CA2621794C - High purity lithium polyhalogenated boron cluster salts useful in lithium batteries - Google Patents
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Abstract
Description
USEFUL IN LITHIUM BATTERIES
BACKGROUND OF THE INVENTION
[0001] Lithium secondary batteries, by virtue of the large reduction potential and low molecular weight of elemental lithium, offer a dramatic improvement in power density over existing primary and secondary battery technologies. Here, lithium secondary battery refers to both batteries containing metallic lithium as the negative electrode and batteries which contain a lithium ion host material as the negative electrode, also known as lithium-ion batteries. By secondary battery it is meant a battery that provides for multiple cycles of charging and discharging. The small size and high mobility of lithium cations allow for the possibility of rapid recharging. These advantages make lithium batteries ideal for portable electronic devices, e.g., cell phones and laptop computers.
Recently, larger size lithium batteries have been developed and have application for use in the hybrid vehicle market.
lithium hexafluoroarsenate has a problem of arsenic toxicity; and lithium triflate lead to significant corrosion of aluminum current collectors typically used in lithium ion batteries.
BRIEF SUMMARY OF THE INVENTION
Li2B12F.H12..-yZy where x+y is from 3 to 12, and x and y are independently from 0 to 12, and Z
comprises at least one of Cl and Br.
an ability to use a lithium based salt for an electrolyte solution which has electrochemical, thermal, and hydrolytic stability;
an ability to use a salt with acceptably low levels of impurities harmful to lithium ion cells (e.g., substantially free of water, hydroxyl moieties, metal cations including alkali metals and hydrogen fluoride);
an ability to use a lithium electrolyte solution which can be used at a low lithium based salt concentration, e.g., one-half the concentration of many other lithium-based salts, e.g.,LiPF6; and, an ability to form low viscosity, low impedance lithium electrolyte solutions which can be recycled.
BRIEF DESCRIPTION OF THE DRAWINGS
spectroscopy.
impurities.
DETAILED DESCRIPTION OF THE INVENTION
Other desired features of lithium electrolyte solutions include: high flash point;
low vapor pressure; high boiling point; low viscosity; good miscibility with solvents customarily employed in batteries, especially ethylene carbonate, propylene carbonate and alpha-omega-dialkyl glycol ethers; good electrical conductivity of their solutions over a wide temperature range, and tolerance to initial moisture content.
Li2B12F.H12-X-yZr where x+y is from 3 to 12, and x and y are independently from 0 to 12, and Z
is at least one of Cl and Br. Specific examples of lithium based dodecaborates comprise at least one member selected from the group consisting of Li2B12F5H7, Li2B12F6H6, Li2B12F7H5, Li2B12F8H4, Li2B12F9H3, Li2B12F,oH2, Li2B12F11H and mixtures of salts with varying x such that the average x is equal to or greater than 5, or equal to 9 or 10, or Li2B12FXCI12_x and Li2B12FxBr,2.x where x is 10 or 11, or Li2B12FCI2H9, Li2B12C13H9, Li2B12F2CI3H7, Li2B12CI5H7 and Li2B12FCI6H5; and mixtures thereof.
Metathesis using lithium hydroxide can provide the lithium salt. This reaction is normally conducted in a liquid medium. In direct fluorination, fluorine is usually diluted with an inert gas, e.g., nitrogen. Fluorine concentrations from about 10 to about 40 %
by volume are commonly employed. If further halogenation is desired, the partially fluorinated hydridoborate can be reacted with the desired halogen, e.g., chlorine or bromine.
reduced in acidity by the incorporation of a weak base. While any suitable acid can be employed, examples of suitable acids comprise at least one member selected from the group consisting of formic, acetic, trifluoroacetic, dilute sulfuric triflic, and sulfonic acids hydrohalic (HCI(aq), HBr(aq), Hl(aq), and HF(ft), and mixtures thereof. The addition of buffering salts, e.g., alkali metal fluorides such as potassium and sodium fluoride, also can reduce the acidity of neat HF in the fluorination reaction. A Hammett acidity, H , between 0 > H > -11 is useful as an acidic medium for effecting fluorination.
Without wishing to be bound by any theory or explanation, it is believed that radical scavengers can limit the formation of hydrogen peroxide, or HOF which may be generated with fluorine. Radical scavengers can be used to inhibit the side-reaction of fluorine with the solvent, thereby improving fluorination efficiency. Examples of radical scavengers comprise oxygen, nitroaromatics, and mixtures thereof. One method for employing a radical scavenger comprises introducing a relatively small amount of air to the liquid medium.
generation, which, in turn, can corrode electrode materials. As a result, the inventive salts and electrolytes are also substantially free of hydrogen fluoride (HF). Typical OH
containing impurities are water and alcohols in the electrolyte salts and solvents.
a) dissolving the material in an aprotic organic solvent to form a solution and passing said solution through an adsorbent (e.g., alumina column), b) dissolving the material in a solvent to form a solution, and passing said solution through a cation exchange medium (e.g., a column in Li` form), c) drying the material at a temperature and under conditions sufficient to volatize the impurity (e.g., a temperature greater than the than about 180 C
under vacuum or nitrogen purge), d) dissolving the material in an aprotic organic solvent to form a solution and passing said solution through a sieve (e.g., Li-substituted molecular sieve).
a) dissolving a salt comprising B12F,H12.x.yZy (2-) anion in an organic solvent to form a solution and treating the solution with an adsorbent which has higher affinity for impurities compare to the adsorbent affinity to the product b) dissolving a salt comprising B12F,H12_,.yZy (2-) anion in a solvent to form a solution, and passing said solution through a cation exchange column in Li+ form, c) drying lithium salt comprising B12F.H12.x.yZy (2-) anion at greater than about 180 C under vacuum or nitrogen purge, d) dissolving lithium salt comprising B12FXH72.x.yZy (2-) anion salt in an aprotic organic solvent to form a solution and passing said solution through a Li-substituted molecular sieve.
yZy (2-) anion and at least one cation, at least one useful solvent and at least one adsorbent are selected so the adsorbent has greater affinity to the salts of the impurities in comparison to the adsorbent affinity to the salts of B12FxH12.x_yZy (2-) anion.
Aluminum oxide acidity is selected to achieve the most efficient removal of impurities.
For example, acidic (pH of aqueous suspension is - 4.5), weakly acidic (pH of aqueous suspension is - 6.0), neutral (pH of aqueous suspension is - 7.0) and basic (pH of aqueous suspension is - 9.5) alumina can be employed. The adsorbent concentration in the solution ranges from about 0.1 to about 50 weight %. The mixture of adsorbent and the solution may be agitated for about 0.5 to about 24 hours and adsorbent may be removed by filtration. To improve the efficiency of purification process the solution may be eluted via a column packed with the adsorbent. Adsorbent may be used in powder or granular form. Powder form of adsorbent may allow faster adsorption rate while granular adsorbent may provide faster elution rate in the continuous column processes.
TGA/IR
analysis shows a drying temperature of greater than about 180 C and usually greater than about 220 C is needed for efficient drying. The lithium salt is further ground and loaded into a vessel (e.g., a drying column), which can be heated and allows for a dry, inert gas to be purged through the lithium salt at sufficient rate to fluidize or cause percolation of the bed of salt. Dry nitrogen is suitable as an inert gas and the vessel is typically heated to between about 230 to about 280 C. After about 3 to about 72 hrs, the lithium salt was analyzed (i.e., by Karl-Fischer analysis), and determined to contain between about 1 to about 50 ppm water, and usually about 5 to about 20 ppm water.
to about 72 hrs. While any suitable molecular sieves can be used, examples of suitable molecular sieves comprise 3A through 5A and normally lithium cation exchanged versions of these.
After this treatment the electrolyte solution typically contains less than about 20ppm water and usually less than about 10 ppm water. When similarly impure (e.g., about >20 to >100 ppm) electrolyte solutions comprising LiPF6 combined with aprotic organic solvents were dried by using molecular sieves, hydrolysis of the PF6- anion was observed. Unlike LiPF6, the inventive salt is stable with respect to such molecular sieves.
Typically, these aprotic solvents are anhydrous, and anhydrous electrolyte solutions are desirable, and in some cases organic. While any suitable solvent can be employed, examples of aprotic solvents or carriers for forming the electrolyte systems can comprise at least one member selected from the group consisting of dimethyl carbonate, ethyl methyl carbonate, diethyl carbonate, methyl propyl carbonate, ethyl propyl carbonate, dipropyl carbonate, bis(trifluoroethyl) carbonate, bis(pentafluoropropyl) carbonate, trifluoroethyl methyl carbonate, pentafluoroethyl methyl carbonate, heptafluoropropyl methyl carbonate, perfluorobutyl methyl carbonate, trifluoroethyl ethyl carbonate, pentafluoroethyl ethyl carbonate, heptafluoropropyl ethyl carbonate, perfluorobutyl ethyl carbonate, etc., fluorinated oligomers, dimethoxyethane, triglyme, dimethylvinylene carbonate, tetraethyleneglycol, dimethyl ether, polyethylene glycols, sulfones, and gamma-butyrolactone; and mixtures thereof.
or iron complex compounds such as ferrocyan blue, berlin green, among others and mixtures thereof. Specific examples of lithium composites for use as positive electrodes include LiNi,_xCoxO2and lithium manganese spinel, LiMn2O4.
Examples 7-9 illustrate a method to remove impurities comprising OH groups substituted on the B12 cage and alkali metal impurities. Example 10 shows that the last equivalent of water associated with the salt comes off most rapidly above 180 C and preferably above 220 C. Examples 11 and 12 illustrate the difference in efficiency of vacuum drying vs fluidized bed drying of the salt compositions produced in accordance with example 9 (e.g., water levels of 10-20 ppm were obtained). Examples 13 and 14 illustrate molecular sieve drying of electrolyte solutions. Example 15 illustrates the electrochemical impact of traces of water. Examples 16-18 illustrate using the inventive method for removing impurities from a potassium salt.
Example 1 Preparation of Li2B12F,H12.x, where x = 10-12 [0044] A colorless slurry containing 2.96 g (11.8 mmol) K2B12H12-CH3OH in 6 ml formic acid at an average Hammett acidity of H = -2 to -4 was fluorinated at 0 to 20 C. When 100% of the desired F2 (142 mmol) was added as a mixture of 10%F2/10%02/80%N2, a colorless solution remained. Further fluorination (3%) at 30 C resulted in precipitation of solid from solution. Solvents were evacuated overnight, leaving 5.1 g of a colorless, friable solid. Analysis of this crude product by 19F NMR revealed primarily B12F10H22_ (60%), B12F11H2- (35%), and B12F122- (5%). The crude reaction product was dissolved in water and the pH of the solution adjusted to between 4-6 with triethylamine and triethylamine hydrochloride. The precipitated product was filtered, dried, and resuspended in water. Two equivalents of lithium hydroxide monohydrate were added to the slurry and the resulting triethylamine evacuated. Additional lithium hydroxide was added until the pH of the final solution remained at 9-10 after distillation of all triethylamine. Water was removed by distillation and the final product was vacuum-dried at 200 C for 4-8 hrs. Typical yields of Li2B12F,,H12.x (x = 10,11,12) were -75%.
Example 2 Preparation of Li2B12F.,Br12_,, (x >_ 10, ave. x = 11) (0045] 3g Li2B12FXH12_. (x ? 10) (0. 008 mol) of average composition U213121=11H was dissolved in 160 mL of 1 M HCI(aq). Br2, 1.4 mL (0.027mol) was added and the mixture refluxed at 100 C for 4 hours. A sample was taken for NMR analysis.
Example 3 Preparation of Li2B12F,,CI12.X (ave. x = 11) [0047] 20 g Li2B12F11H mixture dissolved in 160 mL 1 M HCI in a three neck round bottom flask fitted with a reflux condenser and fritted bubbler. The mixture was heated to 100 C and CI2 gas was bubbled through at 15 standard cubic centimeter (sccm/min) The effluent, through the condenser, was passed through a solution of KOH and Na2SO3.
After 16 hours of bubbling CI2, the solution was purged with air. The HCI and water were distilled out and the residue was titrated with ether. Upon ether evaporation and vacuum oven drying of the white solid, 20 g of material of the above formula were recovered (92%). 19F-NMR in D20: -260.5, 0.035 F; -262.0, 0.082 F; -263.0, 0.022 F; -264.5, 0.344 F; -265.5, 0.066 F; -267.0, 0.308 F; -268.0, 0.022 F; -269.5, 1.0 F. 11B-NMR in D20: -16.841; -17.878 Example 4 Preparation of Li2B12FXCI12.x (ave. x =3) [0048] 3.78g K2B12F3H9 mixture was dissolved in 100 mL 1M HCI in a three neck round bottom flask fitted with a reflex condenser and fritted bubbler. The mixture was heated to 100 C and CI2 gas was bubbled through at 15 sccm. The effluent, through the condenser was passed through a solution of KOH and Na2SO3. After 8 hours of bubbling CI2, the solution was purged with air. There was some precipitate that formed and it was filtered out. The solution was brought to a pH of 9 by the addition of Et3N
which produced a white precipitate. The solution was cooled to 0 C to maximize precipitation and then filtered on a Buchner funnel and washed with cold water. The solid was dried in a vacuum at 120 C. 4.62 g of a composition of the above formula was recovered.
19F-NMR in acetone-d6: -225.2, 0.023 F; -228.5, 0.078 F; -229.5, 0.082 F; -231.2, 0.036 F; -232.8, 0.302 F; -233.2, 0.073 F; -234.3, 0.032 F; -235.5, 0.104 F; -237.6, 0.239 F; -238.4, 0.037 F; -239.8, 0.057 F; -242.0, 0.033 F. 11B-NMR in acetone-d6: -6 multiplet; -15 multiplet.
Example 5 Preparation of Li2B12F.,Cl12_x (ave. x = 11) [0049] 3 g Li2B12F11H mixture dissolved in 110 mL 1 M HCI in a three neck round bottom flask fitted with a reflux condenser and fritted bubbler. 1.4 mL Br2 was added.
The mixture was heated to 1000 C for 4 hours. An aliquot was removed for NMR
analysis. The mixture was again heated to 1000 C and CI2 gas was bubbled through at 15 sccm. The effluent, through the condenser was passed through a solution of KOH
and Na2SO3. After half an hour, the red Br2 solution was yellowish. After another 6 hours of bubbling CI2, the solution was purged with air. An aliquot was taken for 19F
NMR and found to be identical to the first sample. HCI and water were distilled out. The residue was vacuum dried at 150 C. 2.55 g of a composition of the above formula were recovered. 19F-NMR in D20: -257.8, 0.024 F; -259.0, 0.039 F; -259.5, 0.040 F; -261.0, 0.028 F; -261.5, 0.028 F; -263.0, 0.321 F; -265.2, 0.382 F; -269.2, 1.0 F.
Example 6 Preparation of Li2B12FxCl12_x (ave. x = 3) [0050] 2.48 g K2B12F3H9 mixture was dissolved in 100 mL 1M HCI in a round bottom flask fitted with a reflux condenser. The mixture was heated to 1000 C. After 8 hours of stirring, the solution was cooled to room temperature and left over the weekend. The excess Br2 was neutralized with Na2SO3 and the solution was brought to a pH of 9 by the addition of Et3N which produced a white precipitate. The solution was cooled to 00 C to maximize precipitation and then filtered on a Buchner funnel and washed with cold water. The solid was dried in a vacuum at 120 C. 19F-NMR in acetone-d6: -212.2, 0.030F; -213.6, 0.284 F; -216, 0.100 F; -217.0, 0.100 F; -217.9, 0.100 F; -219.3, 1.0 F; -221.3, 0.201 F; -222.5, 0.311 F; -223.2, 0.100 F; -225.2, 0.100 F; -225.5, 0.639 F; -226.6, 0.149 F; -229, 0.245 F; -232.0, 0.120 F. Metathesis with LiOH H2O was carried out as in Example 1. A composition described by the above formula was obtained.
Example 7 Purification of Li2B12FxZ12_x from Li2B12FXZy(OH)12.x_y [0051) In this example 50.5 g of partially fluorinated lithium fluorododecaborate salt having an average composition Li2B12F9H3, and also containing - 10 mol. % of Li2B12F9H2(OH) (an average composition of hydroxyl-substituted anions), was dissolved in 250 ml of 5-methyl-2-hexanone. The small amount of insoluble material was removed on the centrifuge and the clear solution was eluted via a column containing neutral alumina. The lithium salt was extracted from the eluent with 4x75 ml of water.
Aqueous fraction was washed with 3x1 00 ml of hexanes and water was distilled off. The solid was dried under vacuum at 150 C to give 38.6 g of white powder, having an average composition Li2B12F9H3 and having undetectable by NMR or lR levels of hydroxyl-derivatives of fluoroborate anions (< 1000 ppm). Alumina column was washed with 600 ml of water, water was distilled off and the residue was dried under vacuum at 150 C to give 5.8 g of tan solid, which was mostly lithium salt with average composition Li2B12F9H2(OH). Thus, using this method lithium fluorododecaborate salts can be purified from the fluorinated hydroxyl derivatives.
Example 8 Purification of L12B12F12 from Li2B12F11(OH) [0052] In this example 100.8 g of crude Li2B12F12, containing - 1 mol. % of Li2B12F11(OH), was dissolved in 400 ml of 5-methyl-2-hexanone. The small amount of insoluble material was removed on the centrifuge and the clear solution was eluted via a column containing neutral alumina. The compound Li2Bt2Fi2 was extracted from the eluent with 4x125 ml of water. Aqueous fraction was washed with 3x100 ml of hexanes and water was distilled off. The solid was dried under vacuum at 200 C to give 87 g of white Li2B12F12, which had non-detectable levels (by NMR or 1R) of Li2B12F11(OH) (note that in a separate experiment, - 0.02 mol.% of Li2B12F11(OH) (- 200 ppm) were detected in Li2B12F12 by NMR using the difference in 19F NMR spectra of these two compounds).
Thus, using this method Li2B12F12 containing < 200 ppm of hydroxyl-derivatives of fluorododecaborate anions (< - 10 ppm of hydroxyl group) can be prepared.
Example 9 Purification of Li2B12F12 from Sodium and Potassium.
Example 10 Thermal Gravimetric Analysis(TGA)/IR of Li2B12F12 [0054] TGA/IR analyses were performed on Li2B12F12 by ramping the sample in the TA
2960 SDT by heating from RT to 800 C at 10 C/min. in 100 cc/min. of N2, H2O
saturated N2 or air. The evolved gas is passed through a 10 cm IR gas cell.
The IR
spectrum is collected at 4 cm-1 resolution and a gain of 1 on the AVATAR IR.
The spectra are collected as a series of spectra at 1-minute intervals. Profiles of the evolved gases were prepared by measuring the absorbance for different compounds at the band maximum in the IR spectra. The quantitative information was derived by multiplying the area under the profile curve by the calibration factor and dividing by the sample weight.
The IR profiles shown in Figure 1 show that under N2 purge most of the water comes off this sample at -190 C, and it is still being removed at 225 C. Final water removal at or below 180 C will proceed relatively slowly.
Comparative Example 11 Vacuum Drying of Li2B12F,,Z12.,, Salts [0055] Approximately 200 g Li2B12F12 salt prepared according to example 1 was ground and dried under a dynamic vacuum of 30 mTorr for 8 hrs at 250 C. The sample was transferred to an argon-filled inert atmosphere dry-box. Moisture analysis of our salt was carried out on an Orion AF7 Coulometeric Karl - Fischer Titrator. HydranalTM
Karl-Fischer reagents and standards from Riedel-de Haen were used. - 0.60g Li2B12F12 was dissolved in 3 ml dry acetonitrile and 3-1 mL were taken for water analysis.
After this drying procedure water values of - 100 ppm on a salt weight basis were obtained.
Vacuum drying in this manner typically gave water readings of 100-500 ppm.
Example 12 Drying of Li2B12FXZ12_x in a Fluidized Bed (0056] Approximately 100 g Li2B12F12 salt prepared according to example 1 was ground and dried under a dynamic vacuum of 100 mTorr at 150-200 C for 4 hrs. The sample was further ground and loaded on to a quartz frit in a vertical glass tube.
The tube was externally heated to 260 C and dry nitrogen was purged through the salt at a sufficient rate to fluidize the bed of salt. After 12 hrs the sample was cooled and transferred to an argon filled inert atmosphere box for analysis of water content. Karl-Fischer analysis performed as in example 7 showed the salt contained 10-20 ppm water on a salt weight basis.
Example 13 Drying of Electrolyte Solution Comprising a Combination of Li2B12F12 in 1:1 Ethylene carbonate (EC):Diethylene carbonate (DEC) [0057] Approximately 100 g of a solution comprising - 10 g Li2B12F12 salt, prepared according to example 1, combined with - 90 g of a 50:50 weight % mixture of EC
and DEC was measured to have a water content > 100 ppm. The solution was stored over dry 4A molecular sieves for 4 hrs and then decanted on to fresh, dry 4A
molecular sieves for an additional 8 hrs. After filtration the solution was found to contain between 5-15 ppm water by Karl-Fischer analysis. 19F NMR showed no evidence of hydrolysis of the B12F122" anion Comparative Example 14 Drying of Electrolyte Solution Comprising a Combination of mixtures of Li2B12F12 and LiPF6 in 1:1 Ethylene carbonate (EC):Diethylene carbonate (DEC) [0058] When an attempt was made to dry a solution comprising a mixture of 9 wt. %
L12B12F12 and 1 wt. % LiPF6 in combination with EC:DEC by the method of example 12, hydrolysis of the PF6 anion to P02F2 and HF was observed by 19F NMR, while no evidence of B121712 2- hydrolysis was observed.
Example 15 Determination of Oxidative and Reductive Stability and Decomposition Temperature of Lithium Electrolyte Solutions for Use in Lithium Secondary Batteries [0059] To assess the oxidative stability of substituted dodecaborates as battery electrolytes, and the impact of OH containing impurities, cyclic voltammetry (CV) experiments were performed using CH Instruments potentiostat and a conventional three-electrode cell under laboratory atmosphere. Two solutions each containing 0.4 M
Li2B12F12 salt were prepared using EC:DEC (3:7) solvents. The salt used in one of the solutions contained > 100 ppm water and the salt used in the second solution contained < 20 ppm water as an impurity (and were produced in accordance with Example 12.
Cyclic voltammetry was carried out to evaluate the oxidation characteristics of the two salt solutions. The working electrode was Pt (1.6 mm diameter). The reference and the counter electrodes were both lithium foils. The scan rate was 20 mV/s.
Example 16 Purification of K2B12FxZ,2_x from K2B12FxZy(OH)12_x-y [0061] In this example 12.5 g of 20 wt % solution of potassium salt in acetonitrile having an average composition K2B12F11H, and also containing - 2,000 ppm of K2B12F11H(OH) (as determined by liquid chromatography method), was agitated with 4.0 g of activated neutral aluminum oxide (powder, -150 mesh) for 16 hours.
Alumina was filtered out and liquid chromatography analysis indicated that purified solution contained less than - 10 ppm of hydroxyl-substituted clusters.
Example 17 Purification of K2B,2FxZ,2_x from K2B12FxZy(OH)12_x_y [0062] In this example 12.5 g of 20 wt % solution of potassium salt in acetonitrile having an average composition K2B12F11H, and also containing - 2,000 ppm of K2B12F11H(OH) (as determined by liquid chromatography method), was agitated with 4.0 g of activated granular basic aluminum oxide (1 mm beads) for 16 hours.
Alumina was filtered out and liquid chromatography analysis indicated that purified solution contained less than - 10 ppm of hydroxyl-substituted clusters.
Example 18 Purification of K2B12FXZ12.X from K2B12FXZy(OH)12_x.y [0063] In this example 12.5 g of 20 wt % solution of potassium salt in acetonitrile having an average composition K2B12F11H, and also containing - 2,000 ppm of K2B12F11H(OH) (as determined by liquid chromatography method), was agitated with 4.0 g of titanium oxide for 16 hours. Titanium oxide was filtered out and liquid chromatography analysis indicated that purified solution contained less than -10 ppm of hydroxyl-substituted clusters.
Claims (5)
a) dissolving the material in at least one organic solvent to form a solution and passing said solution through an adsorbent, b) dissolving the material in at least one solvent to form a solution, and passing said solution through a cation exchange medium, c) drying the material at a temperature and under conditions sufficient to volatize the impurity, d) dissolving the material in at least one aprotic organic solvent to form a solution and passing said solution through a sieve, wherein the material comprises K2B12F x Z12-x wherein Z is at least one member selected from the group consisting of H, Cl and Br.
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| US11/710,116 US7981388B2 (en) | 2004-08-23 | 2007-02-23 | Process for the purification of lithium salts |
| US11/710,116 | 2007-02-23 |
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| KR101046107B1 (en) | 2011-07-01 |
| US20070189946A1 (en) | 2007-08-16 |
| EP1964813A3 (en) | 2010-04-07 |
| CA2621794A1 (en) | 2008-08-23 |
| US7981388B2 (en) | 2011-07-19 |
| TWI427036B (en) | 2014-02-21 |
| KR20080078605A (en) | 2008-08-27 |
| TW200846285A (en) | 2008-12-01 |
| JP2008251528A (en) | 2008-10-16 |
| JP2011198771A (en) | 2011-10-06 |
| EP1964813A2 (en) | 2008-09-03 |
| CN101304102A (en) | 2008-11-12 |
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