CA2872715C - Surface-modified carbon hybrid particles, methods of making, and applications of the same - Google Patents
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- H01M4/583—Carbonaceous material, e.g. graphite-intercalation compounds or CFx
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Abstract
Description
APPLICATIONS OF THE SAME
FIELD OF THE DISCLOSURE
[0001] The present disclosure relates to surface-modified carbon hybrid particles, methods for preparation thereof, and their use, for example as conductive additives in a variety of applications.
BACKGROUND
Nakamura, K. Takahashi, M. Tsubota, Journal of Power Sources, 64 (1997), 147 and D.
Pavlov, P.
Nikolov, T. Rogachev Journal of Power Sources 196 (2011) 5155-5167). When a lead acid battery is operated at partial state-of-charge (PSoC) the irreversible formation of lead acid sulfate ("sulfation effect") causes a significant reduction of the battery cycle life (see, for example, D. Pavlov, Lead-Acid Batteries-Science and Technology, Elsevier 2011, Chapter 1, pp. 23-26).
Pavlov, Lead-Acid Batteries-Science and Technology, Elsevier 2011, Chapter 7).
The battery characteristics obtained in these advanced lead acid batteries at shallow high rate discharge operations make them good candidates for micro- and mild hybrid electric vehicles.
Hong, Xiaobin;
Xie, Kai; Rong, Lixia, Huagong Jinzhan (2011), 30(5), 991-996 and Yao, Zhen-Dong; Wei, Wei; Wang, Jiu-Lin; Yang, Jun; Nuli, Yan-Na, Wuli Huaxue Xuebao (2011), 27(5), 1016).
Swette, J. Giner, Proceedings - Electrochemical Society (1992), 92-11(Proc.
Workshop Struct. Eff. Electrocatal. Oxygen Electrochem., 1992), 510-22, S. Muller, F.
Holzer, H. Arai, 0. Haas, Journal of New Materials for Electrochemical Systems (1999), 2(4), 227-232 and F. Mai!lard, P. Simonov, E. Savinova, Carbon Materials for Catalysis (2009), 429-480).
Primak, L.H. Fuchs, Phys. Rev. 95(1) (1954) 22).
Welham, J.S.
Williams, Carbon 36(9) (1998) 1309-1315, T.S. Ong, H. Yang, Carbon, 38 (2000) and Y. Kuga, M. Shirahige, Y. Ohira, K. Ando, Carbon 40 (2002), 695-701). A
drawback of conventional milling processes is that activated carbon and high surface area graphite can contain a relatively high amount of trace metals due to the use of metal based milling equipment. Metal trace elements may act as electrocatalysts interfering with the desired electrochemical process and cause parasitic chemical or electrochemical side reactions which decrease the cycling stability and reduce the cell life.
Bansal, M. J. Wang, in Carbon Black Science and Technology, 2nd ed., Marcel Dekker Inc., New York, 1993).
The large intra- and inter-aggregate void volume of conductive carbon black created by the carbon black structure results in high oil absorption numbers. Conductive carbon blacks typically have oil absorption numbers above 150 mL/100 g (measured according to ASTM
D2414-01, see method described below).
Rodriguez-Reinoso, Activated Carbon, Elsevier, 2006).
As both low and high surface area carbons (graphite and amorphous carbon powders) have shown to exert positive effects yet suffer from different drawbacks in the intended applications, attempts to use a mixture of the two have been described in the literature (see for example, M. Fernandez, Batteries & Energy Storage (BEST) Spring 2011 81-93 and M.
Fernandez, N, Munoz, R. Nuno, F. Trinidad, Proceedings of the 8th International Conference on Lead Acid Batteries, Extended Abstract #6, Lead Acid Battery Department of the Bulgarian Academy of Science, Sofia, Bulgaria, June 7th-10th, 2011, p. 23-28).
However, such mixtures are fraught with problems. For example, in the manufacturing process of the negative electrode, the required homogeneous mixing of two carbon components, one of which has a very low volume density in the lead oxide paste formulation, can be problematic.
SUMMARY
surface area of at least 50 m2/g and no greater than 800 m2/g, a DFT mesopore area of at least 40 m2/g and no greater than 400 m2/g, wherein the DFT mesopore area is equal to or less than the BET
surface area.
BRIEF DESCRIPTION OF THE DRAWINGS
exhibits a higher intensity of the G-band indicating a higher degree of graphitization.
illustrating the amorphous carbon morphology at the surface of the secondary particles (particle microstructure).
DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS OF THE INVENTION
Surface-modified Carbon Hybrid Particles
mesopore volume of the surface-modified carbon hybrid particles is at least 0.10 cm3/g, or at least 0.15 cm3/g, or at least 0.17 cm3/g, or at least 0.29 cm3/g, and/or the ratio of DFT
mesopore volume to total DFT pore volume is from 50 to 95 %, or from 70 to 95 %, or from 80 to 95 %. This data demonstrates that a large proportion of the surface pore area is made up of mesopores and an even larger proportion of the total pore volume is made up of mesopores.
measurement by laser diffraction can be explained by the higher shear forces applied to the agglomerates in the wet dispersion method, which appears to break down the largest agglomerate particles during the dispersion step required for the measurement while the dry dispersion method appears to have less impact on the agglomerate carbon hybrid particle size. In any event, the surface-modified carbon hybrid particles mentioned herein refer to the agglomerated product unless specified otherwise. Likewise, unless specified otherwise, the values given herein (e.g. BET SSA, mesopore area or volume, etc.) also refer to the agglomerated products and not the primary (often sub-micron) particles.
Thus, in some embodiments of the invention, the oxygen content of the surface-modified carbon hybrid particles, as measured according to the method set out below, is at least 0.45 % w/w, or at least 0.85 % w/w, or at least 1 % w/w, or at least 2 % w/w, or at least 3 %
w/w and typically no greater than 7 % w/w, or no greater than 8 % w/w. As can be seen in Table 2 below, the comparative examples of a variety of known carbon materials all have an oxygen content of 0.41 % w/w or below. Since some of the oxygen groups on the surface of the particles are effectively carboxyl groups, it is not surprising that in most embodiments, the surface-modified carbon hybrid particles have an acidic pH, i.e. a pH of below 7.0, preferably below 6.7, or below 6.5, or below 6.0, or below 5.5, or even below 5Ø
appears to be especially relevant for the affinity of the particles to lead.
This is particularly important when using the surface-modified hybrid carbon particles as conductive additives in the negative electrode of a lead acid battery. Furthermore, the combination of high mesopore content and high concentration of "surface oxides" seems to lead to excellent lead plating properties (cf. Figure 10).
Alternatively, the surface-modified carbon hybrid particles can also be characterized by their so-called Scott density. Thus, in many embodiments the Scott density of the surface-modified carbon particle will typically range from 0.2 to 0.6 g/cm3, or from 0.25 to 0.6 g/cm3.
Accordingly, the degree of graphitization of the surface-modified carbon hybrid particles (which is calculated according to the method outlined below with the aid of the c/2 value) typically ranges from 80 to 95%, or from 85 to 95%, or from 90 to 95%.
A Dgo value of non-agglomerated particles of less than 10 pm, or less than 8 pm, or less than 5 pm, or less than 4 pm, or less than 3 pm, or less than 2 pm, or less than 1.8 pm; and/or a D50 value of non-agglomerated particles of less than 4 pm, or less than 2 pm, or less than 1 pm, or less than 0.75 pm, or less than 0.4 pm, or less than 0.3 pm; and/or a D10 value of non-agglomerated particles of less than 0.6 pm, or less than 0.4 pm, or less than 0.2 pm, or less than 0.15 pm.
In fact, at corresponding compaction densities, the electrical resistivity that can be obtained for the surface-modified carbon hybrid particles approaches that of graphite, which in turn is lower than the resistivity obtained with carbon black.
Methods for Making Surface-modified Carbon Hybrid Particles
a Dgo value of from 20 to 60 pm, or from 30 to 50 pm, or from 40 to 50 pm, and/or a D50 value of from 7 to 15 pm, or from 7 to 12 pm, and/or a D10 value of from 0.3 to 4 pm, or from 0.4 to 3 pm, or from 0.5 to 2 pm.
Thus, there will be no burn-off of carbonaceous material as is observed in surface-modification processes at temperatures above 400-500 C. Nevertheless, as briefly mentioned before, due to the exothermic reaction of the oxygen containing gas with the carbon particles, a temperature rise (e.g. to about 150 C) will often be observed in the mixer even if there is no external heating applied to the mixture.
w/w, or at least 3 % w/w. Likewise, the controlled oxidation is in most embodiments carried out until the pH is below 7Ø In some embodiments the pH of the particles will be below 6.7, below 6.5, below 6.0, below 5.5, or even below 5Ø
Optionally, the mill is fitted with an internal non-metal lining, preventing further metal contamination of the particles.
Polymer Compounds Filled with Surface-modified Carbon Hybrid Particles
Use of Surface-modified Carbon Hybrid Particles as Additives in Battery Electrodes
89-92).
Power Sources 73 (1998), pp. 89-92).
by weight of the total mass of the electrode.
Moreover, compared with other carbons having a similar surface area a better resistivity against oxidative corrosion and electrolyte decomposition in lead acid batteries has also been observed for the carbon hybrid particles described herein. In addition, the increased concentration of superficial oxide surface groups causes a more polar carbon surface and therefore increases of the carbons' hydrophilicity. This improved wetting of the carbon hybrid surface in aqueous media leads to advantages in the manufacturing process of the negative electrode mass as the carbon hybrid, compared to typical graphite or carbon black, mixes more readily into the aqueous paste of lead oxide and other negative electrode components.
Due to the micro-structure of the surface-modified carbon hybrid particles, they may act as a host for the sulfur acting as the electrochemically active component in the positive electrode.
It has been found that positive electrodes containing sulfur absorbed within the microstructure of the surface-modified carbon hybrid particles show excellent mechanical stability and resistivity against oxidative corrosion.
Use of Surface-modified Carbon Hybrid Particles as Catalyst Supports
in air electrodes used in fuel cells and metal air electrodes, the metal or metal oxide catalysts can be finely dispersed on the amorphous carbon surface. It is thought that the surface õoxides" and pores function as anchor points to stabilize the catalyst finely dispersed on the carbon surface, which appears to suppress any segregation effects during preparation and operation. The high and homogeneous dispersion of the metal catalyst cannot be achieved in typical graphite powders, which is thought to be at least in part due to the absence of the aforementioned surface morphology exhibited by the carbon hybrid particles as described herein.
Dispersions of Surface-modified Carbon Hybrid Particles
wetting agents) in liquid polar media.
Measurement Methods
Specific BET Surface Area, DFT Micropore and Mesopore Volume and Area
are measured and processed with DFT calculation in order to assess the pore size distribution, micro- and meso pore volume and area.
Reference: Ravikovitch, P., Vishnyakov, A., Russo, R., Neimark, A., Langmuir 16 (2000) 2311-2320; Jagiello, J., Thommes, M., Carbon 42 (2004) 1227-1232.
Particle Size Distribution (PSD)
parallel beam from a low-power laser lights up a cell which contains the sample suspended in water. The beam leaving the cell is focused by an optical system. The distribution of the light energy in the focal plane of the system is then analyzed. The electrical signals provided by the optical detectors are transformed into particle size distribution by means of a calculator. The method yields the proportion of the total volume of particles to a discrete number of size classes forming a volumetric particle size distribution (PSD). The particle size distribution is typically defined by the values D10, D50 and Dgo, wherein 10 percent (by volume) of the particle population has a size below the D10 value, 50 percent (by volume) of the particle population has a size below the D50 value and 90 percent (by volume) of the particle population has a size below the Dgo value.
References: ISO 13320 (2009) / ISO 14887 Primary Particle Size
Oxygen Content
Gases generated in the furnace are released into flowing inert gas stream. The gas stream is then sent to the appropriate infrared (0 as CO by NDIR) or thermal conductivity (N and H by TCD) detectors for measurement. Instrument calibrations are performed using known reference materials.
pH Value
meter is placed in the slurry. After a stabilization time of 2 minutes the slurry is stirred and the pH value is recorded to the nearest 0.05 unit. (ASTM D1512-95 (method B)) Tapped density
Subsequently, the cylinder is fixed on the off-centre shaft-based tapping machine and 1500 strokes are run. The reading of the volume is taken and the tap density is calculated.
Reference: -DIN-ISO 787-11 Scott density
Reference:- ASTM B 329-98 (2003) Oil Absorption
Oil Absorption Number
Carbon powder, ground to a maximum particle size of 80 pm by means of a vibrated mill is compacted to a tablet. The sample is placed onto the excitation stand under argon atmosphere of the spectrometer. Subsequently the fully automatic analysis can be initiated.
Reference: (i) K. Slickers Automatic Emission Spectroscopy Bruhl Druck und Presshaus Giessen (D) (1992), (ii) M. Wissler und P. Gebhardt Protokoll der 29. Sitzung des Unterausschusses Feststoffe im Arbeitskreis Kohlenstoff der Deutschen Keramischen Gesellschaft (12./13. Dez 1984) Crystallite Size La
La[Angstrom (A)]= C x (IG/ID) where constant C has values 44[A] and 58[A] for lasers with wavelength of 514.5 nm and 632.8 nm, respectively. IG and ID are the intensity of the G- and D-band Raman absorption peaks at 1580 cm-1 and 1320 cm-1, respectively.
Crystallite Size Lc
lwashita, C. Rae Park, H. Fujimoto, M. Shiraishi and M. lnagaki, Carbon 42, 701-714 (2004)) is used. The algorithm proposed by lwashita has been specifically developed for carbon materials. The widths of the line profiles at the half maximum of sample and reference are measured. By means of a correction function, the width of pure diffraction profile can be determined. The crystallite size is subsequently calculated by applying Scherrer's equation (P. Scherrer, Gottinger-Nachrichten 2 (1918) p. 98).
Interlayer Spacing c/2
Reference: Klug and Alexander, X-Ray diffraction Procedures John Wiley and Sons Inc., New York London (1967) Degree of Graphitization
d ¨
F¨
a ¨
where d is the measured average interlayer spacing measured according to the method above, a' is the interlayer distance for a random orientation (0.344 nm), and a" is the spacing for a graphitic orientation (0.3354 nm).
Reference: H. Takahashi Carbon 2 (1965) 432 Powder conductivity, compressibility, and compression work
/IV ¨ _________________________________________ where .:(P: is the specific resistivity as a function of the pressure, A is the cross section area of the samples, i is the applied current, V(P) is the established voltage difference, and t(P) is the thickness of the sample. For comparison purposes Aiv-!. is reported as a function of sample density calculated as following:
Q(F) = ________________________________________ A t(P) where Q02; is the density of the sample and m is its mass. The mechanical work for compression is calculated as - hi) where E is the mechanical work of compression, p is the pressure, S is the cross section area and h is the thickness (N. Probst, E. Grivei, Carbon 40 (2002) 201-205).
Lead impregnation
BET surface area and Pb content is measured on the dry carbon according to the methods described above.
Immersion potential
aqueous Pb(NO3)2 solution measured against a Hg/Hg(SO4)/3.8M H2SO4 reference electrode (Potential vs NHE 634mV). The given value is an average over the first minute of immersion.
Lead deposition
reference electrode is applied after 60s of equilibration time at the open circuit potential. The working electrode is rested at the open circuit potential for 60 s after the potentiostatic pulse and then carefully washed in deionized water and dried. The dried electrode is observed with a scanning electron microscope to visualize possible lead deposition.
Powder conductivity of mixtures
Double layer capacitance
electrolyte in a three electrode arrangement with a Hg/Hg(SO4)/3.8M H2SO4 reference electrode and a counter electrode. The cyclic voltammetries are measured in the potential range 0.1 ¨ -0.5V vs. reference electrode in order to avoid faradaic reactions at the scan rate lmV/s. The specific double layer capacitance is derived from the average absolute current in the in the potential range 0 ¨ -0.4V as following:
ILI
C = ¨
s. m where C is the specific capacitance, I z I is the average absolute current in the potential range 0 - -0.1V, s is the scan rate, and m is the active material mass of the tested electrode.
Hydrogen evolution
electrolyte in a three electrode arrangement with a Hg/Hg(SO4)/3.8M H2SO4 reference electrode and a counter electrode. The cyclic voltammetries are measured in the potential range 0.1 ¨ -1.2V vs. reference electrode. H2 evolves at a potential of ca. -0.8V for the considered systems. The charge involved in H2 evolution is calculated as following:
1 -1.2V i Q ¨ 1 .-' 11 C 06 ... 17L
where Q is the specific charge involved in H2 evolution, i is the current, m is the active material mass in the electrode, t is the time, and C is the specific capacitance. The reduction charge is calculated from the cyclic voltammetry in the potential range -0.6 --1.2V. From the so calculated charge value, the charge needed to charge the double layer (C .
0,.6) is subtracted.
Spring back
Some embodiments will now be described by way of illustration, with reference to the following numbered embodiments and working examples.
1. Surface-modified carbon hybrid particles comprising a graphite core coated with amorphous carbon in agglomerate form having a BET surface area of at least 50 m2/g, or at least 80 m2/g, or at least 100 m2/g and no greater than 800 m2/g and a DFT
mesopore area of at least 40 m2/g, or at least 60 m2/g, or at least 70 m2/g, or at least 80 m2/g and no greater than 400 m2/g.
2. The surface-modified carbon hybrid particles of embodiment 1, wherein the ratio of DFT mesopore area to total DFT pore area is from 20 to 90 %, or from 45 to 75 %, or from 50 to 70%.
3. The surface-modified carbon hybrid particles of embodiment 1 or embodiment 2, wherein the DFT mesopore volume is at least 0.10 cm3/g, or at least 0.17 cm3/g, or at least 0.29 cm3/g.
4. The surface-modified carbon hybrid particles of embodiments 1 to 3, wherein the ratio of DFT mesopore volume to total DFT pore volume is from 50 to 95 %, or from 70 to 95 %.
5. The surface-modified carbon hybrid particles of embodiments 1 to 4, wherein the agglomerates have a Dgo value (as determined by the wet dispersion method) of from 20 to 60 pm, or from 30 to 50 pm, or from 40 to 50 pm and/or a D50 value of from 7 to 15 pm, or from 7 to 12 pm and/or a D10 value of from 0.3 to 4 pm, or from 0.4 to 3 pm, or from 0.5 to 2 pm and/or a Dgo value (as determined by the dry dispersion method), of from 50 to 300 pm, or from 100 to 300 pm, or from 100 to 200 pm, or from 150 to 200 pm.
6. The surface-modified carbon hybrid particles of embodiments 1 to 5, wherein the oxygen content is at least 0.45 % w/w, or at least 0.85 % w/w, or at least 1 %
w/w, or at least 2 % w/w, or at least 3 % w/w.
7. The surface-modified carbon hybrid particles of embodiments 1 to 6, wherein the pH
of the particles is below 7.0, or below 6.5, or below 6.0, or below 5Ø
8. The surface-modified carbon hybrid particles of embodiments 1 to 7, wherein the tapped density is from 0.35 to 0.7 g/cm3, or from 0.4 to 0.7 g/cm3, and/or wherein the Scott density is from 0.2 to 0.6 g/cm3, or from 0.25 to 0.6 g/cm3 9. The surface-modified carbon hybrid particles of embodiments 1 to 8, wherein the oil absorption is 150 % w/w or less, or 140 % w/w or less, or 120 % w/w or less, or 100% w/w or less, or 80 % w/w or less.
10. The surface-modified carbon hybrid particle of embodiments 1 to 9, wherein the ash content is below 0.1 %, or below 0.08 %, or below 0.05 %.
11. The surface-modified carbon hybrid particles of embodiments 1 to 10, wherein the Fe content value is below 500 ppm, or below 400 ppm, or below 300 ppm, or below 200 ppm, or below 160 ppm.
12. The surface-modified carbon hybrid particles of embodiments 1 to 11, wherein the crystallite size La (as measured by Raman spectroscopy) is from 1 to 10 nm, or from 3 to 8 nm, or from 4 to 6 nm.
13. The surface-modified carbon hybrid particles of embodiment 1 to 12, wherein the crystallite size Lc (as measured by XRD) is from 10 to 100 nm, or from 10 to 60 nm, or from 10 to 50 nm.
14. The surface-modified carbon hybrid particles of embodiments 1 to 13, wherein the degree of graphitization is from 80 to 95 %, or from 85 to 95 %, or from 90 to 95 %.
15. The surface-modified carbon hybrid particles of embodiments 1 to 14, wherein the D90 value of non-agglomerated particles (as determined by the wet dispersion method) is less than 10 pm, or less than 8 pm, or less than 5 pm, or less than 4 pm, or less than 3 pm, or less than 2 pm, or less than 1.8 pm and/or wherein the D50 value of non-agglomerated particles is less than 4 pm, or less than 2 pm, or less than 1 pm, or less than 0.75 pm, or less than 0.4 pm, or less than 0.3 pm and/or wherein the D10 value of non-agglomerated particles is less than 0.6 pm, or less than 0.4 pm, or less than 0.2 pm, or less than 0.15 pm.
16. A method of making surface-modified carbon hybrid particles as defined in any one of embodiments 1 to 15, comprising the steps of; a) milling graphite in a gas-tight sealed mill; b) functionalizing the resulting hybrid carbon by controlled oxidation.
17. The method of embodiment 16, wherein step a) is carried out until the Dgo value of non-agglomerated particles (as determined by the wet dispersion method) is less than 10 pm, or less than 8 pm, or less than 5 pm, or less than 4 pm, or less than 3 pm, or less than 3 pm, or less than 1.8 pm and/or wherein the D50 value of non-agglomerated particles is less than 4 pm, or less than 2 pm, or less than 1 pm, or less than 0.75 pm, or less than 0.4 pm, or less than 0.3 pm and/or wherein the D10 value of non-agglomerated particles is less than 0.6 pm, or less than 0.4 pm, or less than 0.2 pm, or less than 0.15 pm.
18. The method of embodiments 16 or 17, wherein the product from step a) is held in the gas-tight sealed mill for at least 15 minutes, or at least 30 minutes, or at least 45 minutes before carrying out step b).
19. The method of embodiment 18, wherein the product from step a) is held in the gas-tight sealed mill until the Dgo value (as determined by the wet dispersion method) of from 20 to 60 pm, or from 30 to 50 pm, or from 40 to 50 pm and/or a D50 value of from 7 to 15 pm, or from 7 to 12 pm and/or a D10 value of from 0.3 to 4 pm, or from 0.4 to 3 pm, or from 0.5 to 2 pm and/or a Dgo value (as determined by the dry dispersion method), of from 50 to 300 pm, or from 100 to 300 pm, or from 100 to 200 pm, or from 150 to 200 pm.
20. The method of embodiments 16 to 19, wherein the controlled oxidation is carried out by stirring the particles obtained in step a) in a mixer.
21. The method of embodiments 16 to 20, wherein the controlled oxidation is carried out at a temperature no greater than 400 C, or no greater than 300 C, or no greater than 200 C, or no greater than 100 C, or no greater than 50 C, or no greater than 30 C.
22. The method of embodiments 16 to 21, wherein the controlled oxidation is out carried until the oxygen content is at least 0.45 % w/w, or at least 0.85 % w/w, or at least 1 % w/w.
23. The method of embodiments 16 to 22, wherein the controlled oxidation is carried out until the pH is below 7.0, or below 6.5, or below 6.0, or below 5Ø
24. The method of embodiments 16 to 23, wherein the controlled oxidation is carried out in the presence of air, humidity, oxygen, another oxidizing gas and/or an oxidizing liquid.
25. The method of embodiment 24, wherein the oxidizing gas is NON, ozone or carbon dioxide.
26. The method of embodiment 24, wherein the oxidizing liquid is hydrogen peroxide or nitric acid.
27. The method of embodiments 16 to 26, wherein the sealed mill is a ball mill, such as a rotating mill, a tumbling mill or a vibration mill.
28. The method of embodiments 16 to 27, wherein the mill chamber is fitted with an internal lining.
29. The method of embodiments 16 to 28, wherein ceramic balls are used in step a).
30. The method of embodiments 16 to 29, wherein step a) is carried out for no longer than 150 hours, or no longer than 96 hours, or no longer than 84 hours, or no longer than 72 hours or no longer than 60 hours.
31. The method of embodiments 16 to 30, wherein after step b) the product is dispersed in a liquid in the presence of a surfactant or a polymer compound by applying shear force to deagglomerate the particles.
32. The surface-modified carbon hybrid particles as defined in any one of embodiments 1 to 15, obtainable by the method as defined in any one of embodiments 16 to 31.
33. A mixture of the surface-modified carbon hybrid particles according to any one of embodiments 1 to 15 or embodiment 32, and lignosulfonates and/or barium sulfate as an additive for the negative electrode of lead acid batteries.
34. A battery electrode comprising the surface-modified carbon particles of any one of embodiments 1 to 15 or embodiment 32, or the mixture of embodiment 33 as a conductive additive.
35. The battery electrode of embodiment 34, wherein the barium sulfate is added in an amount of about 0.2 to about 2 % by weight of the total mass of the electrode.
36. The battery electrode of embodiment 34 or 35, wherein the lignosulfonates are added in an amount of about 0.1 to about 1.5 % by weight of the total mass of the electrode.
37. A polymer compound filled with the surface-modified carbon particles of any one of embodiments 1 to 15 or embodiment 32.
38. Use of the battery electrode of any one of embodiments 34 to 36 in lead acid batteries.
39. Use of the battery electrode of embodiment 34 in lithium sulfur batteries.
40. Use of the battery electrode of embodiment 34 in electrochemical double layer capacitors.
41. The use according to embodiment 38, wherein the electrochemical double layer capacitors have an average capacitance of above 7 F/g, or above 6 F/g, or above 5.5 F/g.
42. Use of the surface-modified carbon particles of any one of embodiments 1 to 15 or embodiment 32 as carbon supports.
43. A dispersion of the surface-modified carbon particles of any one of embodiments 1 to or embodiment 32 in a liquid in the presence of a surfactant.
44. Use of the surface-modified carbon particles of any one of embodiments 1 to 15 or embodiment 32 to form a dispersion in a liquid in the presence of a surfactant by applying shear force to deagglomerate the particles.
10 45. Use of the dispersion of embodiment 40 or 41 as a conductive coating.
EXAMPLES
Example 1 ¨ Method for the Preparation of Surface-Modified Carbon Hybrid Particles
Table 1:
Carbon Milling Time BET SSA Mesopore Area Superficial Oxygen Hybrid [h] [m2/g] [m2/g] Groups [wt.%]
A 5 107 74 0.87 B 10 224 129 1.3 C 16.5 290 165 1.6 D 32 431 227 3.4 E 48 501 249 4.1
Graphite and Carbon), expanded graphite (TIMREX BNB90 ¨ TIMCAL Graphite and Carbon), carbon black (ENSACO 350G ¨TIMCAL Graphite and Carbon), and activated carbon (YP5OF ¨ Kuraray Chemical Co.):
Table 2:
Carbon Material Oxygen content [/o] pH BET
surface area [m2/g]
Carbon Hybrid A 0.87 5.1 107 Carbon Hybrid C 1.6 4.7 290 Carbon Hybrid D 3.4 4.5 431 Carbon Black 0.41 10 800 Synthetic graphite 0.16 5.4 16 Expanded Graphite 0.32 5.9 24 Table 3:
Carbon Material Oil Absorption (%) Spring Back (%) Carbon Hybrid A 79 14 Carbon Hybrid B 93 18 Carbon Hybrid C 102 18 Carbon Hybrid D 110 19 Carbon Hybrid E 120 17 Carbon black >600 88 Synthetic graphite 175 11 Activated carbon 155 75 Expanded graphite 166 11 Table 4:
Carbon material La Lc c/2 Degree of Tapped density [nm] [nm] [nm] graphitization P [/o]
[g/cm3]
Carbon Hybrid A 5.7 53 0.3361 92 0.676 0.5 Carbon Hybrid B 4.8 41 0.3361 92 0.641 0.3 Carbon Hybrid D 4.9 18 0.3370 83 0.431 0.8 Expanded graphite 24.3 1 40 0.3360 93 0.079 0.5 Synthetic graphite A 24.9 1 175 0.3357 97 0.12 .1 Activated Carbon 0 0 0 0 0.305 Synthetic graphite B - -- 99 -Table 5:
Carbon Material Average capacitance Fig BET SSA (m2/g) Carbon Hybrid A 7.5 110 Carbon Hybrid B 20.1 220 Carbon Hybrid C 25.1 275 Carbon Hybrid D 58.7 419 Carbon Hybrid E 58.3 481 Expanded graphite 4.4 24 Carbon black 20.6 753 Synthetic graphite 4.9 9 Activated carbon 198 1473 Table 6: Mesopore and Micropore surface area (cf. Figure 4) BET area DFT area Micropore Micropore Mesopore Mesopore (m2/g) (m2/g) area (m2/g) area (%) area (m2/g) area (%) Carbon 107 105 31 30 74 70 hybrid A
Carbon 224 223 94 42 129 58 hybrid B
Carbon 290 288 123 43 165 57 hybrid C
Carbon 431 431 204 47 227 53 hybrid D
Carbon 501 505 256 51 249 49 hybrid E
Carbon 809 777 357 46 420 54 black Expanded 30 44 0 0 44 100 graphite Activated 1382 1854 1659 89 195 11 carbon Table 7: Mesopore and Micropore volume (cf. Figure 5) DFT pore Micropore Micropore Mesopore Mesopore volume volume volume (%) volume volume (%) (cm2/g) (cm2/g) (cm2/g) Carbon 0.187 0.014 8 0.173 93 hybrid A
Carbon 0.315 0.042 13 0.273 87 hybrid B
Carbon 0.405 0.055 14 0.350 86 hybrid C
Carbon 0.557 0.090 16 0.466 84 hybrid D
Carbon 0.615 0.113 18 0.503 82 hybrid E
Carbon 0.979 0.166 17 0.813 83 black Expanded 0.142 0 0 0.142 100 graphite Activated 0.791 0.603 76 0.188 24 carbon
Table 8:
Carbon hybrid D Before functionalization After functionalization (oxidation) but after (oxidation in air at RT in an storage in air at RT for 24 h intensive mixer for 3 h, temperature measured in sample 140 C) Oxygen content [wt.%] 0.21 3.4 c/2 [nm] 0.3367 0.337 Lc [nm] 20 18 La [nrn] 5.8 4.9 Graphitization (P-factor) 85 83 BET [g cm-3] 389 419 Micropore area [m2 g-1] 192 204 Mesopore area [m2 g-1] 205 227 Micropore volume [cm3 g-1] 0.052 0.055 Mesopore volume [cm3 g-1] 0.326 0.350 Particle size distribution (Laserdiffraction MALVERN
Mastersizer S) Dry dispersion of particles in a MALVERN DRY
POWDER FEEDER MSX64) D10 [1-1111] 2.3 2.1 D50 [1-1m] 18.7 15.8 D90 [P ni] 183.8 147.9 Wet dispersion (5 min. ultrasonic treatment) D10 [1-1111] 1.1 1.1 D50 [1-1m] 10.9 10.9 D90 [pm] 44.8 43.1 Example 2 ¨ Alternative Method for the Preparation of Surface-Modified Carbon Hybrid Particles
relative humidity for 3 h. The resulting hybrid carbon showed a BET SSA of 720 m2/g and a mesopore area vs. total DFT area ratio of 45 %.
Example 3 ¨ A Further Alternative Method for the Preparation of Surface-Modified Carbon Hybrid Particles
The quantity of graphite loaded corresponds to a graphite-to-milling media ratio of about 20.
The vibrating ball mill was sealed gastight and the (dry) milling process was carried out in the gastight milling chamber of the vibrating ball mill. After the graphite was milled for 20 h, the ground carbon was rested for about 0.5 h in the sealed milling chamber and then transferred into an intensive batch mixer (Eirich, Germany 75 L batch size) for the functionalization process. The functionalization of the resulting carbon material was done by gently stirring the carbon material in the batch mixer flooded by air for 1 h. The resulting hybrid carbon showed a BET SSA of 330 m2/g and a mesopore area vs. total DFT area ratio of about 56 %.
Example 4¨ A Further Alternative Method for the Preparation of Surface-Modified Carbon Hybrid Particles
speed = 50-80 rpm) for a total duration of 5, 16, 32 and 48 h depending on the BET targeted resulting in hybrid carbons with a BET SSA of about 100, 300, 400 and up to 500 m2/g, respectively after the functionalization process which was done in the intensive batch mixer flooded with air for 1 h.
Milling time, graphite batch, milling media type, size and shape, together with mill filling and weight ratio are the process parameters that allow to adjust the final properties of the products, i.e. BET surface area, PSD, Scott density.
Example 5 ¨ A Further Alternative Method for the Preparation of Surface-Modified Carbon Hybrid Particles
in terms of reduction of milling time. Other means of improving the purging efficiency, like setting the milling chamber shortly in motion, may be applied as well.
Example 6¨ A Further Alternative Method for the Preparation of Surface-Modified Carbon Hybrid Particles
surface area, PSD and mesopore content, although slightly longer milling times were required in some instances compared to iron or stainless steel milling media.
Grinding with the non-metal grinding media did not lead to any increase of the metal contamination like iron, nickel, molybdenum, and vanadium. In fact, the iron content of the obtained particles was well-below 50 ppm or even less (depending on the purity of the starting material).
Example 7¨ Preparation of an Aqueous Colloidal Dispersion of Surface-Modified Hybrid Carbon Particles
Claims (22)
mesopore area to total DFT pore area is from 20 to 90 %, from 45 to 75 %, or from 50 to 70 %;
or the DFT mesopore volume is at least 0.10 cm3/g, at least 0.17 cm3/g, or at least 0.29 cm3/g; or the ratio of DFT mesopore volume to total DFT pore volume is from 50 to 95 %, or from 70 to 95 %
w/w or less, or wherein the degree of graphitization is from 80 to 95 %, from 85 to 95 %, or from 90 to 95 %.
a) milling graphite in a gas-tight sealed mill, and b) functionalizing the resulting hybrid carbon by controlled oxidation;
wherein the method further includes holding the product of the milling step a) in the gas-tight sealed mill to allow completion of agglomeration of milled primary particles before functionalization.
or wherein the D50 value of non-agglomerated particles is less than 4 µm, less than 2 µm, less than 1 µm, less than 0.75 µm, less than 0.4 µm, or less than 0.3 µm, or wherein the D10 value of non-agglomerated particles is less than 0.6 µm, less than 0.4 µm, less than 0.2 µm, or less than 0.15 µm.
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| KR101245815B1 (en) * | 2011-07-14 | 2013-03-21 | 국립대학법인 울산과학기술대학교 산학협력단 | Graphite with Edge Functionalized by Mechanochemical Method and Method for Producing It |
| HUE038545T2 (en) | 2012-05-21 | 2018-10-29 | Imerys Graphite & Carbon Switzerland Ltd | Surface-modified carbon hybrid particles, methods of making, and applications of the same |
-
2013
- 2013-03-15 HU HUE13712721A patent/HUE038545T2/en unknown
- 2013-03-15 CN CN201380023629.1A patent/CN104271502B/en active Active
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- 2013-03-15 WO PCT/EP2013/055370 patent/WO2013174536A1/en not_active Ceased
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- 2013-03-15 MX MX2014014227A patent/MX360762B/en active IP Right Grant
- 2013-03-15 EP EP13712721.3A patent/EP2852554B1/en active Active
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|---|---|
| CN106082203B (en) | 2018-12-14 |
| WO2013174536A1 (en) | 2013-11-28 |
| JP6235569B2 (en) | 2017-11-22 |
| EP2852554B1 (en) | 2017-12-20 |
| KR102069120B1 (en) | 2020-01-22 |
| PL2852554T3 (en) | 2018-06-29 |
| NO2870515T3 (en) | 2018-05-26 |
| US20180254119A1 (en) | 2018-09-06 |
| CA2872715A1 (en) | 2013-11-28 |
| DK2852554T3 (en) | 2018-03-12 |
| MX2014014227A (en) | 2015-08-05 |
| US20150099180A1 (en) | 2015-04-09 |
| US10115493B2 (en) | 2018-10-30 |
| CN106082203A (en) | 2016-11-09 |
| JP2015525184A (en) | 2015-09-03 |
| HUE038545T2 (en) | 2018-10-29 |
| ES2663004T3 (en) | 2018-04-10 |
| CN104271502B (en) | 2016-08-24 |
| BR112014029026A2 (en) | 2017-06-27 |
| MX360762B (en) | 2018-11-15 |
| CN104271502A (en) | 2015-01-07 |
| EP2852554A1 (en) | 2015-04-01 |
| KR20150059137A (en) | 2015-05-29 |
| US9991016B2 (en) | 2018-06-05 |
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