KR20190015951A - Fallen leaf derived microporous electrode material for supercapacitor and method for manufacturing the same - Google Patents

Abstract

The present invention relates to an electrode material for a super capacitor. More particularly, the present invention relates to an electrode material for a super capacitor manufactured by using a carbon-based material derived from fallen leaves. According to the present invention, by applying the carbon-based material derived from the fallen leaves as an electrode of a super capacitor, an electrode for a super capacitor having excellent specific surface area and electrochemical characteristics can be provided.

Description

TECHNICAL FIELD [0001] The present invention relates to an electrode material for a microporous supercapacitor fabricated from a fallen leaf, and a method for manufacturing the electrode material for the microporous supercapacitor.

The present invention relates to an electrode material for a supercapacitor, and more particularly, to an electrode material for a supercapacitor manufactured using a carbon-based material obtained from a litter.

BACKGROUND OF THE INVENTION [0002] The importance of a rechargeable power source with excellent electrochemical performance in emerging technologies such as mobile phones, portable computers, electronic devices, and electric vehicles is becoming increasingly important. Of the chargeable energy storage systems, supercapacitors are power sources that have the advantages of relatively simple cell configuration, high power density, and excellent cycle stability. However, due to its low energy density, its application is limited. Energy density may be determined by CV _i ^2/2, wherein C is the capacitance, V _i represents a voltage. Capacitance is greatly influenced by the active area of the electrode material, the textural properties, and the amount of redox active heteroatoms. Therefore, effective design of the supercapacitor is needed to increase the energy density.

Porous carbon based materials (PCMs) are mainly used as electrode materials for supercapacitors due to their advantages such as high specific surface area, conductivity, light weight, chemical stability, low cost raw materials and low processing cost. The activated carbon having a specific surface area of about 500 to 3000 m ² / g has a specific storage capacity of about 50 to 300 F / g in the aqueous electrolyte. The introduction of a redox active heteroatom on the carbon surface can increase the capacitance because it can store additional charge through pseudocapacitive behavior. In addition, PCM sub-nanometer scale pores can effectively increase the capacitance by effectively reducing the thickness of the electrical double layer. Therefore, in order for a supercapacitor to have a high energy density, it is preferable to use an electrode material having a high specific surface area, a suitable pore size, and a high amount of redox active heteroatoms. Furthermore, the use of redox mediators in aqueous electrolytes can increase the capacitance further. In a study by Wu et al. (J. Wu, H. Yu, L. Fan, G. Luo and J. Lin, M. Huang, J. Mater. The non - storage capacity of ~ 605 F / g was shown in the KOH electrolyte. This is close to twice the energy density of conventional super capacitors. Well-developed PCM and redox active electrolytes can exhibit better electrochemical performance due to their synergistic effects on energy storage.

Leaves are one of the most abundant and common natural wastes. Carbon-based materials from litters are used in a wide range of applications, such as electrocatalysis, energy storage, carbon capture, and biosensors, due to their low cost, renewable and environmentally friendly advantages. The texture and surface properties of carbon materials are determined by precursor materials and processes. Carbon-based materials from litters can be used as active electrode materials for supercapacitors because they exhibit different physico-chemical properties.

J. Wu, H. Yu, L. Fan, G. Luo, J. Lin, M. Huang, J. Mater. Chem. 22 (2012) 19025.

It is an object of the present invention to provide an electrode for a supercapacitor having excellent specific surface area and electrochemical characteristics by applying a carbon-based material obtained from a litter to an electrode of a supercapacitor in order to solve the above problems .

In order to solve the above problems,

It is an aspect of the present invention to provide an electrode material for a supercapacitor including a carbon-based material obtained from litter.

The leaves may be ginkgo biloba.

The carbon-based material may be a pyropolymer.

The carbon-based material may have a Raman peak intensity ratio (I _D / I _G ) of 1.06 to 1.13.

The carbon-based material may comprise a redox active heteroatom.

The carbon based material may include micropores of 0.7 nm or less.

The present invention also provides a method for producing a pulverized mixture, comprising the steps of: (a) preparing a pulverized mixture by mixing a leaf and a basic solution and pulverizing the mixture; (b) heat treating the pulverized mixture to produce a carbon-based material; And (c) treating the dried carbon-based material with an acid. The present invention further provides a method of manufacturing an electrode material for a supercapacitor using a litter.

The leaves may be ginkgo biloba.

In the step (a), the basic solution may be KOH.

In the step (b), the temperature may be elevated at a rate of 10 [deg.] C / min under an inert gas atmosphere, followed by heat treatment at 800 [deg.] C.

The step (c) may be an acid treatment using nitric acid.

By applying the carbon-based material obtained from the litter according to the present invention as an electrode of a supercapacitor, there is an effect of providing an electrode for supercapacitor having excellent specific surface area and electrochemical characteristics.

FIG. 1 shows the result of thermogravimetric analysis according to various heating rates of ginkgo leaves.
FIG. 2 shows XPS analysis results of a carbon-based material (GL-AMPs, GL-MPs) according to an embodiment of the present invention.
FIG. 3 shows XPS analysis results of a sample (Gl-800) subjected to heat treatment of ginkgo leaf according to an embodiment of the present invention.
4 (a) and 4 (b) are photographs of a surface image of a carbon-based material (GL-MPs) according to an embodiment of the present invention. : FE-TEM image)
5 (a) and 5 (b) show FE-SEM images, (c), (d), and (d) : FE-TEM image)
6 shows XRD analysis results (a) and Raman spectrum (b) of a carbon-based material (GL-AMPs, GL-MPs) according to an embodiment of the present invention.
7 shows the nitrogen adsorption-desorption isotherm (a), micropore size distribution (b) and mesopore size distribution (c) of the carbon based material (GL-AMPs, GL-MPs) according to an embodiment of the present invention It is.
8 is a graph showing a cyclic voltage-current curve (a: GL-AMPs, b: GL-MPs) of a carbon based material (GL-AMPs, GL-MPs) and a reference material , c: KB) and rate capabilities (d) according to the current density of 1 to 35 A / g.
9 is a graph showing a relationship between a constant current charge / discharge profile (a: GL-AMPs, GL-AMPs, and GL-AMPs) according to current density of a carbon- b: GL-MPs, c: KB).
FIG. 10 shows the capacitance retention rate according to a cycle of a carbon-based material (GL-AMPs) according to an embodiment of the present invention.
Figure 11 shows electrochemical performance results in an electrolyte to which 0.05 M PPD of a carbon-based material (GL-AMPs) according to an embodiment of the present invention is added, wherein the electrochemical performance at a scan rate of 5 mV / s (B), a rate characteristic (c) according to a current density of 1 to 15 A / g, a constant current discharge profile according to current density (a), a constant current charge / discharge profile (insertion degree of c) and stability performance results (d) up to 1000 cycles.
12 is a graph showing electrochemical characteristics of a carbon-based material (GL-AMPs) according to an embodiment of the present invention in an aqueous 1 M sulfuric acid electrolyte to which 0.02 M hydroquinone is added, wherein a scan rate of 5 to 100 mV / s (B) and a rate characteristic (c) at a current density of 3 to 15 A / g according to a current density of 3 to 15 A / g will be.

Hereinafter, the present invention will be described in more detail by way of examples. However, the present invention is not limited by the examples.

Example 1. Preparation of microporous pyropholymer

10 g of KOH is added to 5 g of ginkgo leaves (GLs) and ground in a mortar for 30 minutes to prepare a mixture. The mixture is heated at a rate of 10 ° C / min under an inert gas Ar atmosphere (Ar supply rate: 200 mL / min) and heat-treated at 800 ° C to produce a carbon material. The carbon material is washed several times with distilled water and ethanol, and then dried in an oven at 60 ° C. The dried sample (hereinafter referred to as "GL-MPs") was stirred at 60 ° C. for 3 hours using 40 wt% nitric acid to prepare a microporous pyrophyl polymer (hereinafter referred to as GL-AMPs) . The prepared GL-AMPs are washed several times with distilled water and ethanol, dried in an oven at 60 ° C, and stored in an oven at 30 ° C.

Comparative Example 1

In the procedure of Example 1 above, GL-MPs not treated with nitric acid are prepared.

Comparative Example 2

A sample (hereinafter referred to as "GL-800") is prepared by performing the same process as in Example 1 except that the GLs are heat-treated without using KOH.

Measurement example 1. Thermogravimetric analysis (TGA) of ginkgo leaf (GLs)

The thermal decomposition behavior of GLs samples was analyzed by thermogravimetric analysis (TGA, Q50, TA instrucments, UK) at 800 ℃ for 5, 10, 20 and 50 ℃ / The results are summarized in FIG.

Referring to FIG. 1, when the heat treatment was carried out at a heating rate of 5 ° C / miin to 800 ° C, a yield of about 29.3 wt.% Was obtained. When the heat treatment was carried out at a heating rate of 50 ° C / wt.%, which is about 5 wt.%.

Measurement example 2. X-ray analysis

The surface chemistry characteristics of the samples prepared in Example 1 (GL-AMPs), Comparative Examples 1 (GL-MPs) and 2 (GL-800) were analyzed by X-ray photoelectron spectroscopy (XPS, PHI 5700 ESCA, USA) (GL-AMPs, GL-MPs) and FIG. 3 (GL-800).

2, the C 1s of GL-MPs were observed at 284.4, 285.9 and 290.2 eV, respectively, and the C 1 C bonds, the CO 2 bonds and the O 2 = CO 2 bonds were observed in FIG. Three peaks were observed. The C-O and C-O bonds in O-1s of GL-MPs appeared at 532.0 and 533.9 eV, respectively, and functional groups containing oxygen at similar positions were observed in GL-AMPs. However, the peak intensity of the C-O bond is larger than the peak intensity of C = O. This may mean that the Ca compound has been removed by acid treatment of GL-MPs. Table 1 summarizes the specific components obtained by XPS analysis. Referring to Table 1, GL-MPS and GL-AMPs contain a small amount of nitrogen atoms by 0.83 at.% And 1.03 at.%, Respectively.

Atomic ratio (at.%) C O N GL-MPs 90.58 8.59 0.83 GL-AMPs 86.62 12.35 1.03

Referring to FIG. 3, the XPS C 1s spectrum of the GL-800 sample in FIG. 3 a shows that GLs has been converted into a pyropolymer mainly composed of a hexagonal sp ² -bonded carbon structure. However, referring to FIG. 3 (b), it can be confirmed that a large amount of Ca compound exists in the form of CaCO ₃ in GL-800.

Measurement example 3. Morphology analysis

(FE-SEM, S-4300, Hitachim Japan) and a transmission electron microscope (FE-TEM, JEM2100F, JEOL, Tokyo, Japan) were used for the samples prepared in Example 1 and Comparative Example 1 The morphology was analyzed and the results are shown in Fig. 4 (GL-MPs) and Fig. 5 (GL-AMPs), respectively.

Referring to FIG. 4, in the case of GL-MPs (Comparative Example 1) heat-treated with GLs and KOH at once, the yield was reduced to ~ 18 wt.%, But a large amount of Ca compound still remained on the surface of the sample . On the other hand, referring to FIG. 5, a large amount of Ca compound was removed after acid treatment of GL-MPs with a 40 wt.% Nitric acid solution (Example 1). The GL-AMPs (Example 1) have a random shape of micrometer-scale pieces (Fig. 1a-c), and a high resolution FE-TEM image shows the amorphous carbon structure of poorly graphitized graphite (Fig. 1D).

Measurement example 4. Structural analysis

Raman spectroscopy (514.5 nm wavelength, 2.41 eV, 16 mV power, 100x objective) and X-ray diffraction (XRD, Rigaku DMAX 2500, 40 kV, Cu- Kα radiation) was used to analyze the structure of GL-AMPs (Example 1) and GL-MPs (Comparative Example 1), and the results are shown in FIG.

Referring to Figure 6, in the XRD pattern, the main peaks at 29.3 urn show GL-MPs peak (104) of CaCO ₃ , and the GL-AMPs demarcated at 24 ㅀ near the faint graphite (002) peak Which is an amorphous carbon structure in which the Ca compound is removed (FIG. 6A). A distinct D band of ~ 1350 cm ^-1 and a G band of ~ 1580 cm ^-1 were observed in Raman spectra of GL-MPs and GL-AMPs (FIG. 6b). (I _D / I _G ) of the D-band peak and the G-band peak intensity is 1.13 for GL-MPs and 1.06 for GL-AMPs, indicating that it is composed of a nanometer-sized hexagonal carbon ring structure 6b).

Measurement example 5. Pore structure analysis

GL-AMPs (Example 1), GL-MPs (Comparative Example 1) and GL-800 (Comparative Example 2) were prepared using a nitrogen adsorption-desorption isotherm using surface area and porosity analyzer (ASAP 2020, Micromeritixs, USA) ). The results are shown in FIG.

Referring to FIG. 7, the isotherms of GL-AMPs and GL-MPs are mixed with IUPAC type-1 and type-4, indicating that both micropore and mesoporous structures exist (FIG. In contrast, the isotherm of the GL-800 shows a very small amount of nitrogen adsorbed on the surface of the sample. Differences in the amount of nitrogen adsorption between GL-800 and other samples (GL-AMPs, GL-MPs) occur mainly in the low relative pressure (<0.02) region. Isolation sites or monolayer nitrogen adsorption generally occur at low relative pressures. Therefore, large amounts of nitrogen adsorbed on GL-AMPs and GL-MPs indicate that these samples have a highly developed microporosity structure. In addition, hysteresis was observed in the desorption curves of GL-AMPs and GL-MPs. This is because the nitrogen gas is adsorbed and condensed in multiple layers when filling the pores. Hysteresis provides information about the mesopore structure. Both GL-AMPs and GL-MPs samples exhibit H4-type hysteresis, which is shown by slit-shaped pores. Mesoporous structures can occur when a hexagonal carbon layer is randomly aggregated. More specific pore size distributions of GL-AMPs and GL-MPs are shown in Figures 7b and 7c. Most micropores have a subnanometer scale. In particular, an ultra-micropore of 0.7 nm or less has been developed (Fig. 7B). GL-AMPs have about 30% larger pore volume than GL-MPs. In contrast, the mesopore structure of the two samples is similar (Figure 7c). The specific surface area of GL-AMPs is 1348.4 m ² / g, which is about 38% higher than that of GL-MPs (975.8 m ² / g). Details of the tissue characteristics are summarized in Table 2 below.

Textural properties (m ² g ^-1 ) S _BET S _MIC S _MESO GL-MPs 975.8 898.3 77.5 GL-AMPs 1348.4 1058.2 290.2

1) S _BET : BET specific surface area, 2) S _MIC : micropore specific surface area, 3) S _MESO : mesopore surface area.

Experimental Example 1. Electrochemical Characteristics

Electrochemical properties of GL-AMPs (Example 1) and GL-MPs were measured by cyclic voltammograms (CVs) and time potential difference method (PGSTAT302N, Autolab).

Ag / AgCl was used as a reference electrode and platinum wire was used as a counter electrode. A 2 M KOH aqueous electrolyte added with 6 M KOH aqueous electrolyte and 0.05 M para-phenylenediamine (PPM) was used . This was tested with a three-electrode beaker cell.

Add 5 wt.% Of polytetrafluoroethylene (PTFE, Sigma-Aldrich, 60 wt.% Dispersion ins H ₂ O) to each GL-AMPs and GL-MPs. Thereafter, it is spread on a sheet having a constant thickness of 40 to 50 mm, and a sufficiently dried electrode in a 100 ° C oven is cut to a size of 1 cm ² . The amount of active electrode is 3 to 4 mg.

The equation for calculating the non-accumulating capacity through the galvanostatic measurement is shown in the following equation (1).

Equation (1)

(1), C is the non-storage capacity, I _cons is the current constant, m is the weight of the carbon electrode, and dV / dt is the discharge curve calculated by the description of the discharge curve in the voltage window Value.)

Referring to FIG. 8, the electrochemical performance of GL-AMPs and GL-MPs electrodes in a 6 M aqueous KOH solution was tested. A near-rectangular graphical representation of the capacitor charge storage behavior over the entire voltage range is shown in the cycling voltammogram (FIG. 8a) of the GL-AMPs measured at a scan rate of 5 mV / s. In addition, a small redox peak is found due to the pseudo-capacitive charge storage of the oxygen function. Even if the scan ratio increases, it maintains a rectangular shape. This means that the mass transfer resistance is low. The smoothing voltage cur- rent curve (CV) (Fig. 8b) of GL-MPs shows a similar rectangular shape but is much smaller than the capacity of GL-AMPs. These capacity differences are due to the presence or absence of Ca compounds. Ca compounds mainly present as CaCO ₃ are electrochemically inactive but have a high density of 2.711 g / cm ³ . The Ca compound can be electrochemically removed to increase the non-storage capacity. To compare the electrochemical performance of GL-AMPs and GL-MPs, Ketjenblack (KB) with a specific surface area of about 1400 m ² / g was used as a reference (FIG. 8C). In the case of KB, the rectifying voltage cur- rent curve (CV), which is more rectangular than the two samples, exhibits excellent kinetic properties. In contrast, KB has a lower non-storage capacity than GL-AMPs. Referring to Figure 9, the galvanostatic charge / discharge test profile of GL-AMPs, GL-MPs, and KB showed an isosceles triangle shape consistent with the CV result (Figure 9A: GL -AMPs, Figure 9b: GL-MPs, Figure 9c: KB). In addition, such a profile exhibits a coulombic efficiency close to 100%.

The speed characteristics are shown in FIG. 8D through a constant current charge / discharge test. At a current density of 1 A / g, the non-storage capacity of GL-AMPs is about 302 F / g, which is a hierarchical porous carbon (~ 223 F / g) graphene (~ 250 F / g). It is also the non-storage capacity corresponding to twice the GL-MPs and three times the KB. As the current density increases, the capacitance remains at about 207 F / g at a current density of 35 A / g despite the decrease in capacitance. This is still about twice the value of KB. It can have a high non-storage capacity because it has an efficient pore structure for storing hydrated potassium ions. In addition, GL-AMPs exhibited stable characteristics over 5000 cycles in 6 M KOH aqueous solution, and excellent cycle characteristics maintaining 87% of initial capacity after 5000 cycles (FIG. 10).

Referring to FIG. 11, when the aqueous solution of 2M KOH added with 0.05 M of PDD was added, the non-storage capacity of GL-AMPs increased sharply. A large redox peak was observed in the smoothed voltage cur- rent curve (Figure 11a), and a voltage plateau was observed in the constant current charge / discharge profile (Figure 11b), which was caused by the faradaic process of the PPD. The smoothing voltage cur- rent curve and the constant-current charge / discharge profile show an electrochemical double layer and oblique voltage drop due to capacitor charge storage in the range of -0.4 to -1.0 V versus Ag / AgCl, respectively. These high capacities are derived from capacitor charge storage and faraday charge storage. The discharge capacity ratio of the GL-AMPs from the current density of 1 A / g to 15 A / g is shown in FIG. 11C. The non-reactive capacity of GL-AMPs at a current density of 1 A / g was 731 F / g, which was previously reported (J. Wu, H. Yu, L. Fan, G. Luo, J. Lin, M. Huang, J. Mater. Chem. 22 (2012) 19025.). The current density was maintained at 545 F / g when increased to 15 A / g. FIG. Lt; / RTI &gt; shows a constant current discharge profile at one current density. It was confirmed that the plaeau and sloping interval still appeared. The GL-AMPs showed a stable and excellent cycle, maintaining a capacitance of 85% after 1000 cycles in the cycle test (FIG. 11d).

FIG. 12 shows electrochemical performance using a 1 MH ₂ SO ₄ aqueous electrolyte containing 0.02 M hydroquinone, another redox mediated electrolyte system. Referring to FIG. 12, a current density of 15 A / g But still maintained a high non - current capacity of 570 F / g. However, it is confirmed that the electrochemical performance of the aqueous solution of 2 M KOH added with 0.05 M PPD is lower than that of the aqueous solution.

Sintering.

The carbon-based materials (GL-AMPs) of the present invention have an amorphous carbon structure with nanometer-scale hexagonal carbon containing redox active heteroatoms such as oxygen and nitrogen, and also have a number of 1348.4 m &lt; ² &gt; / g. In the 6 M KOH electrolyte as the electrode for the supercapacitor, GL-AMPs show non-discharge capacity ~ 302 F / g and ~ 207 F / g respectively at current density of 1 A / g and 35 A / g. The high energy and output characteristics were confirmed. In the 2 M KOH electrolyte containing PPD, a very high noncircular capacity of 731 F / g was obtained at a current density of 1 A / g, and 545 F / g The non-discharging capacity was maintained. In addition, GL-AMPs exhibited stable cycling characteristics over 1000 cycles.

Claims (11)

An electrode material for a supercapacitor comprising a microporous carbon-based material obtained from litters.
The method according to claim 1,
Wherein said leaves are ginkgo leaves.
The method according to claim 1,
Wherein the carbon-based material is a pyropolymer.
The method according to claim 1,
Wherein the carbon-based material has a Raman peak intensity ratio (I _D / I _G ) of 1.06 to 1.13.
The method according to claim 1,
Wherein the carbon-based material comprises a redox active heteroatom.
The method according to claim 1,
Wherein the carbon-based material comprises micropores of 0.7 nm or less.
(a) preparing a pulverized mixture by mixing the leaves and a basic solution and pulverizing the mixture;
(b) heat treating the pulverized mixture to produce a carbon-based material; And
(c) treating the dried carbon-based material with an acid to thereby produce an electrode material for a supercapacitor.
8. The method of claim 7,
Wherein the leaves are ginkgo leaves. &Lt; RTI ID = 0.0 &gt; 11. &lt; / RTI &gt;
8. The method of claim 7,
Wherein, in step (a), the basic solution is KOH.
8. The method of claim 7,
Wherein the step (b) is performed at a temperature elevating rate of 10 ° C / min under an inert gas atmosphere, and then heat-treated at 800 ° C to produce an electrode material for a supercapacitor.
8. The method of claim 7,
Wherein the step (c) comprises performing an acid treatment using nitric acid.

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