CA3214830A1 - Composition of matter for the production of graphite powder - Google Patents
Composition of matter for the production of graphite powder Download PDFInfo
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- CA3214830A1 CA3214830A1 CA3214830A CA3214830A CA3214830A1 CA 3214830 A1 CA3214830 A1 CA 3214830A1 CA 3214830 A CA3214830 A CA 3214830A CA 3214830 A CA3214830 A CA 3214830A CA 3214830 A1 CA3214830 A1 CA 3214830A1
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Abstract
Description
POWDER
FIELD OF THE INVENTION
The present invention relates to a composition of matter suitable for the production of a graphite powder, suitable for making high performance lithium-ion battery anodes and other applications. The composition of matter comprises a biochar, a metal and graphite.
BACKGROUND OF THE INVENTION
[0001] Lithium-ion batteries have become ubiquitous in society, being used in anything from portable electronic equipment to power tools to electrical vehicles. The rise in utilisation of lithium-ion batteries has driven the development to explore new and improved materials of construction to increase performance. In addition, certain lithium-ion battery components are limited in supply and will only increase in scarcity as demand grows with the global transition to an electrical infrastructure rather than a fossil fuel based one. For this reason, there is a concerted effort to find alternative raw material sources, most suitably from renewable resources to ensure sustainability. One of the components in the lithium-ion battery that is in short supply is graphite.
Innumerable possibilities exist for arriving at a mixture of graphite, catalyst and residual char.
However, only a small subset of such mixtures result in a composition of matter suitable for further processing into graphite and eventual use in lithium-ion batteries.
SUMMARY OF THE INVENTION
In one embodiment the transition metal is selected from chromium, zirconium, molybdenum, ruthenium, rhodium, palladium, silver, cadmium, zinc, copper, nickel, cobalt, iron, manganese, chromium, vanadium or any combination thereof.
the method including the steps of:
i) thermally treating biomass in particulate form at a temperature of between 200 and 1000 degrees Celsius to form a particulate biochar;
ii) combining the resulting biochar with a particulate metal compound in a wet or a dry form to create a precursor mixture;
iii) heating the precursor mixture to between about 400 to about 3000 degrees Celsius under inert conditions to form a graphite containing mixture;
iv) sieving the final mixture to below about 1 mm particulate size to produce a mixture having (a) a graphite content of between about 25 to 65 percent by weight, (b) a metal content of between about 15 to 75 percent by weight and (c) a biochar content of between 1 and 35 percent by weight.
BRIEF DESCRIPTION OF THE DRAWINGS
DETAILED DESCRIPTION OF THE INVENTION
Definitions
Furthermore, unless otherwise clear from the context, a numerical value presented herein has an implied precision given by the first significant digit. Thus, a value 1.105 implies a value from 1.0 to 1.2, whereas 110.5 given by 1.105x102, implies a value from 100 to 120.
Composite of biochar, metal and graphite
pyrolysis) up to several hours. Alternatively, the biomass can be converted into char using a hydrothermal approach. Here the char and water can be placed in an autoclave at around 360 degrees Celsius and a pressure of approximately 200 bar for the same time periods as pyrolysis, followed by drying. In all cases the resulting char is comprised mainly of the element carbon, with a so-called fixed carbon content above at least 40%
but more usually above 60%. The remainder is comprised of a set of heteroatoms, mainly hydrogen, oxygen, nitrogen and sulphur. In addition, the char may contain volatile matter, defined as hydrocarbons, aliphatic or aromatic, which are of high enough molecular weight to not have been vaporised during the heat treatment. The exact composition will depend on the pyrolysis conditions and the selected biomass starting material. This material is conventionally referred to as a "green" char.
Following subjection of the precursor mixture (biochar and metallic compound) to the stated heat treatment procedure, the char is altered in two ways. Firstly, practically all of the residual heteroatoms and volatile matter have been removed, resulting in a material that is virtually exclusively carbon and has a fixed carbon content in excess of -99%.
This material is conventionally referred to as a "calcined" or "fully carbonized"
char.
Secondly, the mass of carbon has been reduced. The carbon acts as a reductant for the organic or inorganic metallic compound that makes up a part of the precursor mixture.
However, the metal component may also be comprised of non-transition metals such as:
sodium, magnesium, potassium, calcium, tin, lead and others. Upon heat treatment, most organic and some inorganic compounds will undergo decomposition(s) to form a metal oxide. However, this is not a requirement, instead the only critical prerequisite is that the original compound or formed intermediate compound(s) can be reduced to its metallic state during the heat treatment process. The reduction is typically achieved under an inert atmosphere, in the presence of the aforementioned carbon (char) component.
This process results in a reduction in solid mass as well as particle size, due to the loss of non-metallic elements as gas and an increase in density of the metal relative to the compound (in most cases).
In the former a carbon source is dissolved in the metal and graphite is spontaneously precipitated due to differences in their free energy or level of structural ordering. In the latter an unstable metal carbide is formed, which spontaneously decomposes to yield graphite. The exact formation mechanism is not relevant to the current composition of matter.
Given the fact that the biochar component is fully carbonized to contain in excess of -99% carbon and graphite is also an allotrope of pure carbon, the composite is a binary mixture with an elemental composition of between 25 to 75 percent carbon and the difference being made up of a selected pure metal (when an alloy is not used).
For graphitic materials this percentage is also known as the "total graphitic carbon" or -TGC".
defined the interlayer spacing of non-graphitic (i.e. amorphous) carbons as 0.3440 nm and graphite having an interlayer spacing of 0.3354 nm. Practical graphitic materials fall somewhere in between. Depending on the chosen conditions and selected metallic precursor the achieved d-spacing will vary. For the novel composition of matter under consideration, the required d- spacing may be specified as 0.3354 nm to 0.3401 nm.
The following description of a method to produce the aforementioned mixture is presented for purposes of illustration and description. It is not exhaustive and does not limit the method to the precise form disclosed. Modifications and variations are possible in light of this disclosure or may be acquired from the practicing of these methods.
The selected biochar and chosen metallic compound may be milled, if required, to ensure an even distribution. The two precursors (biochar and metal component) are then mixed in a ratio of between about 0.1 up to about 10 wt/wt. This can be done under wet or dry conditions. The mixture is heated to a temperature of between 400 and 3000 degrees Celsius in a furnace, oven, kiln, reactor vessel or similar.
The heating may be achieved by resistively heated electrical elements, microwaves or the inductive coupling of high frequency electromagnetic fields. The selected heating method however must ensure homogenous heating of the entire material mass to ensure sufficient conversion and a consistent product quality throughout. Thus, surface heating techniques such as lasers or electromagnetic waves with limited sample penetration are excluded. Such techniques will not achieve the high total graphitic carbon for the carbon component (TGC >55 %wt), stipulated herein as a requirement for this composition of matter. The mixture is soaked for periods of between 1 minute and 20 hours under inert atmosphere. Following this time, the mixture is cooled, removed from the furnace and sieved to a particle size below 1 millimetre to produce the said mixture with the desired properties.
The aforementioned properties of the mixture are desirable for achieving the final set of physical properties and performance characteristics to allow the resulting graphite to be used as a high-performance anode in lithium-ion batteries. The composite can be further processed to enable the measurement of some of these properties. One such step is the removal of the metal component. The relative amount and size of the metal allows for its rapid removal using acid leaching. The small particles (<1 mm) enable efficient exposure to the acid, while the chosen mass loading of between 25 to 75 % wt ensures that leaching times do not become excessive. Very high purities exceeding 99.5 wt carbon can be achieved within hours. If the metal content is reduced, fast leaching is also possible but conversion into graphite will be inadequate, thereby compromising other battery anode properties.
The high purity, high density graphite derived from this novel mixture composition of matter composite has achieved "Coulombic efficiencies" of greater than 60% and as high as 99%, thereby satisfying the requirements for lithium-ion batteries.
EXAMPLES
The applicator arrangement is shown in Figure 1. A microwave generator delivers power to the applicator via a WR340 waveguide auto-tuner, a PTFE window and a passive coupling element. The microwave generator is a 2.45GHz YJ1600-based source (Sairem). A sample is placed within a crucible and positioned within the applicator, usually on a "pillar" or stand, at a predeteimined height to obtain a specific radiation distributions (see Figure 2 a). The unit is sealed and purged using nitrogen gas (99.9%
pure) at a high flowrate for approximately 1 hour to establish an inert atmosphere and then a lower purge flowrate is used to maintain it. After this the power is gradually applied at a rate of 30 W/min to allow the sample to heat up slowly and rapidly achieve steady state at the desired final power. The steady power setting is chosen to achieve a desired temperature. The final power level is then held for a specific time, depending on the desired outcome. At this point the sample is glowing red and the crucible surface temperature can be measured using a handheld pyrometer through the sight glass, as shown in Figure 2 b. Pyrometer readings demonstrated a high level of fluctuation and uncertainty, thus a temperature band is reported in the applicable Examples below. Power is then maintained steady for a given time frame, after which the generator is turned off and the resulting mixture sample allowed to cool for removal.
Example 1
Inert conditions were established using nitrogen gas as described above and power was gradually increased at a rate of approximately 30 W/min up to 1.9 kW.
Temperature was measured to be between 1700-1900 degrees Celsius. The power was maintained steady for around 5 to 10 minutes after which the power was cut to the microwave applicator to produce a resulting mixture. Once cooled the sample was sieved to below 1 mm to remove some large metal particles in the mixture, at this point the mixture composition can be calculated as shown in Table 1. It was then leached with 500 ml of concentrated hydrochloric acid overnight, followed by washing with deionised water and filtering with a Buchner funnel to produce graphite. The resulting graphite was analysed using XRD
(Braker D8 Advance diffractometer using a mirror-derived lmm high parallel beam of cobalt K alpha radiation, weighted mean wavelength 1.709026 Angstroms) and SEM
(using an ultra-high-resolution field-emission microscope: Zeiss Ultra Plus 55 FEGSEM, equipped with an in-lens detection system operating at an acceleration voltage of 1 to 10 kV. A working distance of between 1 and 5 mm was used and the powders were lightly deposited on carbon tape without any additional sample preparation). The XRD
spectra is shown in Figure 4 and indicates a d-spacing of 0.3355 nm, in addition since no other peaks except those for graphite it can be concluded that the sample has a graphite (carbon) purity in excess of 90% wt. Furthermore, since the XRD spectra lacks the broad, low intensity peak of amorphous carbon at low angles, it can be concluded that less than 20%
of the carbon is not graphitic. A sample of the resulting graphite was characterised and found to have a specific surface area of 26.8 m2/g. The structure of the formed graphite is shown in Figure 3, indicating a large, flake-like, anisotropic material with highly ordered graphite crystals. This experiment produced some large metal particles in the mixture, examples of which are shown in Figure 5.
Table 1¨ Example 1 - Mixture Composition Carbon Metal Yield content (%) (est.) of Mn Mass post Carbon Acetate Metal Carbon Metal Component (g) reduction (g) (%) (g) (%) (%) Dry char 17.5 55% 9.625 82%
Mn Acetate 9.4 22% 2.1 18%
Based on the XRD result it can be assumed that 80% of the carbon is graphitic, thus the composition of the mixture can be stated as:
(a) a graphite content of about 66 percent by weight, (b) a metal content of about 18 percent by weight, and (c) a biochar content of about 16 percent by weight.
Example 2
Sawdust (50 g) from pine trees (pinus radiata) was hydrothermally treated with deionised water at a temperature of 360 degrees Celsius for 20 min in an autoclave. The sample was allowed to cool and then filtered using a Buchner funnel; the resulting char was dried in a conventional oven. The dry char (10.1 g) with carbon content around 80%, was combined with 8.2 g of Manganese Acetate (tetrahydrate). The resulting mixture was placed in a crucible and transferred to the microwave applicator.
Inert conditions were established and power was gradually increased at a rate of approximately 30 W/min up to 1.3 kW. Temperature was measured to be between 1600 degrees Celsius. The power was maintained steady for around 5 to 10 minutes after which the power was cut. Once cooled the sample was sieved to below 1 mm, at this point the mixture composition can be calculated as shown in Table 2. It was then leached with 500 ml of hydrochloric acid overnight, followed by washing with deionised water and filtering with a Buchner funnel. The resulting graphite was analysed using XRD
(Bruker D8 Advance diffractometer using a mirror-derived lmm high parallel beam of cobalt K alpha radiation, weighted mean wavelength 1.709026 Angstroms) and SEM
(using an ultra-high-resolution field-emission microscope: Zeiss Ultra Plus 55 FEGSEM, equipped with an in-lens detection system operating at an acceleration voltage of 1 to 10 kV. A working distance of between 1 and 5 mm was used and the powders were lightly deposited on carbon tape without any additional sample preparation). The XRD
spectra is shown in Figure 7 and indicates a d-spacing of 0.3392 nm, in addition since no other peaks except those for graphite it can be concluded that the sample has a graphite (carbon) purity in excess of 90% wt. Furthermore, since the XRD spectra lacks the broad, low intensity peak of amorphous carbon at low angles, it can be concluded that less than 20%
of the carbon is not graphitic. A sample of the graphite was characterised and found to have a surface area of 74.0 m2/g. The structure of the formed graphite is shown in Figure 6, indicating a material with smaller, random crystallites and a more isotropic structure.
Table 2¨ Example 2 - Mixture Composition Metal Carbon content Yield of Mn Mass (%) est. post Carbon Acetate Metal Carbon Metal Component (g) reduction (g) (%) (g) (%) (%) Dry char 10.1 55% 5.555 75%
Mn Acetate 8.2 22% 1.8 25%
Based on the XRD result it can be assumed that 80% of the carbon is graphitic, thus the composition of the mixture can be stated as (a) a graphite content of about 60 percent by weight, (b) a metal content of about 25 percent by weight and (c) a biochar content of about 15 percent by weight.
Example 3
Inert conditions were established and power was gradually increased at a rate of approximately 30 W/min up to 1.3 kW. Temperature was measured to be between 1600 degrees Celsius. The power was maintained steady for around 30 to 40 minutes after which the power was cut. Once cooled the sample was sieved to below 1 mm, at this point the mixture composition can be calculated as shown in Table 3. It was then leached with 500 ml of hydrochloric acid overnight, followed by washing with deionised water and filtering with a Buchner funnel. The resulting graphite was analysed using XRD (Bruker D8 Advance diffractometer using a mirror-derived lmm high parallel beam of cobalt K alpha radiation, weighted mean wavelength 1.709026 Angstroms) and SEM (using an ultra-high-resolution field-emission microscope: Zeiss Ultra Plus 55 FEGSEM, equipped with an in-lens detection system operating at an acceleration voltage of 1 to 10 kV. A working distance of between 1 and 5 mm was used and the powders were lightly deposited on carbon tape without any additional sample preparation). The XRD spectra is shown in Figure 9 and indicates a d-spacing of 0.3360 nm, in addition since no other peaks except those for graphite it can be concluded that the sample has a graphite (carbon) purity in excess of 90% wt. A sample of the graphite was characterised and found to have a surface area of 50.2 m2/g. Furthermore, since the XRD
spectra lacks the broad, low intensity peak of amorphous carbon at low angles, it can be concluded that less than 20% of the carbon is not graphitic. The structure of the formed graphite is shown in Figure 8, indicating an intermediary between flake-like particles and smaller, random crystallites with a more isotropic structure.
Table 3¨ Example 3 - Mixture Composition Metal Carbon content Yield of Mn Mass (%) est. post Carbon Acetate Metal Carbon Metal Component (g) reduction (g) (%) (g) (%) (%) Dry char 26.7 55% 14.685 80%
Mn Acetate 16.2 22% 3.6 20%
Based on the XRD result it can be assumed that 80% of the carbon is graphitic, thus the composition of the mixture can be stated as:
(a) a graphite content of about 64 percent by weight, (b) a metal content of about 20 percent by weight, and (c) a biochar content of about 16 percent by weight.
Example 4
The graphite from several test runs under similar conditions as those described in Example 1 to 3, were mixed together to generate a large sample for battery testing. The mixed sample was analysed using XRD and found to have a d-spacing of around 0.3378 nm as shown in Figure 10. Surface area was measured as 52.85 m2/g. The particle size distribution was verified and the material was found to have an average particle size of 29.22 micron as demonstrated in Figure 11. The lithium-ion battery performance was verified as follows: graphite was coated onto a copper foil using a suitable binder. After drying circular discs were cut using a punch and mallet. These were combined with lithium metal foil to form a coin cell. The organic electrolyte consisting of LiPF6 and ethylene carbonate was introduced under inert conditions. The coin cell was sealed and tested using a potentiostat. The electrochemical data was collected and analysed manually after testing in CR2016 coin cells. Figure 12 shows first charge and discharge cycles at C/20 (C being the theoretical capacity of graphite which is 372 mAh/g) at constant current rate. The specific capacity obtained from the first discharge cycle for the CarbonScape graphite in the half cell is 410.87 mAh/g while the charge capacity is 275 mAh/g. This gives a first cycle or "Colounabic- efficiency of 66.46%, thus the graphite exhibits properties which are suitable for use in lithium-ion batteries.
Example 5
Aircooled Vacuum Furnace model RD-G). Inert conditions were established by purging with Argon gas (>99.9%) and the temperature was increased at a ramp rate of 10 degrees per minute. Final temperature was set at 1750 degrees Celsius. The temperature was maintained steady for 180 minutes after which the furnace was switched off.
Once cooled the sample was sieved to below 1 mm, at this point the mixture composition can be calculated as shown in Table 4. It was then leached with 500 ml of hydrochloric acid overnight, followed by washing with deionised water and filtering with a Buchner funnel.
The resulting graphite was analysed using XRD (Bruker D8 Advance diffractometer using a mirror-derived 1 mm high parallel beam of cobalt K alpha radiation, weighted mean wavelength 1.709026 Angstroms). The XRD spectra is shown in Figure 13 and indicates a d-spacing of 0.3358 nm, in addition since no other peaks except those for graphite it can be concluded that the sample has a graphite (carbon) purity in excess of 90% wt. Using the established correlation between d-spacing and discharge capacity [5], this material may be estimated to have an electrochemical capacity of around 351 mAh/g.
Furthermore, since the XRD spectra lacks the broad, low intensity peak of amorphous carbon at low angles, it can be concluded that less than 20% of the carbon is not graphitic.
A sample of the graphite was characterised and found to have an unexpectedly low surface area of 5.439 m2/g. Using the established correlation between "Coul ombi c efficiency" and specific surface area [5], this material may be estimated to have a "Coulombic efficiency" of around 85%
Table 4- Example 5 - Mixture Composition Metal Carbon content Yield of Mn Mass (%) est. post Carbon Acetate Metal Carbon Metal Component (g) reduction (g) (%) (g) (%) (%) Sawdust 10 20% 2 34%
Mn Acetate 17.6 22% 3.9 66%
Based on the XRD result it can be assumed that 80% of the carbon is graphitic, thus the composition of the mixture can be stated as:
(a) a graphite content of about 27 percent by weight, (b) a metal content of about 66 percent by weight, and (c) a biochar content of about 7 percent by weight.
Example 6
(Bruker D8 Advance diffractometer using a mirror-derived lmm high parallel beam of cobalt K
alpha radiation, weighted mean wavelength 1.709026 Angstroms). The XRD spectra is for this sample is also shown in Figure 13 and indicates a d-spacing of 0.3362 nm, in addition since no other peaks except those for graphite it can be concluded that the sample has a graphite (carbon) purity in excess of 90% wt. Using the established correlation between d-spacing and discharge capacity [5], this material may be estimated to have an electrochemical capacity of around 346 mAh/g. Furthermore, since the XRD
spectra lacks the broad, low intensity peak of amorphous carbon at low angles, it can be concluded that less than 20% of the carbon is not graphitic. A sample of the graphite was characterised and found to have an exceptionally low surface area of just 0.204 m2/g.
Using the established correlation between "Coulombic efficiency" and specific surface area [5], this material may be estimated to have a "C oul omb i c efficiency"
of around 96%.
Table 5¨ Example 6 - Mixture Composition Metal Carbon content Yield of Mn Mass (%) est. post Carbon Oxide Metal Carbon Metal Component (g) reduction (g) (%) (g) (%) (%) Dry Char 10 80% 8 66%
Mn Oxide 6.6 63% 4.2 34%
Based on the XRD result it can be assumed that 80% of the carbon is graphitic, thus the composition of the mixture can be stated as:
(a) a graphite content of about 53 percent by weight, (b) a metal content of about 34 percent by weight, and (c) a biochar content of about 13 percent by weight.
REFERENCES
[1] Mochida, 1., Ohtsubo, R., Takeshita, K. and Marsh, H., 1980. Catalytic graphitization of non-graphitizable carbon by chromium and manganese oxides. Carbon, 18(2), pp.117-123.
[2] Oya, A., Yamashita, R. and Otani, S., 1979. Catalytic graphitization of carbons by borons. Fuel, 58(7), pp.495-500.
[3] Franklin, R.E., 1951. The structure of graphitic carbons. Acta crystallographica, 4(3), pp.253-261.
[4] Tatsumi, K., Iwashita, N., Sakacbe, H., Shioyama, H., Higuchi, S., Mabuchi, A. and Fujimoto, H., 1995. The influence of the graphitic structure on the electrochemical characteristics for the anode of secondary lithium batteries. Journal of the Electrochemical Society, 142(3). p.716.
[5] Nishida, T., 2009. Trends in carbon material as an anode in lithium-ion battery. In Lithium-ion batteries (pp. 329-341). Springer, New York, NY.
[6] Dahn, J.R., Zheng, T., Liu, Y. and Xue. J.S., 1995. Mechanisms for lithium insertion in carbonaceous materials. Science, 270(5236), pp.590-593.
Claims
1 A composition of matter comprising a mixture of biochar, a metal and graphite, with (a) a graphite content of between about 25 to 65 percent by weight, (b) a metal content of between about 15 to 75 percent by weight and (c) a biochar content of between 1 and 35 percent by weight.
2 The composition as claimed in claim 1, wherein the graphite has a d-spacing of between about 0.3354 and 0.3401 nm.
3 The composition as claimed in claim 1, wherein the graphite electrochemical capacity is at least 200 mAh/g.
4 The composition as claimed in claim 1, wherein the graphite electrochemical capacity is at least 300 mAh/g.
5 The composition as claimed in claim 1, wherein the specific surface area of the graphite is between about 0.2 to 50 m2/g.
6 The composition as claimed in claim 1, wherein the specific surface area of the graphite is between about 0.5 to 20 na2/g.
7 The composition as claimed in claim 1, wherein the graphite exhibits a "Coulombic" or first cycle efficiency of greater than 60%.
8 The composition as claimed in claim 1, wherein the graphite exhibits a "Coulombic" or first cycle efficiency of greater than 80%.
9 The composition as claimed in any one of claims 1 to 8, wherein the graphite content in the mixture is in particulate form.
10 The composition as claimed in any one of claims 1 to 9, wherein the metal content in the mixture is in particulate form.
11 The composition as claimed in any one of claims 1 to 10, wherein the biochar content in the mixture is in particulate form.
12 The composition as claimed in any one of claims 1 to 8, wherein the graphite, metal and biochar content are all in particulate form.
13 The composition as claimed in any one of claims 1 to 12, wherein the mixture is a binary mixture having an elemental composition of between about 25 to 75 percent carbon made up of biochar and graphite and between about 75 to 25 percent of a selected metal.
14 The composition as claimed in any one of claims 1 to 13, wherein the biochar content is derived from woody biomass heated to temperatures of between about 200 and 1000 degrees Celsius.
The composition as claimed in any one of claims 1 to 14, wherein the metal is a transition metal.
16 The composition as claimed in claim 15, wherein the transition metal is selected from chromium, zirconium, molybdenum, ruthenium, rhodium, palladium, silver, 10 cadmium, zinc, copper, nickel, cobalt, iron, manganese, chromium, vanadium or any combination thereof.
17 The composition as claimed in any one of claims 1 to 16, wherein the particulate sizes of the biochar component are less than about 1 millimetre.
18 The composition as claimed in any one of claims 1 to 17, wherein the particulate 15 sizes of the metal component are less than about 1 millimetre.
19 The composition as claimed in any one of claims 1 to 18, wherein the particulate sizes of the graphite component are less than about 1 millimetre.
The composition as claimed in any one of claims 1 to 16, wherein the particulate sizes of all the components are less than 1 millimetre.
20 21 The composition as claimed in any one of claims 1 to 20 wherein the rnixture has a total graphitic carbon content greater than about 55%wt.
22 A graphite powder produced from a mixture as claimed in any one of claims 1 to 21.
23 A high performance lithium ion battery anode powder produced from a mixture as claimed in any one of claims 1 to 21.
24 A method of producing a mixture as claimed in any one of claims 1 to 23; the method including the steps of:
i) theimally treating biomass in particulate form at a temperature of between 200 and 1000 degrees Celsius to form a particulate biochar;
ii) combining the resulting biochar with a particulate metal compound combining the resulting biochar with a particulate metal compound in a wet or a dry form to create a precursor mixture;
iii) heating the precursor mixture to between about 400 to about 3000 degrees Celsius under inert conditions to form a graphite containing mixture;
iv) sieving the final mixture to below about 1 mm particulate size to produce a mixture having (a) a graphite content of between about 25 to 65 percent by weight, (b) a metal content of between about 15 to 75 percent by weight and (c) a biochar content of between 1 and 35 percent by weight.
25 The method as claimed in claim 24, wherein the biomass is thermally treated in water in a hydrothermal step.
26 The method as claimed in claim 24, wherein the biomass is thermally treated under inert conditions in a dry pyrolysis step.
27 The method as claimed in any one of claims 24 to 26, wherein the biomass is forestry residue.
28 The method as claimed in any one of claims 24 to 26, wherein the biomass is sawdust, wood chip or other wood-based material.
29 The method as claimed in any one of claims 24 to 28, wherein the biomass particles are less than about 10 mm.
The method as claimed in any one of claims 24 to 28, wherein the biomass particles are less than about 1 mm.
31 The method as claimed in any one of claims 24 to 30, wherein the method includes one or more of the following steps, selected from:
25 (a) purification;
(b) washing and filtering the resulting graphite;
(c) densification; and (d) carbon coating.
32 The method as claimed in claim 31, wherein acid leaching is used in the 30 purification step.
33 The method as claimed in claim 31 or claim 32, wherein spheroidization is used in the densification step.
34 A graphite powder produced from a method as claimed in any one of claims 24 to 33.
35 A high performance lithium ion battery anode powder produced from a method as claimed in any one of claims 24 to 33.
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| PCT/NZ2021/050146 WO2022225405A1 (en) | 2021-04-21 | 2021-08-25 | Composition of matter for the production of graphite powder |
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