CN117293312B

CN117293312B - Hard carbon material, preparation method and application thereof, and sodium ion battery

Info

Publication number: CN117293312B
Application number: CN202311579178.1A
Authority: CN
Inventors: 李启东; 王硕; 李子坤; 黄友元
Original assignee: Shenzhen Beiteri New Energy Technology Research Institute Co ltd
Current assignee: Shenzhen Beiteri New Energy Technology Research Institute Co ltd
Priority date: 2023-11-24
Filing date: 2023-11-24
Publication date: 2024-03-12
Anticipated expiration: 2043-11-24
Also published as: CN117293312A

Abstract

The invention provides a hard carbon material, a preparation method and application thereof, and a sodium ion battery. The preparation method comprises the following steps: sequentially carbonizing, crushing and purifying a carbon source to obtain a carbonized material precursor; sequentially sintering the carbonized material precursor at low temperature Duan Shaojie and high temperature, and performing post-treatment to obtain a hard carbon material; the low temperature Duan Shaojie adopts a first heating rate and a first sintering temperature, the high temperature section sintering adopts a second heating rate and a second sintering temperature, the first heating rate is higher than the second heating rate by more than 4.5 ℃/min, and the first sintering temperature is lower than the second sintering temperature by more than 200 ℃. The preparation method can obtain the hard carbon material with small domain size and low oxygen content, and the sodium ion battery based on the hard carbon material has higher reversible capacity, high first coulomb efficiency and good dynamic performance.

Description

Hard carbon material, preparation method and application thereof, and sodium ion battery

Technical Field

The invention belongs to the technical field of carbon materials, and particularly relates to a hard carbon material, a preparation method and application thereof, and a sodium ion battery.

Background

In recent years, lithium electricity price has rapidly increased, and the problem of insufficient lithium ore resources faced in the field of large-scale application has been getting worse. Sodium Ion Batteries (SIBs) rely on sodium resources that are lower cost and more abundant than lithium batteries, and are widely recognized as the most competitive alternatives to lithium ion batteries. The graphite cathode materials commonly used in lithium ion batteries have very low sodium storage capacity and are not suitable for sodium ion battery systems. The hard carbon material has a long and highly reversible plateau region (< 0.1V), so that its performance in sodium ion batteries is relatively similar to that of graphite in lithium ion batteries, and is one of the preferred negative electrode materials for sodium ion batteries.

However, the application of the hard carbon material in the sodium ion full battery still has some challenges, wherein the main thing is that the hard carbon material has poor dynamic performance, is difficult to be compatible with high capacity and high rate performance, and has great hidden danger of sodium precipitation. Aiming at the problems, the CN115347185A is doped with N, br and Ca to exert the synergistic effect of three anions and cations co-doping, increase the interlayer spacing of the hard carbon, cause defect sites, improve the embedding capacity and the adsorption capacity of the hard carbon material and improve the multiplying power performance of the material; meanwhile, by introducing calcium-carbon ionic bonds and combining three ions, the multiplying power performance of the material is further improved, so that the nitrogen-bromine-calcium co-doped hard carbon material has good charge-discharge cycling stability under a large multiplying power. However, doping of the hetero atoms can have a certain improvement effect on the rate performance, but the doping process is complex, the efficiency is lower, and meanwhile, the cost of doping auxiliary materials is increased, so that the hard carbon material loses the cost advantage of the hard carbon material. And the sodium storage capacity provided by the heteroatom defect is poor in reversibility and poor in cycle performance. CN114524433a utilizes the characteristic that agarose can form gel state, so that agarose and template agent form a highly dispersed integral structure, then the use amount of different template agents is regulated to realize the optimal regulation of pore diameter and number of pores, and further the specific surface area and defect sites of porous carbon are regulated, so that unnecessary specific surface area and defect sites are reduced, and the hierarchical porous structure hard carbon material is obtained. Although the construction of the pore structure of the hard carbon material can improve the sodium storage capacity, the pore diameter suitable for sodium ion storage has stricter requirements, and the oversized pore structure has poor dynamic performance and poor reversibility, so that the multiplying power performance and the cycle performance of the pore structure are poor, and therefore, the means for constructing the multistage pore structure is not suitable for the hard carbon material for sodium ion storage.

Therefore, providing a hard carbon material for sodium ion batteries with good rate capability and fast dynamic process is one of the problems to be solved in the field.

Disclosure of Invention

In order to solve all or part of the technical problems, the invention provides the following technical scheme:

one of the objects of the present invention is to provide a hard carbon material in which the domain size of graphite crystallites isL _a Less than 50 and nm, and the oxygen element content delta is less than 10 percent;

wherein,L _a is obtained by carrying out Raman spectrum test on the hard carbon material,L _a =(2.4×10 ^-10 )(λ _nm ) ⁴ (I _G /I _D )，I _G is a Raman shift of 1500cm in Raman spectrum ^-1 ～1650cm ^-1 Peak intensity of G peak appearing in the range of (I) _D Is a Raman shift of 1300cm in Raman spectrum ^-1 ～1400cm ^-1 Peak intensity of D peak appearing in range lambda _nm A wavelength of light emitted by the raman light source;

delta is by converting the hard carbon material to CO ₂ And then measured by infrared spectroscopy.

The storage of sodium ions from the outside of the hard carbon material to the inside of the pore structure of the hard carbon material needs to undergo the transportation of crystal domains, and in the range of the crystal domain size La of the hard carbon material provided by the invention, the transportation of sodium ions can be accelerated, so that the carbon material has a rapid sodium ion transmission dynamic process; oxygen element plays a role in blocking sodium ion transmission, and the small-domain hard carbon material with the oxygen element content within the range further increases the sodium ion transmission efficiency.

In some embodiments, delta < 2%,L _a < 11.5 nm. When the small-domain hard carbon material with the domain size and the oxygen element characteristics is used as a negative electrode material of the sodium ion battery, the assembled sodium ion battery has higher reversible capacity, first coulomb efficiency and quick dynamic process.

In some embodiments, dQ/dV is greater than 0.53V in a discharge curve obtained by performing a constant current charge-discharge test on the hard carbon material. The hard carbon material provided by the invention has higher platform voltage passing constant-current charge and discharge tests.

The second object of the present invention is to provide a method for producing a hard carbon material, the method comprising:

sequentially carbonizing, crushing and purifying a carbon source to obtain a carbonized material precursor;

sequentially sintering the carbonized material precursor at low temperature Duan Shaojie and high temperature, and performing post-treatment to obtain a hard carbon material;

the low temperature Duan Shaojie adopts a first heating rate and a first sintering temperature, the high temperature section sintering adopts a second heating rate and a second sintering temperature, the first heating rate is higher than the second heating rate by more than 4.5 ℃/min, and the first sintering temperature is lower than the second sintering temperature by more than 200 ℃.

The preparation method can regulate and control the domain size and the oxygen content of the carbon material at the same time, and improve the dynamic performance of the hard carbon material, so that the sodium ion battery based on the hard carbon material has high capacity and high multiplying power. According to the invention, the growth of the hard carbon material in La and Lc directions is different in response to temperature, la has a relatively high growth speed in a low-temperature section, and Lc has a relatively high growth speed in a high-temperature section, so that La and Lc can be regulated and controlled by rapidly heating in the low-temperature section and slowly heating in the high-temperature section, and a small-crystal domain hard carbon material with relatively small La is obtained; meanwhile, the temperature regulation mode can obtain the hard carbon material with low oxygen content, so that the sodium ion transmission dynamics of the hard carbon material is further improved.

Further, the first sintering temperature is 800-1000 ℃, and the second sintering temperature is 1200-1400 ℃.

Further, the first heating rate is 5-20 ℃/min, and the second heating rate is 0.5-10 ℃/min. Further, the first temperature rising rate is preferably 8-15 ℃/min. The second heating rate is preferably 3-5 ℃/min.

Further, when the high-temperature section sintering is performed, the heat preservation time at the second sintering temperature is 0.5-24h. The holding time of the second sintering temperature is preferably 2-5h. That is, the preparation method is to raise the temperature to the first sintering temperature at the first temperature raising rate, change the temperature raising rate to the second temperature raising rate after reaching the first sintering temperature, raise the temperature to the second sintering temperature at the second temperature raising rate, and then keep the temperature.

The two-stage sintering treatment adopted in the invention, in particular to the sintering temperature, the heating speed and the heat preservation time adopted in the high-temperature stage sintering, has great influence on the control of the oxygen content, and the hard carbon material with low oxygen content can be obtained in the sintering temperature, the heating speed and the heat preservation time adopted in the high-temperature stage sintering.

Further, the low temperature Duan Shaojie and high temperature sintering are performed in an inert atmosphere. The inert atmosphere comprises any one or a combination of at least two of nitrogen, argon, neon, helium, xenon and krypton.

In some embodiments, the carbon source comprises one or more of a plant-based carbon source, a carbohydrate carbon source, a resin-based carbon source, and a polymer-based carbon source.

Further, the plant carbon source comprises one or more of coconut shell, almond shell, pistachio shell, macadamia shell, jujube core shell, chestnut shell, hazelnut shell, peanut shell, walnut shell, peach core shell, cotton, wood, bamboo, straw and lignin.

Further, the carbohydrate carbon source comprises one or more of glucose, sucrose, maltose, lactose, fructose, starch, cellulose.

Further, the resin-based carbon source includes one or more combinations of phenolic resin, epoxy resin, urea resin, melamine resin, polyimide resin, polyester resin, aldehyde resin, polyolefin resin, polyacrylic resin.

Further, the polymer-based carbon source comprises one or a combination of more of polyfurfuryl alcohol, polyaniline, polyethylene glycol, polyethylene oxide, polyvinylidene fluoride, natural rubber and polyacrylonitrile.

In some embodiments, the carbonization treatment comprises: heating the carbon source at 400-800 deg.c for 0.5-24 hr. Preferably, the carbon source is heated at a temperature of 500 ℃ to 600 ℃ for 1 to 5 hours.

In some embodiments, the carbonization treatment is performed in an inert atmosphere or an oxygen-deficient atmosphere.

Further, the inert atmosphere comprises one or more of nitrogen, argon, neon, helium, xenon, krypton.

Further, the oxygen-deficient atmosphere is a gas atmosphere with an oxygen content of less than or equal to 1 wt%.

In some embodiments, the comminution process comprises: the carbonized product was crushed to a median particle size of 1 μm to 15 μm and sieved using a 30 mesh sieve. If the particle size is small, an excessively large specific surface area results in low initial efficiency of the battery, and if the particle size is large, it also results in reduced battery performance.

Further, the crushing treatment comprises one or a combination of more of ball milling, air flow crushing, mechanical crushing and extrusion crushing. The pulverizing treatment is performed, for example, using one or a combination of at least two of a ball mill, a jet mill, a mechanical pulverizer, and a roll mill.

In some embodiments, the preparation method specifically includes: sequentially carbonizing, crushing, activating and purifying the carbon source to obtain a carbonized material precursor; wherein the activation treatment comprises solid phase pore-forming and/or gas phase pore-forming.

Further, the solid phase pore-forming comprises: and uniformly mixing the crushed product with the solid phase pore-forming agent under the inert atmosphere condition, and carrying out high-temperature treatment.

And further, after the solid phase pore forming is completed, washing the activation treatment product to pH of 4-8, and drying.

Further, the solid phase pore-forming agent comprises one or a combination of more of sodium hydroxide, potassium hydroxide, sodium oxide, potassium oxide, sodium carbonate, sodium bicarbonate, potassium carbonate and potassium bicarbonate.

Further, the mass ratio of the crushing treatment product to the solid phase pore-forming agent is 1:2-2:1.

Further, in the solid phase pore-forming, the temperature of the high-temperature treatment is 500-800 ℃, and the time of the high-temperature treatment is 10-120 min.

Further, the gas phase pore forming includes: and under the inert atmosphere condition, heating the crushed product to a third temperature, then preserving heat, introducing a gas-phase pore-forming agent in the heat preservation process, and stopping introducing the gas-phase pore-forming agent after the heat preservation is finished.

Further, the gas phase pore former comprises one or more of water vapor, carbon dioxide, oxygen and air.

Further, in the gas phase pore forming, the third temperature is 700 ℃ to 1000 ℃.

Further, in the gas phase pore forming, the heat preservation time is 0.5h-10h.

Further, the inert atmosphere adopted by the solid phase pore-forming and the gas phase pore-forming independently comprises one or a combination of more of nitrogen, argon, neon, helium, xenon and krypton.

In some embodiments, the purification process comprises: and uniformly mixing the crushed product with acid, stirring for 0.5-24h, and carrying out solid-liquid separation after stirring.

Further, the purification treatment specifically includes: mixing the crushed product, acid and water according to the mass ratio of 1:1:1-1:1:10, stirring, washing the purified product obtained by solid-liquid separation to pH of 4-8, and drying.

Further, the acid includes one or more of hydrochloric acid, hydrofluoric acid, nitric acid, phosphoric acid, and sulfuric acid.

Further, the concentration of the acid is 35-98 wt%.

In some embodiments, the post-processing includes: and carrying out VC mixing and screening on the sintered product to obtain the hard carbon material.

Further, the screening adopts a screen mesh number of 200-400 meshes. Preferably, the screen mesh number is 325 mesh.

It is a further object of the present invention to provide a hard carbon material obtained by the method according to any one of the above.

In some embodiments, the hard carbon material has a median particle size of 5 to 9 μm. The specific surface area of the hard carbon material is 3-30 m ² And/g. The hard carbon material has an oxygen element content of less than 10wt%, preferably less than 2wt%. The hard carbon material has a domain size La of less than 50 nm, preferably less than 11.5 nm.

The fourth object of the present invention is to provide an application of the hard carbon material in preparing a carbon negative electrode material for sodium ion batteries or sodium ion batteries.

The invention aims to provide a sodium ion battery which comprises a positive electrode, a negative electrode, electrolyte and a diaphragm, and is characterized in that: the negative electrode comprises the hard carbon material of any one of the above.

The sixth object of the present invention is to provide a method for controlling the domain size and oxygen content of a hard carbon material, comprising:

Further technical solutions of the "method for controlling domain size and oxygen content of hard carbon material" described in the sixth aspect of the present invention are described in detail in the second aspect of the present invention, and are not described herein.

Compared with the prior art, the invention has at least the following beneficial effects: the invention provides a hard carbon material with small crystal domain (La size) to shorten the transmission distance of sodium ions in the hard carbon material and further combine the characteristic of low oxygen content to improve the transmission dynamics of sodium ions; the invention provides a high-temperature sintering method combining fast and slow heating modes, which can regulate and control the domain size and oxygen content of a hard carbon material at the same time, so as to prepare the hard carbon material with low oxygen content and small domain; the sodium ion battery based on the hard carbon material has higher reversible capacity, high first coulombic efficiency and good dynamic performance.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present application, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a diagram showing the structure of graphite crystallites in a hard carbon material prepared in example 1 of the present invention;

FIG. 2 is an XRD pattern of the hard carbon material prepared in example 1 and comparative example 1 according to the present invention;

FIG. 3 is an SEM image of a hard carbon material prepared according to example 1 of the present invention;

FIG. 4 is a graph showing the first charge-discharge curves of the hard carbon materials prepared in example 1 and comparative example 1 according to the present invention;

FIG. 5 is a graph showing the sub-discharge curve dQ/dV of the hard carbon material prepared in example 1 and comparative example 1;

fig. 6 is a ratio reversible capacity comparison chart of batteries based on the corresponding hard carbon materials prepared in example 1 and comparative example 1 according to the present invention.

Detailed Description

The following detailed description of the present invention is provided in connection with specific embodiments so that those skilled in the art may better understand and practice the present invention. Specific functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention in virtually any appropriately detailed embodiment.

Example 1

Under the nitrogen atmosphere, the apricot shells are placed in a box-type furnace to be carbonized for 1h at 600 ℃, and after carbonization, carbonized products are cooled to room temperature; coarse crushing the carbonized product, and crushing the carbonized product by adopting air current until the median particle diameter is about 5.0 mu m to obtain a crushed product; then VC mixing the crushed product and sodium hydroxide according to the mass ratio of 1:1, heating to 700 ℃ in an activating furnace under nitrogen atmosphere, preserving heat for 30min to perform activating treatment, and cooling after the activating treatment is completed to obtain an activated product; mixing the activated product, concentrated hydrochloric acid (with the acid concentration of 37%) and pure water according to the mass ratio of 1:1:3, stirring for 3 hours, centrifuging to remove filtrate, washing the precipitate with pure water to PH=4-7, centrifuging and drying to obtain a carbonized material precursor;

placing the carbonized material precursor in a box furnace, firstly raising the temperature to 1000 ℃ at the heating rate of 15 ℃/min, then raising the temperature to 1400 ℃ at the heating rate of 3 ℃/min, and then preserving the heat for 2 hours to perform calcination treatment; and (5) cooling and VC mixing after the calcination is finished, and screening by adopting a 325-mesh screen to obtain the hard carbon material.

The median particle diameter, specific surface area, oxygen content and domain size characteristics of the hard carbon material obtained in this example are shown in table 1. Fig. 1 is a diagram showing the structure of crystallites of graphite in the hard carbon material prepared in this example. Fig. 2 shows the XRD pattern of the hard carbon material prepared in this example. Fig. 3 is an SEM image of the hard carbon material prepared in this example.

The sodium ion button half cell is prepared by adopting the hard carbon material, and the preparation of the button cell pole piece is prepared by adopting a method known in the art:

mixing the hard carbon material, the conductive agent (SP) and the binder (LA 133) according to the mass ratio of 91:3:6 to obtain a mixture, regulating the solid content of the mixture to 50% by using deionized water, uniformly mixing to obtain a uniform mixture, coating the uniform mixture on a copper foil current collector, and then carrying out vacuum drying and rolling to obtain the copper foil current collector with the surface density of 5.5+/-0.5 mg/cm ² Is a negative electrode plate;

and (3) manufacturing a button cell: naPF with sodium sheet as counter electrode, 1mol/L ₆ DIGLYME (100 Vol%) as electrolyte, glass fiber as separator, and 2032 button cell casing was used for assembly to obtain button half cell.

The battery performance of the button half cell was tested and the test results are shown in table 2.

Example 2

Under argon atmosphere, placing cellulose into a box furnace, carbonizing at 500 ℃ for 24 hours, and cooling carbonized products to room temperature after carbonization; mechanically crushing the carbonized product to a median particle diameter of about 7.0 mu m to obtain a crushed product; then VC mixing the crushed product and potassium hydroxide according to the mass ratio of 1:2, heating to 800 ℃ in an activating furnace under nitrogen atmosphere, preserving heat for 1h to perform activating treatment, and cooling after the activating treatment is completed to obtain an activated product; mixing an activated product, concentrated nitric acid (with the acid concentration of 69%) and pure water according to the mass ratio of 1:1:3, stirring for 3 hours, centrifuging to remove filtrate, washing precipitate with pure water to PH=4-7, centrifuging and drying to obtain a carbonized material precursor;

placing the carbonized material precursor in a box furnace, firstly raising the temperature to 800 ℃ at the heating rate of 5 ℃/min, then raising the temperature to 1300 ℃ at the heating rate of 0.5 ℃/min, and then preserving the heat for 5 hours to perform calcination treatment; and (5) cooling and VC mixing after the calcination is finished, and screening by adopting a 325-mesh screen to obtain the hard carbon material. The median particle diameter, specific surface area, oxygen content and domain size characteristics of the hard carbon material obtained in this example are shown in table 1.

The hard carbon material in example 1 was replaced with the hard carbon material in this example, and a sodium ion button half cell was assembled in the same manner as in example 1, and the cell performance was as shown in table 2.

Example 3

Under argon atmosphere, placing polyimide resin into a box-type furnace, carbonizing for 5 hours at 800 ℃, and cooling carbonized products to room temperature after carbonization; then carrying out jet milling on the carbonized product until the median particle diameter is about 6.0 mu m to obtain a milled product; cooling the crushed product, transferring the crushed product into an activation furnace, heating to 900 ℃, introducing steam under nitrogen atmosphere, preserving heat for 2 hours, stopping introducing steam and cooling to obtain a carbonized material precursor;

placing the carbonized material precursor in a box furnace, firstly raising the temperature to 900 ℃ at the heating rate of 20 ℃/min, then raising the temperature to 1200 ℃ at the heating rate of 10 ℃/min, and then preserving the heat for 1h to perform calcination treatment; and (5) cooling and VC mixing after the calcination is finished, and screening by adopting a 325-mesh screen to obtain the hard carbon material. The median particle diameter, specific surface area, oxygen content and domain size characteristics of the hard carbon material obtained in this example are shown in table 1.

Example 4

Under vacuum condition, placing polyvinylidene fluoride into a box furnace, carbonizing at 700 ℃ for 8 hours, and cooling carbonized products to room temperature after carbonization; coarse crushing the carbonized product, and crushing the carbonized product by adopting air current until the median particle diameter is about 5.0 mu m to obtain a crushed product; then, carrying out VC mixing on the crushed product and sodium oxide according to the mass ratio of 2:1, heating to 750 ℃ in an activating furnace under the nitrogen atmosphere, preserving heat for 2 hours to carry out activating treatment, cooling after the activating treatment is finished, washing with pure water until PH=4-8, centrifuging and drying to obtain a carbonized material precursor;

placing the carbonized material precursor in a box furnace, firstly raising the temperature to 1000 ℃ at the heating rate of 10 ℃/min, then raising the temperature to 1250 ℃ at the heating rate of 5 ℃/min, and then preserving the heat for 5 hours to perform calcination treatment; and (5) cooling and VC mixing after the calcination is finished, and screening by adopting a 325-mesh screen to obtain the hard carbon material. The median particle diameter, specific surface area, oxygen content and domain size characteristics of the hard carbon material obtained in this example are shown in table 1.

Example 5

Under the nitrogen atmosphere, placing sucrose into a box furnace, carbonizing for 3 hours at 550 ℃, and cooling carbonized products to room temperature after carbonization; coarse crushing the carbonized product, and crushing the carbonized product by adopting air current until the median particle diameter is about 8.0 mu m to obtain a crushed product; then VC mixing the crushed product and potassium carbonate according to the mass ratio of 2:1, heating to 750 ℃ in an activating furnace under nitrogen atmosphere, preserving heat for 1h to perform activating treatment, cooling after the activating treatment is finished, washing with pure water to PH=4-8, centrifuging and drying to obtain a carbonized material precursor;

placing the carbonized material precursor in a box furnace, firstly raising the temperature to 900 ℃ at the heating rate of 15 ℃/min, then raising the temperature to 1300 ℃ at the heating rate of 2 ℃/min, and then preserving the heat for 1h to perform calcination treatment; and (5) cooling and VC mixing after the calcination is finished, and screening by adopting a 325-mesh screen to obtain the hard carbon material. The median particle diameter, specific surface area, oxygen content and domain size characteristics of the hard carbon material obtained in this example are shown in table 1.

Comparative example 1

Comparative example 1 was different from example 1 only in that the carbonized material precursor was placed in a box furnace, heated to 1400 c at a heating rate of 0.5 c/min, and then heat-preserved for 2 hours to perform calcination treatment, and otherwise the same procedure as example 1 was performed to obtain a hard carbon material, and a sodium ion button half cell was assembled using the hard carbon material in the same manner as example 1.

Fig. 2 shows the XRD pattern of the hard carbon material prepared in this comparative example 1. Fig. 4 is a graph showing the first charge-discharge curves of the hard carbon materials prepared in example 1 and comparative example 1. FIG. 5 is a graph showing the sub-discharge curve dQ/dV of the hard carbon material prepared in example 1 and comparative example 1. Fig. 6 is a ratio reversible capacity comparison chart of the batteries based on the corresponding hard carbon materials prepared in example 1 and comparative example 1. As can be seen by comparison, the hard carbon material prepared by the embodiment of the invention shows better electrochemical comprehensive performance.

Comparative example 2

Comparative example 2 differs from example 2 only in that comparative example 2 was not subjected to the activation treatment step, resulting in a carbonized material precursor; the carbonized material precursor was placed in a box furnace, heated to 1100 ℃ at a heating rate of 1 ℃/min, and the rest was carried out in the same manner as in example 2 to obtain a hard carbon material, and a sodium ion button half cell was assembled by using the hard carbon material in the same manner as in example 1.

Comparative example 3

Comparative example 3 differs from example 3 only in that the carbonized product was jet-pulverized to a median particle diameter of about 15.0 μm; the carbonized material precursor was placed in a box furnace, heated to 1600 ℃ at a heating rate of 20 ℃/min, then heat-preserved for 1 hour to perform calcination treatment, and the rest was performed in the same manner as in example 3 to obtain a hard carbon material, and a sodium ion button half cell was assembled using the hard carbon material in the same manner as in example 1.

Comparative example 4

Comparative example 4 differs from example 4 only in that comparative example 4 was not subjected to an activation step, resulting in a carbonized material precursor; the carbonized material precursor was placed in a box furnace, heated to 1250 ℃ at a heating rate of 2 ℃/min, then heat-preserved for 5 hours to perform calcination treatment, and the rest was performed in the same manner as in example 4 to obtain a hard carbon material, and a sodium ion button half cell was assembled using the hard carbon material in the same manner as in example 1.

Comparative example 5

Comparative example 5 differs from example 5 only in that comparative example 5 was not subjected to an activation step to obtain a carbonized material precursor; the carbonized material precursor was placed in a box furnace, heated to 900 ℃ at a heating rate of 5 ℃/min, then heat-preserved for 1 hour to perform calcination treatment, and the rest was performed in the same manner as in example 5 to obtain a hard carbon material, and a sodium ion button half cell was assembled using the hard carbon material in the same manner as in example 1.

Comparative example 6

Comparative example 6 was different from example 1 only in that a carbonized material precursor was placed in a box furnace, heated to 1400 c at a heating rate of 15 c/min, then heat-preserved for 2 hours to perform calcination treatment, and the rest was performed in the same manner as example 1 to obtain a hard carbon material, and a sodium ion button half cell was assembled using the hard carbon material in the same manner as example 1.

Comparative example 7

Comparative example 7 was different from example 1 only in that a carbonized material precursor was placed in a box furnace, heated to 1400 c at a heating rate of 3 c/min, then heat-preserved for 2 hours to perform calcination treatment, and the rest was performed in the same manner as example 1 to obtain a hard carbon material, and a sodium ion button half cell was assembled using the hard carbon material in the same manner as example 1.

Comparative example 8

Comparative example 8 was different from example 1 only in that a carbonized material precursor was placed in a box furnace, heated to 1000 c at a heating rate of 3 c/min, heated to 1400 c at a heating rate of 15 c/min, and then heat-preserved for 2 hours to perform a calcination treatment, and the rest was conducted in the same manner as in example 1 to obtain a hard carbon material, and a sodium ion button half cell was assembled in the same manner as in example 1 using the hard carbon material.

Comparative example 9

Comparative example 9 was different from example 1 only in that the activation treatment was not performed, and the rest was performed in the same manner as in example 1 to obtain a hard carbon material, and a sodium ion button half cell was assembled using the hard carbon material in the same manner as in example 1.

Comparative example 10

Comparative example 10 was different from example 1 only in that a carbonized material precursor was placed in a box furnace, heated to 900 c at a heating rate of 15 c/min, then heat-preserved for 2 hours to perform calcination treatment, and the rest was performed in the same manner as example 1 to obtain a hard carbon material, and a sodium ion button half cell was assembled using the hard carbon material in the same manner as example 1.

Comparative example 11

Comparative example 11 was different from example 1 only in that a carbonized material precursor was placed in a box furnace, heated to 2500 c at a heating rate of 10 c/min, then heat-preserved for 2 hours to perform calcination treatment, and the rest was performed in the same manner as example 1 to obtain a hard carbon material, and a sodium ion button half cell was assembled using the hard carbon material in the same manner as example 1.

The hard carbon materials and the sodium ion button half cells obtained in the above examples and comparative examples were subjected to the related performance tests under the following conditions, and the test results are shown in table 1 and table 2, respectively:

(1) And testing the oxygen content of the carbon material. The content of oxygen element is tested by adopting an inert gas melting infrared method, a sample is heated and melted under the protection of helium, oxygen is reduced by carbon at high temperature to generate a large amount of CO, and the CO is oxidized into CO by using a glowing CuO reagent ₂ And (5) entering an infrared absorption cell for detection. Each sample was tested in 5 groups and averaged to obtain the oxygen content of the sample, and the measured value was mass percent.

(2) XRD data are obtained by testing with a Panalytical X' Pert PRO MPD tester, using K alpha rays (wavelength lambda= 0.1541 nm) of a Cu target as a light source, and in the range of 2 Theta 10 DEG to 90 deg.

(3) Raman testing of carbon materials. In order to analyze the internal structural information of the carbon cathode, a high-energy argon ion beam is adopted to cut the carbon cathode material, so that a section sample can be obtained. The Raman spectrum is tested by a Raman tester under the conditions of He-Ne laser (wavelength 532 nm), filter 10%, hole 500 μm, slit 100 μm, grating 1800 gr/mm, exposure time 60 s, cumulative times 2 times, microscope objective 50X Lwd, test range 800 cm ⁻¹ ~ 2000 cm ⁻¹ . The D peak is 1350 and 1350 cm ⁻¹ Nearby, the G peak is 1600 cm ⁻¹ Nearby. Randomly selecting 5 points on the surface of the carbon material to test Raman I _G /I _D Peak intensity ratio (i.e. the ratio of G peak intensity to D peak intensity), I is taken _G /I _D Average value according to the formulaL _a =(2.4×10 ^-10 )(λ _nm ) ⁴ (I _G /I _D ) The domain size can be calculatedL _a 。

(4) Nitrogen adsorption test was performed at 77K using a microphone specific surface area tester (model ASAP 2460) to obtain specific surface area and pore volume, wherein the specific surface area was calculated by BET formula (unit is m ² The pore volume Vpore is the total pore volume of single point adsorption (in cm. Mu.m/g).

(5) Specific capacity and first time efficiency test conditions: testing on a Land battery testing system at room temperature, firstly discharging the constant current of 0.1C to 1mV, and stopping discharging; after standing, the mixture was charged at 0.1C, the cut-off voltage was 2V, and the test results are shown in Table 2. The specific capacity (mAh/g) is the first discharge capacity divided by the weight of the carbon negative electrode material (namely the hard carbon material) contained in the negative electrode plate, the nominal specific capacity is 300mAh/g, and the first efficiency is the ratio of the first charge capacity to the first discharge capacity.

(6) And (3) multiplying power performance test: and (3) performing constant-current charge and discharge tests on the battery subjected to the first week test at 0.1C/0.1C, 0.5C/0.5C, 1C/1C and 2C/2C at normal temperature, and dividing the 2C charge capacity by the 0.1C gram capacity to obtain the rate discharge retention rate.

Table 1 hard carbon material related characteristics in examples, comparative examples

Table 2 battery-related properties in examples, comparative examples

Referring to tables 1 and 2, the reversible specific capacity of the batteries in examples 1-5 is 298.3-335.2mAh/g, the initial coulomb efficiency is 85.2% -94.0%, the 2C capacity retention rate is 71.5% -75.7%, the electrochemical performance is better, and it can be found that the direct linear relation between the voltage level and the rate performance is better, and the higher the voltage level is, the better the rate performance is. This is because oxygen plays an obstacle role in sodium ion transport, so that the lower the oxygen content, the faster the sodium ion transport, while the smaller the domain size La represents the transport distance of sodium ions, the shorter the transport distance, which means the faster the whole transport process. Therefore, the sodium ion battery prepared from the hard carbon material provided by the invention has the characteristics of high reversible capacity, high first coulomb efficiency, good dynamic performance and the like.

Furthermore, as can be seen from the combination of tables 1 and 2, the correlation between the first coulombic efficiency of the battery and the content of oxygen element in the hard carbon material is large, because most oxygen element defects have strong binding energy with sodium ions, i.e. after capturing sodium ions, sodium ions are difficult to remove again, so that the coulombic efficiency is low. In addition, because sodium ions are transported in the hard carbon material from interlayer to closed cell structure, the hard carbon material with low oxygen content and small domain size (La) has better rate capability and rapid dynamic process.

The various aspects, embodiments, features and examples of the invention are to be considered in all respects as illustrative and not intended to limit the invention, the scope of which is defined solely by the claims. Other embodiments, modifications, and uses will be apparent to those skilled in the art without departing from the spirit and scope of the claimed invention.

In addition, the inventors have conducted experiments with other materials, process operations, and process conditions as described in this specification with reference to the foregoing examples, and have all obtained desirable results.

While the invention has been described with reference to an illustrative embodiment, it will be understood by those skilled in the art that various other changes, omissions and/or additions may be made and substantial equivalents may be substituted for elements thereof without departing from the spirit and scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims. Moreover, unless specifically stated any use of the terms first, second, etc. do not denote any order or importance, but rather the terms first, second, etc. are used to distinguish one element from another.

Claims

1. The preparation method of the hard carbon negative electrode material of the sodium ion battery is characterized by comprising the following steps of:

sequentially carrying out carbonization treatment, crushing treatment, activation treatment and purification treatment on a carbon source to obtain a carbonized material precursor, wherein the carbonization treatment is carried out in an inert atmosphere or an oxygen-deficient atmosphere, the carbonization treatment comprises heating the carbon source for 0.5-24h at the temperature of 400-800 ℃, the crushing treatment comprises crushing a product of the carbonization treatment to a median particle size of 1-15 mu m, sieving the crushed product by adopting a sieve with a size below 30 meshes, the activation treatment comprises solid phase pore-forming and/or gas phase pore-forming, the solid phase pore-forming comprises uniformly mixing the crushed product with a solid phase pore-forming agent under the inert atmosphere condition, carrying out high-temperature treatment at the temperature of 500-800 ℃, the high-temperature treatment time is 10-120 min, the gas phase pore-forming comprises heating the crushed product to 700-1000 ℃ under the inert atmosphere condition, then carrying out heat preservation, introducing the gas phase pore-forming agent in the heat preservation process, and stopping introducing the gas phase pore-forming agent in the heat preservation process; the purification treatment comprises the steps of uniformly mixing the activated product with acid, stirring for 0.5-24h, and carrying out solid-liquid separation after stirring to obtain the carbonized material precursor;

sequentially sintering the carbonized material precursor at low temperature Duan Shaojie and high temperature, and performing aftertreatment to obtain a hard carbon anode material of the sodium ion battery;

the low temperature Duan Shaojie adopts a first heating rate and a first sintering temperature, the high temperature section sintering adopts a second heating rate and a second sintering temperature, the first heating rate is higher than the second heating rate by more than 4.5 ℃/min, the first heating rate is 5-20 ℃/min, and the second heating rate is 0.5-10 ℃/min; the first sintering temperature is 200 ℃ or more lower than the second sintering temperature, the first sintering temperature is 800-1000 ℃, and the second sintering temperature is 1200-1400 ℃; and when the high-temperature section sintering is carried out, the heat preservation time at the second sintering temperature is 0.5-24h.

2. The method of manufacturing according to claim 1, characterized in that: the first heating speed is 8-15 ℃/min, the second heating speed is 2-5 ℃/min, the low-temperature Duan Shaojie and high-temperature section sintering is performed in inert atmosphere, and the heat preservation time of the second sintering temperature is 2-5h.

3. The method of manufacturing according to claim 1, characterized in that: the carbon source comprises one or a combination of a plurality of plant carbon sources, sugar carbon sources, resin carbon sources and polymer carbon sources.

4. A method of preparation according to claim 3, characterized in that: the plant carbon source comprises one or more of coconut shell, almond shell, pistachio shell, hawaii shell, jujube core shell, chestnut shell, hazelnut shell, peanut shell, walnut shell, peach core shell, cotton, wood, bamboo, straw and lignin;

the carbohydrate carbon source comprises one or more of glucose, sucrose, maltose, lactose, fructose, starch and cellulose;

the resin carbon source comprises one or more of phenolic resin, epoxy resin, urea resin, melamine resin, polyimide resin, polyester resin, aldehyde resin, polyolefin resin and polyacrylic resin;

the polymer carbon source comprises one or a combination of more of polyfurfuryl alcohol, polyaniline, polyethylene glycol, polyethylene oxide, polyvinylidene fluoride, natural rubber and polyacrylonitrile.

5. The method of manufacturing according to claim 1, characterized in that: the carbonization treatment includes: heating the carbon source at 500-600 deg.c for 1-5 hr.

6. The method of manufacturing according to claim 1, characterized in that: the inert atmosphere in the carbonization treatment comprises one or a combination of more of nitrogen, argon, neon, helium, xenon and krypton; the oxygen-deficient atmosphere is a gas atmosphere with the oxygen content less than or equal to 1 weight percent.

7. The method of claim 1, wherein the comminution process comprises one or a combination of ball milling, jet milling, mechanical milling, extrusion milling.

8. The method of manufacturing according to claim 1, characterized in that: and after the solid phase pore forming is completed, washing the activation treatment product to pH of 4-8, and drying.

9. The method of manufacturing according to claim 1, characterized in that: the solid phase pore-forming agent comprises one or a combination of more of sodium hydroxide, potassium hydroxide, sodium oxide, potassium oxide, sodium carbonate, sodium bicarbonate, potassium carbonate and potassium bicarbonate; the mass ratio of the crushing treatment product to the solid phase pore-forming agent is 1:2-2:1.

10. The method of manufacturing according to claim 1, characterized in that: the gas phase pore-forming agent comprises one or a combination of more of water vapor, carbon dioxide, oxygen and air; in the gas phase pore forming, the heat preservation time at 700-1000 ℃ is 0.5-10 h.

11. The method of manufacturing according to claim 1, characterized in that: the inert atmosphere in the solid phase pore-forming and the gas phase pore-forming comprises one or a combination of more of nitrogen, argon, neon, helium, xenon and krypton.

12. The method of manufacturing according to claim 1, characterized in that: the purification treatment specifically comprises: mixing the crushed product, acid and water according to the mass ratio of 1:1:1-1:1:10, stirring, washing the purified product obtained by solid-liquid separation to pH of 4-8, and drying.

13. The method of manufacturing according to claim 12, wherein: the acid comprises one or more of hydrochloric acid, hydrofluoric acid, nitric acid, phosphoric acid, and sulfuric acid; the concentration of the acid is 35-98 wt%.

14. The method of claim 1, wherein the post-treatment comprises: and carrying out VC mixing and screening on the product sintered by the high-temperature section to obtain the hard carbon negative electrode material of the sodium ion battery.

15. The method of manufacturing according to claim 14, wherein: the number of the screen meshes adopted by the screening is 200-400 meshes.

16. The hard carbon negative electrode material of sodium ion battery obtained by the preparation method according to any one of claims 1 to 15, wherein the hard carbon negative electrode material of sodium ion battery is characterized in that the domain size of graphite crystallites in the hard carbon negative electrode material of sodium ion battery is as followsL _a Less than 11.5 and nm, and the oxygen element content delta is less than 2 percent;

wherein,L _a is obtained by carrying out Raman spectrum test on the hard carbon anode material of the sodium ion battery,L _a =(2.4×10 ^-10 )(λ _nm ) ⁴ (I _G /I _D )，I _G is a Raman shift of 1500cm in Raman spectrum ^-1 ～1650cm ^-1 Peak intensity of G peak appearing in the range of (I) _D Is a Raman shift of 1300cm in Raman spectrum ^-1 ～1400cm ^-1 Peak intensity of D peak appearing in range lambda _nm A wavelength of light emitted by the raman light source;

delta is obtained by converting the hard carbon anode material of the sodium ion battery into CO ₂ And then measured by infrared spectroscopy.

17. The sodium ion battery hard carbon negative electrode material of claim 16, wherein: and performing constant-current charge and discharge test on the hard carbon negative electrode material of the sodium ion battery, wherein the test condition is 0.1C/0.1C constant-current charge and discharge, the test voltage range is 0.001-V-2V, and dQ/dV is more than 0.53V in a discharge curve obtained by the constant-current charge and discharge test.

18. Use of the hard carbon negative electrode material of sodium ion battery according to claim 16 or 17 for preparing sodium ion battery.

19. A sodium ion battery, includes positive pole, negative pole, electrolyte and diaphragm, its characterized in that: the negative electrode comprising the sodium ion battery hard carbon negative electrode material of claim 16 or 17.

20. A method for regulating and controlling the size and oxygen content of a crystal domain of a hard carbon anode material of a sodium ion battery is characterized by comprising the following steps: