KR102426770B1 - Manufacturing Methods For Anode Composite Materials Of Na Secondary Batteries - Google Patents

Abstract

The present invention relates to a method for manufacturing a negative electrode material for a sodium secondary battery having excellent reversible characteristics. The present invention provides a starting material comprising phosphorus sulfide and Sb; and synthesizing amorphous antimony sulfide (Sb ₂ S ₃ ) and phosphorus by milling the starting material. In the composite negative electrode material of the present invention, the reaction product obtained from the starting material has high reversible properties and is evenly dispersed. In addition, it is possible to synthesize the composite active material of the negative electrode material by a simple method, and it is possible to disperse the composite active material on the conductive material matrix.

Description

Manufacturing Methods For Anode Composite Materials Of Na Secondary Batteries

The present invention relates to a method for manufacturing a negative electrode material for a sodium secondary battery, and more particularly, to a method for manufacturing a composite negative electrode material for a sodium secondary battery having excellent reversible characteristics.

Lithium secondary batteries have been commercialized since the 1990s, functioning as a core power source for small IT devices and power tools, and expanding their scope to power sources for electric vehicles (EV, HEV, PHEV).

Lithium resources, the main material of lithium secondary batteries, are limited to South American continents such as Argentina, Bolivia, and Chile.

On the other hand, sodium is very advantageous in terms of raw material supply and demand because of its abundant reserves and low price.

Research on sodium ion batteries began in the 1970s, but lithium batteries were first commercialized and did not attract attention. However, as the need for non-lithium-based Post-Li batteries emerged, full-scale research on sodium ion batteries was being conducted.

The sodium secondary battery has the same operating principle and similar structure as that of the lithium secondary battery, so it has potential as a secondary battery, but it does not reach the characteristics of the lithium secondary battery. However, it can be an innovative alternative that can overcome the limitations of the current lithium secondary battery market as an energy storage and conversion device based on advantages such as easy resource supply and demand and low cost.

In the case of a sodium secondary battery, the cathode active material is mainly composed of oxide-based materials such as NaCrO ₂ , NaMnO ₂ , NaFePO ₄ , polyanions such as Na ₃ V ₂ (PO ₄ ) ₃ , NaFePO ₄ , and Na _x TiS ₂ . Research is being conducted by dividing it into sulfide series, fluoride series such as FeF ₃ , and phosphate series such as NASICON.

However, research on anode materials for Na-ion batteries is very insignificant. Graphite materials used as negative electrode materials for commercial Li-ion batteries do not undergo electrochemical intercalation with Na ions, so they are mainly made of petroleum cokes, carbon black, hard carbon, etc. material is known as a candidate for anode material.

Among carbon-based materials, a hard carbon-based material has been reported to have a capacity of ~300 mAh/g, but in consideration of voltage characteristics and low initial efficiency, the actual capacity that can be used in a battery is within 180 mAh/g.

In addition, in the case of TiO ₂ in addition to the carbon-based material, a low capacity of 100 mAh/g has been reported. In addition, the recently reported Sn, Sb, and Pb series are known to be capable of storing Na ions, but technical problems to be solved such as volume expansion and low charge/discharge efficiency are scattered.

In order to solve the problems of the prior art, an object of the present invention is to provide a method for manufacturing a composite negative electrode material having low irreversible properties and in which an active material for Na is evenly dispersed.

Another object of the present invention is to provide a method for synthesizing a composite negative electrode material having high reversible properties without applying a chemical method to the synthesis of an active material.

Another object of the present invention is to provide a composite negative electrode material in which active materials are evenly dispersed on a conductive material matrix while simultaneously synthesizing Sb ₂ S ₃ and P, which are active materials for Na.

An object of the present invention is to provide a method for preparing a negative active material for a sodium secondary battery having high capacity and cycle characteristics.

In order to achieve the above technical problem, the present invention provides a starting material comprising phosphorus sulfide and Sb; and synthesizing amorphous antimony sulfide (Sb ₂ S ₃ ) and phosphorus by milling the starting material.

In the present invention, the synthesizing step may include dry high-energy milling of the starting material.

Also, in the present invention, the high energy milling step may be performed by planetary milling at 200 rpm or more.

In addition, in an embodiment of the present invention, the phosphorus sulfide preferably includes P ₂ S ₅ .

In addition, according to an embodiment of the present invention, it is preferable that the phosphorus sulfide and Sb of the starting raw material are blended according to the following formula (1).

(Formula 1)

3P ₂ S ₅ + 10Sb → 5Sb ₂ S ₃ + 6P

In the present invention, the starting material may further include a conductive material, and the composite negative electrode material may be one in which amorphous antimony sulfide (Sb ₂ S ₃ ) and phosphorus are dispersed in a matrix phase of the conductive material.

In this case, the conductive material may include super P black.

In the present invention, at least one selected from the group consisting of P ₂ S ₅ , P ₄ S ₄ , P ₄ S ₅ , P ₄ S ₃ , P ₄ S ₇ and P ₄ S ₉ may be used as the phosphorus sulfide.

According to the present invention, it is possible to provide a composite negative electrode material suitable for a sodium secondary battery. In the composite negative electrode material of the present invention, the reaction product obtained from the starting material has high reversible properties and has an even dispersion in the composite negative electrode material. According to the present invention, it is possible to synthesize a composite active material of an anode material by a simple method, and dispersion of the composite active material on a conductive material matrix is possible.

1 is a schematic flowchart illustrating a method of manufacturing an anode active material according to an embodiment of the present invention.
2 is a graph showing an XRD pattern of a specimen obtained after milling according to an embodiment of the present invention.
3 is a photograph of a composite anode material sample powder synthesized according to an embodiment of the present invention observed with a transmission electron microscope.
4 is a graph showing the analysis results of the synthesized composite negative electrode material sample by X-ray optical spectroscopy (XPS).
Figure 5 (a) is a graph showing the result of measuring the initial charge and discharge characteristics, Figure 5 (b) is a differential capacity plot (differential capacity plot) for (a).
6 is a graph showing the charging and discharging characteristics of a battery sample prepared from the composite negative electrode material according to an embodiment of the present invention.
7 is a graph showing the cycle characteristics of a battery sample prepared from the composite negative electrode material according to an embodiment of the present invention.
8 is a graph showing cycle characteristics at a current density of 200 mA/g of a battery sample prepared from the composite negative electrode material according to an embodiment of the present invention.
9 is a graph showing cycle characteristics at a current density of 50 mA/g of a battery sample prepared from the composite negative electrode material according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the drawings.

In an embodiment of the present invention, the composite anode material for a sodium secondary battery includes an antimony sulfide (Sb ₂ S ₃ , antimony sulfide)-based active material.

As a precursor for manufacturing the composite negative electrode material of the present invention, sulfide, metal antimony powder, and carbon powder may be used. The sulfide of the present invention may be a compound that reacts with metal antimony to spontaneously generate Sb ₂ S ₃ .

In the present invention, various phosphorus sulfide may be used as the sulfide, but diphosphorus pentasulfide (P ₂ S ₅ ) is preferably used. In addition, as the phosphorus sulfide in the present invention, one compound selected from the group consisting of P ₄ S ₄ , P ₄ S ₅ , P ₄ S ₃ , P ₄ S ₇ and P ₄ S ₉ may be used. Of course, a mixture of one or more of the phosphorus sulfide listed as the phosphorus sulfide in the present invention may be used.

The composite anode material can be synthesized based on a spontaneous reaction represented by the following chemical formula.

(Formula 1)

As shown in Formula 1, in the present invention, diphosphorus pentasulfide (P ₂ S ₅ ) is used as a precursor of the active material. Diphosphorus pentasulfide is unsuitable as an anode material because of its low electronic conductivity, but it can react spontaneously with antimony (Sb) at room temperature to synthesize antimony sulfide.

Conventionally, the use of antimony sulfide as an anode active material of a lithium secondary battery has been proposed, but antimony sulfide is prepared by a complex chemical method such as a co-precipitation method, a reduction method, and a sol-gel method, which may contain many impurities. . This presents a problem that the irreversible capacity is high.

In the present invention, by using P ₂ S ₅ and Sb as precursors for the synthesis of antimony sulfide and inducing a spontaneous reaction according to Chemical Formula 1, a composite negative electrode material containing Sb ₂ S ₃ and phosphorus as an anode material active material can be prepared. have.

Further, in the present invention Sb ₂ S ₃ In the method for synthesizing a negative electrode material based on carbon, it is possible to prepare a composite negative electrode material in which Sb ₂ S ₃ and phosphorus (P) are dispersed on a carbon matrix by adding carbon to the raw material.

1 is a flowchart schematically illustrating a method for manufacturing a composite negative electrode material according to an embodiment of the present invention.

Referring to FIG. 1 , first, P ₂ S ₅ as a sulfide precursor, and antimony metal powder as an antimony source are prepared. In addition, carbon powder may be added as a conductive material in the present invention (S110). As the conductive material, super P black (super pure carbon black) may be used.

When the added conductive material is according to the manufacturing method of the present invention, it is possible to manufacture a composite negative electrode material in which nano-sized Sb ₂ S ₃ and P particles are well dispersed in the conductive material matrix.

In addition, the composite negative electrode material of the present invention may additionally further include a binder. As the binder, for example, a material commonly used for secondary batteries such as polyacrylic acid (PAA) may be used.

The prepared raw material powder is mixed and milled (S120). In the present invention, high energy milling may be used as the milling method.

In the present invention, high energy milling may be performed by a planetary mill. The energy supplied by the planetary mill is proportional to the rotational speed of the disk and the effective diameter of the disk, and this value can be expressed by the gravitational acceleration (G) expressed by the following equation.

G = (disk rpm × 2π / 60) ² × R1/g

(where R1 is the effective radius of the disk in m, g=9.8 m ² /s)

For example, FRITSCH's model name Pulverisette-5 has an effective radius of the main disk of 0.125 m, so the gravitational acceleration at a rotation speed of 400 rpm is about 22 G. In addition, FRITSCH's model name Pulverisette-7 has an effective radius of the main disk of 0.07 m, so it is about 50 G at a rotation speed of 800 rpm. In the present invention, high-energy milling refers to milling in which a gravitational acceleration of 10 G or more is applied in a rotation system.

In the present invention, the rotational speed of the planetary mill may be, for example, 300 rpm or more. Of course, in the present invention, it is possible to produce the negative electrode composite material of the present invention even at a rotation speed of 300 rpm or less. At this time, the milling time and the stopping time may be controlled according to the rotation speed.

According to an embodiment of the present invention, high energy milling may be performed by a dry method. Dry milling is preferably applied if the starting material has a high reactivity to moisture. However, otherwise, it will be appreciated by those skilled in the art that mechanical milling by the wet method is also applicable to the present invention.

Through this synthesis step, Sb ₂ S ₃ , it is possible to prepare an anode composite comprising P and carbon (S130). Sb ₂ S ₃ and P synthesized in the present invention act as active substances for Na.

In addition, according to the present invention, by weighing the starting material at the mixing ratio according to Formula 1, the synthesized negative electrode material is composed of a composite active material of Sb ₂ S ₃ and P reversible with respect to Na, thereby reducing the irreversible capacity. Here, the added carbon functions as a conductive material.

In addition, according to the method of the present invention, it is possible to manufacture an anode material composed of a nano-sized active material composite. Conventionally, attempts have been made to manufacture nano-sized negative active materials to suppress volume expansion, but these methods have disadvantages such as surface reactivity due to high specific surface area, excessive use of binder/conductive material, low initial efficiency, etc. This made it difficult to use in practice. However, in the present invention, Sb ₂ S ₃ /P/C is not a simple mixture, but can be prepared as a complex by a spontaneous reaction, thereby alleviating such disadvantages.

Hereinafter, preferred embodiments of the present invention will be described.

<Sb ₂ S ₃ /P/C Composite Synthesis by Milling>

P ₂ S ₅ powder (Aldrich, >99%, 10㎛) and Sb powder (Aldrich, 99%, -100 Mesh) were mixed in a molar ratio of 3:10, and this mixture and super P carbon were mixed with a weight ratio of 7:3 Mixed in proportions and milled. Milling was dry-milled in an Ar atmosphere in a planetary mill (FRITSCH's model name: Puverisette-5, Puverisette-7).

The effect of milling conditions on the reaction product was observed by varying the milling time. Milling was performed by periodically repeating the milling and stopping states, and the milling time in this experimental example means the total time of repeating the milling/stop cycle. The milling/stop schedule can be appropriately set to suppress the overheating of the machine, the milling speed was set to 300 rpm, and the 20-minute milling and 10-minute stops were periodically repeated.

2 is a graph showing an XRD pattern of a specimen obtained after milling.

Referring to Figure 2, it can be seen that the Sb peak of the starting material decreases with the lapse of milling time, and a weak peak is observed at 12 hours (HEMM-12hrs) and 24 hours (HEMM-24hrs) milling, but at 36 hours ( HEMM-36hrs), it can be seen that no Sb peak is observed after milling. From this, it can be inferred that Sb of the starting material participates in the reaction and is consumed and an amorphous material is produced.

3 is a photograph of the synthesized composite anode material sample powder observed with a transmission electron microscope. The HEMM-36hrs sample was used as the composite anode material sample.

First, (a) and (b) of Figure 3 are transmission electron microscope images of the synthetic powder, (c) is a diffraction pattern image (SAED: selected area diffraction pattern), (d) to (g) are each C, It is an EDS mapping picture of Sb, S, and P elements.

From FIG. 3, it can be seen that Sb, S, P, and C, which are constituent elements of each phase, are uniformly distributed, and it can be seen that a uniform composite material is formed.

4 is a graph showing the analysis results of the synthesized composite negative electrode material sample by X-ray optical spectroscopy (XPS).

Sb ₂ S ₃ bonding can be confirmed from (a) and (b) of FIG. 4 . In addition, it can be seen that the bond related to P ₂ S ₅ and Sb of the starting material disappears.

In addition, it can be seen from (c) of FIG. 4 that P remaining as a result of the Sb ₂ S ₃ synthesis reaction exists in a state bonded to carbon.

From the above results, it can be seen that P ₂ S ₅ and Sb provided as starting materials participate in the reaction and are consumed, and as a result of the synthesis reaction, amorphous Sb ₂ S ₃ and P are generated.

<Na battery characteristics evaluation>

A slurry was prepared from the composite negative electrode material sample synthesized in the above-described experimental example and PAA, applied on Cu foil, vacuum cured at a temperature of 150° C., and punched into a circular shape of φ 14 mm to prepare a negative electrode. As the counter electrode (auxiliary electrode, counter electrode), a Na metal plate was used. As the electrolyte, a 1M NaClO ₄ solution in which NaClO ₄ was dissolved in a solvent containing 1/1 EC/PC in volume ratio and 5% FEC was used. A coin cell was manufactured by stacking Cu foil, a cathode, a separator (GMF, Glass Microfiber Filter), a gasket, an anode, a spacer, and a spring in a stainless steel container in this order.

The charge/discharge characteristics and cycle characteristics of the prepared coin cell were evaluated. A SERIES-4600A from Maccor was used as the measuring device, and the cut-off voltage was 0.005 to 2V, and the constant current density was in the range of 50 mA/g to 2A/g.

Figure 5 (a) is a graph showing the result of measuring the initial charge and discharge characteristics, Figure 5 (b) is a differential capacity plot (differential capacity plot) for (a).

The portion indicated by the peak on the graph in (b) of FIG. 5 means the potential at which the reaction mainly occurred.

From FIG. 5, it can be seen that the sodiation capacity and desodiation capacity of the composite anode material are about 900 mAh g ^-1 and 687 mAh g ^-1 , and the initial efficiency is about 76%, indicating high reversibility.

In addition, it can be seen from (b) of FIG. 5 that the peaks in the first cycle appear at 0.33, 0.78, and 1.29V, which is the reaction of the Sb ₂ S ₃ /P/C composite negative electrode material with Na and the formation of the SEI layer. is due to

6 is a graph showing charge/discharge characteristics at each charging current density, and FIG. 7 is a graph showing cycle characteristics.

As a result of charging and discharging 5 cycles at current densities of 50, 200, 500, 1000, and 2000 mA/g, a high capacity of 382 mAh/g was obtained even at 2000 mA/g (=3C rate), and 50 mA/g When the current density is lowered again, it can be seen that the initial capacity is easily restored. This is considered to be due to the fact that in the composite negative electrode material according to the present invention, Sb ₂ S ₃ and P are uniformly distributed on the carbon matrix, and stress generated during sodiation and desodiation reactions can be suppressed.

8 is a graph showing cycle characteristics at a current density of 200 mA/g, and FIG. 9 is a graph showing cycle characteristics at a current density of 50 mA/g.

As a result of the cycle experiment at 200 mA/g from FIG. 8, it can be seen that high cycle characteristics such as maintaining 87.2% (533 mAh/g) of the initial capacity until 70 cycles are shown. The blue graph in FIG. 8 shows the coulombic efficiency, and since it shows an average efficiency of 99.7%, it is expected that high performance will be exhibited even when the anode and the full cell are manufactured.

As a result of the cycle experiment at 50 mA/g from FIG. 9, it can be seen that after 100 cycles, it exhibits a capacity almost similar to the initial capacity, such as a capacity of 649 mAh/g.

Claims (8)

providing a starting material comprising phosphorus sulfide and Sb; and
Milling the starting material to synthesize amorphous antimony sulfide (Sb ₂ S ₃ ) and phosphorus. According to claim 1,
The synthesis step is
Method for producing a negative active material for a sodium secondary battery, characterized in that it comprises the step of dry high-energy milling the starting material. 3. The method of claim 2,
The high-energy milling step is
Method for producing a negative active material for a sodium secondary battery, characterized in that the planetary milling at 200 rpm or more. According to claim 1,
The phosphorus sulfide is P ₂ S ₅ Method for producing a negative active material for a sodium secondary battery, characterized in that it comprises. 5. The method of claim 4,
The phosphorus sulfide and Sb are a method for producing a negative active material for a sodium secondary battery, characterized in that it is blended according to the following formula (1).
(Formula 1)
3P ₂ S ₅ + 10Sb → 5Sb ₂ S ₃ + 6P According to claim 1,
The starting material further comprises a conductive material,
A method of manufacturing a negative active material for a sodium secondary battery, characterized in that amorphous antimony sulfide (Sb ₂ S ₃ ) and phosphorus are dispersed in the matrix phase of the conductive material. 7. The method of claim 6,
The method for producing a negative active material for a sodium secondary battery, characterized in that the conductive material comprises super P black. According to claim 1,
The phosphorus sulfide is sodium 2, characterized in that it contains at least one selected from the group consisting of P ₂ S ₅ , P ₄ S ₄ , P ₄ S ₅ , P ₄ S ₃ , P ₄ S ₇ and P ₄ S ₉ . A method for producing a negative active material for a secondary battery.

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