ANODE MATERIAL FOR LITHIUM-ION BATTERY AND ANODE FOR LITHIUM-ION BATTERY

Abstract

The present invention relates to an anode material for lithium-ion batteries. The anode material for lithium-ion batteries is represented by the molecular formula: M.sub.xN.sub.yTi.sub.zO.sub.(x+3y+4z)/2, where: 0x8, 1y8, and 1z8; M is an alkali metal selected from the group consisting of Li, Na, and K; and N is a group V.sub.A element selected from the group consisting of P, Sb, and Bi or a rare earth metal selected from the group consisting of Nd, Pm, Sm, Eu, Yb, and La. The anode material of the present invention has a delithiation potential of 0.8 to 1.2 V vs. Li.sup.+/Li, and has a better potential plateau, better cycle performance, and better output-input properties, than a titanium-based anode material.

Claims

1. An anode material for lithium-ion batteries, the anode material being represented by a molecular formula: M.sub.xN.sub.yTi.sub.zO.sub.(x+3y+4z)/2, where: 0x8, 1y8, and 1z8; M is an alkali metal selected from the group consisting of Li, Na, and K; and N is a group V.sub.A element selected from the group consisting of P, Sb, and Bi or a rare earth metal selected from the group consisting of Nd, Pm, Sm, Eu, Yb, and La.

2. The anode material for lithium-ion batteries according to claim 1, wherein 0x5, 1y5, and 1z5.

3. The anode material for lithium-ion batteries according to claim 1, wherein M is Li or Na, and N is Bi or Eu.

4. The anode material for lithium-ion batteries according to claim 1, wherein the anode material is LiEuTiO.sub.4, NaBiTiO.sub.4, LiBiTiO.sub.4, or Bi.sub.4Ti.sub.3O.sub.12.

5. The anode material for lithium-ion batteries according to claim 1, wherein the anode material has a particle size of 0.1 to 20 m.

6. An anode for lithium-ion batteries comprising the anode material for lithium-ion batteries according to claim 1 as an active material.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] The invention, together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which:

[0014] FIG. 1 is an XRD pattern of the anode material LiEuTiO.sub.4 of Example 1;

[0015] FIG. 2 is an SEM view of the anode material LiEuTiO.sub.4 of Example 1;

[0016] FIG. 3 is a charge/discharge graph of the anode material LiEuTiO.sub.4 of Example 1;

[0017] FIG. 4 is a cycle characteristic diagram of the anode material LiEuTiO.sub.4 of Example 1;

[0018] FIG. 5 is an XRD pattern of the anode material NaBiTiO.sub.4 of Example 2;

[0019] FIG. 6 is an SEM view of the anode material NaBiTiO.sub.4 of Example 2;

[0020] FIG. 7 is a charge/discharge graph of the anode material NaBiTiO.sub.4 of Example 2;

[0021] FIG. 8 is an XRD pattern of the anode material LiBiTiO.sub.4 of Example 3;

[0022] FIG. 9 is an SEM view of the anode material LiBiTiO.sub.4 of Example 3;

[0023] FIG. 10 is a charge/discharge graph of the anode material LiBiTiO.sub.4 of Example 3;

[0024] FIG. 11 is an XRD pattern of the anode material Bi.sub.4Ti.sub.3O.sub.12 of Example 4;

[0025] FIG. 12 is an SEM view of the anode material Bi.sub.4Ti.sub.3O.sub.12 of Example 4; and

[0026] FIG. 13 is a charge/discharge graph of the anode material Bi.sub.4Ti.sub.3O.sub.12 of Example 4.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0027] The anode material compound according to the present invention is represented by the molecular formula: M.sub.xN.sub.yTi.sub.zO.sub.(x+3y+4z)/2, where 0x8, 1y8, and 1z8; M is an alkali metal selected from the group consisting of Li, Na, and K; and N is a group V.sub.A element selected from the group consisting of P, Sb, and Bi or a rare earth metal selected from the group consisting of Nd, Pm, Sm, Eu, Yb, and La.

[0028] Preferably, 0x5, 1y5, and 1z5.

[0029] Preferably, M is Li or Na, and N is Bi or Eu.

[0030] The anode materials obtained in specific examples of the present invention are crystalline particles in a sheet form or in an aggregated form, the size of which is 0.1 to 20 m, preferably 0.2 to 10 m. However, the form and the size of particles of the anode material of the present invention are not specially required, as long as the particle conditions as a common anode raw material for lithium batteries are satisfied.

[0031] The anode material of the present invention can be synthesized by three methods of a solid phase method, a solvothermal method, and a sol-gel method. The M source used as a reaction raw material is an alkali metal hydroxide, carbonate, oxalate, nitrate, acetate, or sulfate. The titanium source is, for example, titanium dioxide, titanium tetrachloride, tetrabutyl titanate, or isopropyl titanium. The N source is an oxide, a nitrate, a carbonate, an oxalate, a sulfate, or a citrate, of group VA elements or rare earth metals.

[0032] Conventional Solid Phase Reaction Method:

[0033] The M source, the titanium source, and the N source are mixed at a stoichiometric mixing ratio based on the molecular formula of a desired anode material compound (for example, by a method of ball milling or grinding), and the mixture is then subjected to heat treatment (for example, for 2 to 24 hours at 600 to 1200 C.). Then, ion exchange is optionally performed in the condition of a molten salt (for 3 to 24 hours at 300 to 700 C.) (For example, in the case of synthesizing LiEuTiO.sub.4, since a Li element easily volatilizes in high temperature treatment, NaEuTiO.sub.4 is first obtained using a Na element, and then it is subjected to ion exchange with a molten Li salt (for example, LiNO.sub.3) to thereby obtain LiEuTiO.sub.4. Specifically, refer to the production process in examples to be described below.). Finally, the product is washed (washed with water or alcohol) and dried (for 6 to 24 hours at 60 to 150 C.)

[0034] Solvothermal Method:

[0035] The M source, the titanium source, and the N source are dissolved and stirred (for 0.5 to 6 hours) in a solvent (for example, water, ethanol, acetic acid, aqueous ammonia, nitric acid, or sodium hydroxide) at a stoichiometric mixing ratio based on the molecular formula of a desired anode material compound to thereby disperse and dissolve the reaction raw materials. Then, the resulting solution is put, for example, into a stainless steel reaction kettle and subjected to heat treatment (for 12 to 48 hours at 120 to 220 C.). Finally, a precipitated product is collected, washed (with water or alcohol), and dried (for 6 to 24 hours at 60 to 150 C.)

[0036] Sol-Gel Reaction Method:

[0037] An alkali metal salt (for example, a hydroxide, a carbonate, an oxalate, a nitrate, an acetate, a sulfate, or the like) is dissolved and stirred in a solvent (for example, water, ethanol, acetic acid, aqueous ammonia, nitric acid, or a solution of sodium hydroxide or the like). A group VA element or a rare earth metal (for example, an oxide, a nitrate, a carbonate, an oxalate, a sulfate, a citrate, or the like) is dissolved in a solvent (for example, water, ethanol, acetic acid, aqueous ammonia, nitric acid, or the like), and the resulting solution is then added to the alkali metal salt solution with stirring. Then, the titanium source (for example, titanium dioxide, titanium tetrachloride, tetrabutyl titanate, isopropyl titanium, or the like) is added to the mixture, followed by adding water thereto. The liquid mixture is stirred for 2 hours and then aged for 10 to 48 hours at 80 to 120 C., and an excess solvent is removed by evaporation. The resulting dry gel (a metal oxide or hydroxide or a blend thereof) is incinerated for 2 to 15 hours at 500 to 1,200 C.

[0038] Measurement of Anode Material

[0039] The crystal structure and morphology of M.sub.xN.sub.yTi.sub.zO.sub.(x+3y+4z)/2 material were analyzed by XRD and SEM, and the electrochemical performance when it is used as an anode material for lithium-ion batteries was measured.

[0040] Electrochemical Performance Measurement Conditions:

[0041] In the measurement of a battery, the anode material is used as a working electrode, and metallic lithium is used as a counter electrode.

[0042] Electrolyte solution: diethyl carbonate/dimethyl carbonate=1/1, 1 M LiPF.sub.6; temperature: 25 C.;

[0043] Binder: carboxymethyl cellulose (CMC);

[0044] Component ratio of electrode material: anode material (active material): conductive acetylene black: CMC=70:20:10;

[0045] Diaphragm: PE polymer diaphragm;

[0046] Voltage range: 0.01 to 3.0 V vs. Li.sup.+/Li.

EXAMPLES

Example 1. LiEuTiO.SUB.4

[0047] Production Method: Solid Phase Reaction Method

[0048] In a mortar, 0.13 mol of Na.sub.2C.sub.2O.sub.4, 0.2 mol of TiO.sub.2, and 0.1 mol of Eu.sub.2O.sub.3 were ground and mixed at a stoichiometric mixing ratio as reaction raw materials. Then, the resulting mixture was subjected to heat treatment (for 12 hours at 900 C.) to thereby obtain 0.2 mol of NaEuTiO.sub.4. The ion exchange between NaEuTiO.sub.4 and lithium ions was performed in 0.26 mol of molten LiNO.sub.3 (for 12 hours at 350 C.). Then, the resulting product LiEuTiO.sub.4 was washed (washed with water) and dried in an oven (at 80 C.)

[0049] As shown in the X-ray diffraction pattern (XRD pattern, FIG. 1) of the product, LiEuTiO.sub.4 that was excellent in crystallinity was successfully synthesized.

[0050] As shown in the scanning electron microscope view (SEM view, FIG. 2) of LiEuTiO.sub.4, the product was in a sheet form and had a size of about 2 m.

[0051] Electrochemical Performance:

[0052] The electrochemical performance of LiEuTiO.sub.4 was measured, and the plateau in the charge/discharge graph was about 0.8 V. Referring to FIGS. 3 and 4, the charge/discharge current density was 100 mA/g.

[0053] The charge/discharge graph of LiEuTiO.sub.4 has one potential plateau of 0.8 V vs Li.sup.+/Li, which is in agreement with the target of the invention of the present application. As shown in FIG. 3, the discharge specific capacity of LiEuTiO.sub.4 was stably maintained at 170 mAh g.sup.1 after 100 cycles, and the coulombic efficiency was about 100% after 20 cycles.

Example 2. NaBiTiO.SUB.4

[0054] Method: Solid Phase Reaction Method

[0055] In a mortar, 0.1 mol of Na.sub.2C.sub.2O.sub.4, 0.2 mol of TiO.sub.2, and 0.1 mol of Bi.sub.2O.sub.3 were ground and mixed at a stoichiometric mixing ratio as reaction raw materials. Then, the resulting mixture was subjected to heat treatment (for 12 hours at 800 C.) to thereby obtain 0.2 mol of NaBiTiO.sub.4. The resulting product NaBiTiO.sub.4 was washed (washed with water) and dried in an oven (at 80 C.)

[0056] As shown in the XRD pattern (FIG. 5), NaBiTiO.sub.4 that was excellent in crystallinity was successfully synthesized.

[0057] As shown in the SEM view (FIG. 6), the product was in a sheet form and had a micron-level size.

[0058] Electrochemical Performance:

[0059] As shown in the charge/discharge graph (FIG. 7) of NaBiTiO.sub.4, it has one potential plateau of 0.8 V vs Li.sup.+/Li. The specific capacity of NaBiTiO.sub.4 is maintained at 355 mAh g.sup.1 after 10 cycles.

Example 3. LiBiTiO.SUB.4

[0060] Method: Solid Phase Reaction Method

[0061] In a mortar, 0.13 mol of Na.sub.2C.sub.2O.sub.4, 0.2 mol of TiO.sub.2, and 0.1 mol of Bi.sub.2O.sub.3 were ground and mixed at a stoichiometric mixing ratio as reaction raw materials. Then, the resulting mixture was subjected to heat treatment (for 12 hours at 800 C.) to thereby obtain 0.2 mol of NaBiTiO.sub.4. The ion exchange between NaBiTiO.sub.4 and lithium ions was performed in 0.26 mol of molten LiNO.sub.3 (for 12 hours at 350 C.). Then, the resulting product LiBiTiO.sub.4 was washed (washed with water) and dried in an oven (at 80 C.)

[0062] As shown in the XRD pattern (FIG. 8), LiBiTiO.sub.4 was successfully synthesized.

[0063] As shown in the SEM view (FIG. 9), the product was in a sheet form and had a size of 1 to 2 m.

[0064] Electrochemical Performance:

[0065] As shown in the charge/discharge graph (FIG. 10) of LiBiTiO.sub.4, it has one potential plateau of 0.8 V vs Li.sup.+/Li. The specific capacity of LiBiTiO.sub.4 is maintained at 217.8 mAh g.sup.1 after 50 cycles.

Example 4. Bi.SUB.4.Ti.SUB.3.O.SUB.12

[0066] Method: Hydrothermal Method (Solvothermal Method)

[0067] Each of 0.1 mol of bismuth nitrate and 0.075 mol of isopropyl titanium was put into 100 mL of water, and then a KOH solution was added thereto until the pH value increased to 12. An ultrasonic wave was applied to the solution obtained in this way for 30 minutes, and then the solution was put into a hydrothermal reaction kettle and heated for 24 hours at 180 C. Finally, the resulting precipitate was washed with water and then dried with 80 C. air.

[0068] As shown in the XRD pattern (FIG. 11) of the product, Bi.sub.4Ti.sub.3O.sub.12 was successfully synthesized.

[0069] As shown in the SEM view (FIG. 12) of the product, the product has a sample size of about 300 to 500 nm and is aggregated.

[0070] Electrochemical Performance:

[0071] As shown in the charge/discharge graph (FIG. 13) of Bi.sub.4Ti.sub.3O.sub.12, it has one potential plateau of 0.8 V vs Li.sup.+/Li. The specific capacity of Bi.sub.4Ti.sub.3O.sub.12 is maintained at 275.8 mAh g.sup.1 after 60 cycles.

Comparative Example 1: Na.SUB.2.Li.SUB.2.Ti.SUB.6.O.SUB.14 .(J. Power Sources, 293, 33-41, 2015)

[0072] The delithiation potential is 1.25 V, and the plateau is short and the plateau capacity is only about 80 mAh g.sup.1. Further, the discharge specific capacity after 30 cycles was about 175 mAh g.sup.1.

Comparative Example 2: MLi.SUB.2.Ti.SUB.6.O.SUB.14 .(M=Sr, Ba, or 2Na) (Inorg. Chem. 2010, 49, 2822-2826)

[0073] The plateau potential was about 1.5 V, the specific capacity was low, and the first discharge specific capacity was about 120 to 160 mAh g.sup.1.