures as well as the determination of the proper grit-number of the sandpaper substrate were successfully carried out. It was found that Fe0.75V0.25 LDHs grown on #15000 grit sandpaper exhibited superior electrochemical performance. Furthermore, the assembled HSC device delivered a higher energy and power density of 0.123 mWh/cm2 and 23.8 mW/cm2 at the current densities of 2 and 18 mA/cm2, respectively. The nylon membrane manufactured through electrospinning is used to manufacture a negative electrode substrate; flexible HSC could be manufactured with high flexibility. Flexible HSCs have stable electrical output at various bending angles. Electrochemical analysis confirmed that the developed FeV-LDHs hierarchical structures deposited on sandpaper, by improving the diffusion rate of electrolyte ions into the electrode, possess excellent electrochemical supercapacitor performance.
3. Results and Discussion
Schematic images of the synthetic process of the suggested Fe-V composite-based electrode are shown in
Figure 1. For the development of a hierarchical micro-nano structure, inherent micro-morphological SP was utilized as a novel substrate material. Nano-structured Fe-V LDHs of electroactive materials were coated onto a Ni-sputtered SP substrate via a facile electrochemical deposition (ECD). The Fe-V growth solution was prepared with individual metal precursors of Fe and V; detailed conditions are provided in the experimental section. For Fe-V deposition, the ECD technique was used at −1.0 V fixed potential for 100 s. Following the deposition of FeV LDHs on the Ni-sputtered SP, the morphology was transformed into a nanoflake/nanosphere structure.
As can be seen in
Figure 2, X-ray diffraction (XRD), energy dispersive X-ray spectroscopy (EDX), and X-ray photoelectron spectroscopy (XPS) characterization were conducted to further examine the materials of the synthesized electrodes (Fe0.
75V
0.25). The EDX spectra shown in
Figure 2a indicate the existence of each element. The significant peaks of Ni, Fe, V, and O confirm the presence of these elements in the synthesized Fe
0.75V
0.25 electrode. Ni peaks are from the layer sputtered onto the SP substrate; the remaining peaks of Fe, V, and O are from the coated FeV LDH electroactive material.
For further analysis, an XRD study was carried out to check the phase and crystallinity, with the results shown in
Figure 2b. The well-defined diffraction peaks observed at 2
θ values of 17.2° in the (200) plane and 26.2° in the (006) plane were indexed to vanadium hydroxide. The orthorhombic crystal structure of vanadium hydroxide was consistent with the standard XRD diffraction peaks (JCPDS. 41-1426). The peak observed at a 2
θ value of 22.5° in the (110) plane was indexed to iron hydroxide. The orthorhombic crystal structure of iron hydroxide matched available reports on iron hydroxide (JCPDS. 29-0713). Herein, XRD peaks at 2
θ values of 44°, 51°, and 76° were well indexed to the (111), (200), and (220) planes, respectively, showing the cubic structure of the conductive Ni substrate. No other crystalline phase is detected, indicating a well-defined layered structure with high crystallinity.
XPS analysis was performed to study the chemical composition, the elemental binding state, and the surface electronic structure of the FeV LDH.
Figure 2c displays the XPS survey spectra of FeV LDH, which consists of iron, vanadium, oxygen, and carbon elements. All the XPS spectra were fitted with a Shirley background. In
Figure 2d, the core-level Fe 2p curves are shown, where a peak is obtained at 710 eV for Fe 2p
3/2 and a peak at 723.8 eV for Fe 2p
1/2. The occurrence of these peaks confirms the presence of Fe at both +2 and +3 oxidation states. Also, a peak is seen at 717.4 eV, which is a satellite peak that indicates the Fe
3+ oxidation state [
38].
Figure 2e illustrates the presence of V 2p peaks at V 2p
3/2 and V 2p
1/2. For V 2p
3/2, the peaks obtained at 515.2 and 516 eV correspond to the presence of vanadium in the V
4+ and V
5+ oxidation states, respectively. Similarly, the V
4+ and V
5+ oxidation states of vanadium are observed for V 2p
1/2 at 522.5 and 523.7 eV, respectively. The deconvoluted peaks for O 1s are illustrated in
Figure 2f; also, a major peak is obtained at 528.9 eV, and two other peaks at 529.6 and 530.8 eV are attributed to the oxygen in vanadium and iron oxide [
39]. In an alkaline solution of KOH electrolyte, the metal hydroxides Fe(OH)
2 and V(OH)
3 were easily converted to metal oxides (Fe
2O
3 and V
2O
5) by fast redox reaction. Followed by the deconvoluted O 1s spectra, the chemical reactions between metal oxide and metal hydroxide were systematically analyzed according to the following Equations (5)–(7) [
1,
2,
3].
Detailed morphological and electrochemical performance analyses of Fe-V compositions coated on various grits of SP substrate (grit numbers of #8000, #15000, and #20000) were conducted, with results shown in
Figure 3. It is well known that an enlarged specific surface area of electrodes is crucial for the enhancement of electrochemical performance. Here, to create a unique hierarchically-structured electrode based on SP as the substrate, it was important to optimize the SP grit number for detailed classification of SP structure. In terms of inherent SP properties, particle size as well as the surface morphology of SP can significantly affect specific electroactive sites. Generally, various grit numbers of SP indicate the particle number per square inch. Thus, for better surface engineering, it is possible to study the effect of the optimized particle number on increasing the surface area.
To further exploit the final structures of each electrode, electrochemical measurements of Fe-V composite electrodes (coated onto different SPs with grit numbers of #8000, #15000, and #20000) were carefully performed in the three electrode configuration shown in
Figure 3a–c. In
Figure 3a,b, cyclic voltammetry (CV) and galvanostatic charge–discharge (GCD) plots of these electrodes (FeV_#8000, FeV_#15000, and FeV_#20000), respectively, are provided; these were obtained using 1.0 M KOH aqueous solution as electrolyte. The FeV_#15000 electrode exhibited the highest electrochemical potential among all the electrodes. The much higher capacity of the optimized FeV_#15000 was successfully demonstrated by the larger integral area of the CV graph and longer charge-discharge time of the GCD graph. To allow a systematic comparison,
Figure 3c shows calculated values of areal capacity for the three electrodes. Areal capacity values of FeV_#8000, FeV_#15000, and FeV_#20000 were 0.031, 0.156, and 0.056 mAh/cm
2, respectively. Finally, the abovementioned FeV_#15000 electrode was considered to have the optimized composition, showing the highest areal capacity due to its superior electrochemical performance.
Aside from electrochemical measurements, morphological studies of these synthesized electrodes were carefully carried out, with results shown in
Figure 3d. The electrodes of FeV_#8000, FeV_#15000, and FeV_#20000 exhibited unique surface morphologies after being coated on SPs with various grit numbers. The inherently different morphologies of the SP (as substrate) lead, through the synthesis of electroactive layers (Fe-V composition), to various electroactive sites. The optimized FeV_#15000 sample exhibited double morphology structures with (i) well-designed nanosheets grown on the porous SP surface, formed by LDH (Fe(OH)
2 and V(OH)
3), and (ii) hierarchically-designed interconnected nanoflakes, formed by metal oxides (Fe
2O
3 and V
2O
5). XPS characterization was used to study the reaction between metal hydroxides and metal oxides; the various oxidation states of Fe and V proved the existence of these structures. Considering the chemical formulas of Fe(OH)
2 and V(OH)
3, the oxidation states of Fe
2+ and V
4+ were studied for LDHs. Also, in the chemical formulas of Fe
2O
3 and V
2O
5, the oxidation states of Fe
3+ and V
5+ were studied for metal oxides. All these results suggest that the unique double morphology forms due to the presence of LDH and metal oxide structures based on transition metal hydroxide/oxide active materials. Furthermore, a nanomorphology of the Fe-V hydroxides/oxides (in electroactive material) can be hierarchically coated onto the inherent micro morphology of the porous SP substrate. On the other hand, FeV_#8000 shows a surface structure with almost flat nanosheet morphology; FeV_#20000 demonstrates a porous surface with partially blocked morphology. Compared with these two electrodes (FeV_#8000 and FeV_#20000), the unique surface morphology of the optimized electrode (FeV_#15000) led to its superior charge storage performance. The appearance of this unique surface morphology for FeV_#15000 grit allows the enhancement of charge-storage performance. The large electrochemically active area of FeV_#15000 resulted in a faster electron transfer between electrolytes and electroactive materials. Accordingly, the distance of interface electrolyte ion diffusion and electron transport pathways can be easily decreased in energy storage mechanisms. Based on these results, further electrochemical measurements were acquired for the optimized SP substrate of #15000-grit.
To determine the proper ratio of Fe to V precursors for electroactive materials, electrochemical measurements of various Fe-V compositions coated onto an optimized #15000 grit SP substrate were conducted, with the results shown in
Figure 4. The various compositions (Ni, Fe, Fe
0.75V
0.25, Fe
0.5V
0.5, Fe
0.25V
0.75, and V) and morphologies exhibited different levels of electrochemical performance as well as material-specific properties. The various electrochemical activities resulted from the different contributions of Fe and V in each composite material.
Figure 4a shows typical CV curves with potential ranges from 0.0 to 0.55 V at a fixed scan rate of 100 mV/s. GCD curves with a current density of 3 mA/cm
2 are shown in
Figure 4b. For comparison, the Fe
0.75V
0.25 electrode demonstrated the highest electrochemical performance among all compositions, with a larger CV area and longer charge-discharge times. The values of areal capacity were calculated according to the measured discharging time, applied current, and area of electroactive sites, and the highest areal capacity value of Fe
0.75V
0.25 was successfully obtained, as shown in
Figure 4c. As the current densities increased, the areal capacity values gradually decreased according to the equation, and all the areal capacity values are provided in
Table S1.
For systematic confirmation of the feasibility of transport of electrolyte ions and electrons in FeV electroactive materials, electrochemical impedance spectroscopy (EIS) of optimized Fe
0.75V
0.25 electrode was performed, with results shown in
Figure 4d. The impedance spectra in the Nyquist plots were recorded in a frequency range of 10,000 to 0.01 Hz; materials demonstrated different behaviors in the different frequency regions. To reveal the electrochemical performance of the suggested electrode in a particular electrolyte, Nyquist plots showing an imaginary component (Z″) against the real component (Z′) were analyzed; these showed a semicircle in the high frequency region and a straight line in the low frequency region. In the high frequency ranges, the equivalent series resistance (ESR) can be obtained to determine the solution resistance (
Rs), the internal resistance of the active material, and the contact resistance at the active material/substrate interface; these values can be used to determine the charge transfer resistance (
Rct) at the electrode/electrolyte interface. In the low frequency range, the diffusion of the electrolyte within the electrode was evaluated by examining electrolyte penetration pathways during the charge storage process. As a result, the great electrical conductivity of the optimized electrode (Fe
0.75V
0.25) was indicated by the small radius of its semicircle, defined using the lowest
Rct, and the steeper slope of the vertical line, which is related to the characteristic of an ideal capacitor. Finally, we demonstrated the superior charge storage performance of the Fe
0.75V
0.25 electrode, showing that this is indeed the ideal composition. From the obtained results, the synergistic effects among different metals were proved by comparisons between mixed metal hydroxide/oxide compositions (Fe
0.75V
0.25, Fe
0.5V
0.5, and Fe
0.25V
0.75) and mono metal hydroxides/oxides (Fe and V). Among the mixed metal hydroxide/oxide compositions, the enhanced electrochemical performance of the optimized composited electrode made of Fe
0.75V
0.25 was especially proven via a detailed morphological study. The specific surface area and pore size distribution play a significant role in the electrochemical supercapacitor performance. Therefore, nitrogen adsorption–desorption isotherm studies were carried out to investigate the specific surface area and porous nature of the corresponding materials. As shown in
Figure S1a, the isotherm of metal hydroxide/oxide samples with a broad hysteresis loop in the range between 0–1.0 demonstrates the mesoporous nature of the material. The Brunauer–Emmett–Teller (BET) surface area of Fe
0.75V
0.25 is observed to be 98.63 m
2/g and confirmed to be the highest compared with remaining samples provided in
Table S2. The enhanced surface area can offer sufficient surface sites for the faradaic redox reaction, thereby leading to enhanced electrochemical supercapacitive performance of the electrode material. Barrett–Joyner–Halenda (BJH) plot shown in
Figure S1b reveals the pore size distribution of all the samples and displays an average pore size of 1.48 nm in the case of Fe
0.75V
0.25. This pore size can effectively support the electrolyte ions diffusion into the internal voids of the materials, contributing to their high-rate capability.
As shown in the SEM images in
Figure 4e, the surface morphologies of the various compositions indicate their controllable construction; these materials promote synergistic effects of pure elements (Fe and V). The surface of the Fe-based electrode almost blocked the sandpaper pores, presenting an almost completely flat structure. Similarly, the surface of the V based electrode exhibited a simple morphology, with interconnected nanorods grown on round SP peaks. On the other hand, the electrodes made of Fe
0.5V
0.5 and Fe
0.25V
0.75 demonstrated only single morphology structures, showing smoothly-covered round peaks without significant porosity. Compared with these four samples, the optimized Fe
0.75V
0.25 electrode had a double morphology due to the well-designed LDH nanosheets and interconnected nanoflake structure with metal oxides. Consequently, the unique double surface morphology of Fe
0.75V
0.25 provides abundant active sites in the form of hierarchical nano- and micro-structures with a high surface area. By allowing a large number of electrochemical active sites, this material promotes easy access to electrolyte ions for facile charge transport in energy storage systems.
To understand the electrochemical behavior and maximum charge storage abilities of the corresponding electroactive materials (including optimized Fe
0.75V
0.25), detailed electrochemical analyses were performed, with results shown in
Figure 5a–d. CV curves recorded at different scan rates from 10 to 150 mV/s are shown in
Figure 5a. The clearly-visible redox peaks in all the graphs indicate the electron/charge transport behavior of Fe
2+/Fe
3+ and V
4+/V
5+. The energy storage mechanism for battery-type Fe
0.75V
0.25 electrodes is based on these transitions between different oxidation states of Fe and V. On the surfaces of the electroactive materials, the highly hierarchical architecture provides excellent access for electrolyte ions. The integral CV area also gradually increased with the increase in the scan rate. In
Figure 5b, GCD analysis results are provided that show the different current densities ranging from 3 to 20 mA/cm
2. A uniform charging/discharging tendency, with a significant plateau shape, was recorded, indicating the reversible faradaic redox process. We calculated the areal capacity values of the Fe
0.75V
0.25 electrode shown in
Figure 5c at different current densities ranging from 3 to 20 mA/cm
2. Based on the abovementioned GCD results, the values of areal capacity were found to gradually decrease with the increase in the applied current density. Finally, the excellent rate performance of the suggested electrode was successfully proven via long-term stability test shown in
Figure 5d. Even after 5000 GCD cycles, the electrode retained 91.8% of its initial areal capacity, indicating the good cycling stability of Fe
0.75V
0.25. This excellent cycling performance is a critical aspect determining electrode applicability for practical energy storage devices. To further verify the importance of electron transport in FeV LDH electrode, SEM images of the pristine electrode (
Figure S2a), and after 5000 cycles (
Figure S2b) are compared. As can be seen, after cycling with different charge-discharge cycles at 20 mA/cm
2, the skeleton of FeV LDH electrode can remain intact, showing outstanding cycle life span. The EIS curve of Fe
0.75V
0.25 electrode before and after cyclic stability study are plotted in
Figure 5e. The
Rs values are 11.4 and 11.8 Ω, equivalent to the electrode before and after cyclic stability test, respectively. While the
Rct values are 10.5 and 10.3 Ω, equivalent to the electrode before and after cyclic stability test, respectively (inset of
Figure 5e shows the equivalent circuit). With the slight changes in
Rs and
Rct, the electrode exhibits a good conductivity even after 5000 charging and discharging cycles.
Considering the superior performance of the Fe
0.75V
0.25 battery-type electrode, a hybrid supercapacitor (HSC), shown in
Figure 6, was fabricated and studied. For the fabrication of HSC devices, the as prepared Fe
0.75V
0.25 and activated carbon (AC)-coated SP substrate (AC//SP) acted as battery-type positive electrodes and electric double layer capacitance (EDLC)-type negative electrodes, respectively. The preparation and electrochemical analysis of the AC//SP electrode are specified in
Figure S3 (Supporting Information). To optimize the potential window of the HSC device, CV curves of the HSC device were plotted at various applied potentials varying from 0–0.6 V, 0–0.8 V, 0–1.0 V, 0–1.2 V, 0–1.4 V, and 0–1.6 V at the sweep rate of 100 mV/s, as revealed in
Figure 6a. The HSC device showed a stable CV plot without any deviations up to 1.6 V, shown in
Figure 6a. Similarly, the GCD analysis of the HSC device at various applied potentials ranging from 0–0.6 V, 0–0.8 V, 0–1.0 V, 0–1.2 V, 0–1.4 V, and 0–1.6 V at the current density of 3 mA/cm
2 is plotted in
Figure 6b. Further, CV and GCD results obtained at the higher applied potential window of 0–1.6 V show stable results without any deviations. Therefore, the optimum working potential window of the HSC device was fixed to be 0–1.6 V.
The CV plots of HSC device obtained at different scan rates varying from 10 to 150 mV/s within the potential window of 0–1.6 V, shown in the
Figure 6c. The shape of the CV plots of the HSC represents the existence of EDLC-type and battery-type electrodes without clear redox peaks, resembling the well-balanced of both charge storage mechanisms.
Figure 6d illustrates the GCD curves, which were obtained by fixing the potential range (0–1.6 V) and varying the current density from 2 to 18 mA/cm
2. On the basis of these results, the areal capacitance values were calculated and are provided in inset
Figure 6e. The values of 94.97, 83.76, 75.95, 58.27, 45.72, and 39.25 μF/cm
2 of areal capacitance were achieved at 2, 3, 5, 7, 10, 15, and 18 mA/cm
2, respectively. The crucial parameters of HSCs are energy density and power density, which are estimated using Equations (3) and (4), respectively. The resultant values of these parameters are plotted in the Ragone diagram shown in
Figure 6e. The HSC device delivered a higher energy density of 0.123 mWh/cm
2 and a maximum power density of 23.8 mW/cm
2. As shown in
Figure 6e, the energy and power density values of the current HSC device are higher than the values of recently reported core-shell heterostructure-based supercapacitors and are provided in
Table S3 [
38,
39,
40,
41,
42]. Making the use of HSCs in any practical application, cycling stability is most important. Therefore, the cycling stability study was carried out for up to 15,000 continuous GCD cycles at the current density of 10 mA/cm
2. The HSC device delivers good stability with 81.2% capacity retention after 15,000 continuous GCD cycles, as shown in
Figure 6f. The
Rs values are 10.7 and 9.3 Ω, equivalent to the device before and after the cyclic stability test, respectively. While, the
Rct values are 5.2 and 4.7 Ω, equivalent to the device before and after the cyclic stability test, respectively. With the minor changes in
Rs and
Rct, the device revealed good conductivity even after 15,000 continuous charging and discharging cycles (
Figure 6g). Such remarkable results unambiguously support the suitability of the as constructed HSC device as an exceptional aspirant for high-energy and power density applications in the energy storage sector.
Figure 6h displays the CV plots of the flexible HSC under various bending angles at 150 mV/s. Regardless of the bending degree, the flexible HSC exhibited excellent electrochemical stability, thereby indicating excellent mechanical stability. The optical image of flexible HSC according to the various bending angles is shown in
Figure S4.