This invention relates to a lithium cobalt-based oxide (LCO) cathode active material powder for lithium-ion secondary batteries (LIBs) suitable for portable electronic device applications.
As the functionalities and performances of portable electronic devices are constantly improving, LIBs having a higher volumetric energy density are required.
The volumetric energy density of a cathode active material powder is obtained according to a following equation:
Volumetric energy density (mAh/cm3)=volumetric capacity (mAh/cm3)×Charge cutoff voltage (V),
, wherein:
A higher charge cutoff voltage (such as superior or equal to 4.5V vs. Li+/Li reference potential) leads to a significant increase of the volumetric energy density of a cathode material powder.
It is therefore an object of the present invention to provide a lithium cobalt-based oxide cathode active material powder for lithium-ion secondary batteries, having an improved volumetric capacity of at least 570 mAh/cm3 obtained by the analytical methods of the present invention.
In addition to the improved volumetric capacity, the LCO cathode active material compound according to the present invention must have a sufficient structural stability at a voltage superior or equal to 4.5V so far. Such a sufficient stability is indicated by a specific floating capacity of at most 80 mAh/g (obtained by the analytical methods of the present invention) during the use of the cathode active material powder in a LIB.
This objective is achieved by providing a lithium cobalt-based oxide cathode active material powder according to claim 1.
It is indeed observed that an improved volumetric capacity of higher than 570 mAh/cm3 and a specific floating capacity of lower than 80 mAh/g, as illustrated in the results provided in Table 2, are achieved with a battery using a LCO cathode material powder according to EX1, having the following features:
The cathode active material powder comprises particles having an Al to (Co+Al+M′+Me) molar ratio (x) inferior or equal to 0.050 so as to minimize a capacity loss, and superior or equal to 0.002 so as to stabilize a crystal-structure of the LCO cathode active material powder during cycling.
The cathode active material powder comprises particles having a Li to (Co+Al+M′+Me) molar ratio (1+a) superior or equal to 0.99 and inferior or equal to 1.01, preferably superior or equal to 0.995 and inferior or equal to 1.005.
If the ratio 1+a is less than 0.99 (a<−0.01), a Co dissolution at a higher voltage such as 4.50V occurs since there is no enough Li to hold the cobalt atoms in the structure of the cathode active material particles and the capacity of the cathode active material powder decreases. If the ratio 1+a is more than 1.01 (a>0.01), the cycle life of the cathode active material powder deteriorates.
In the framework of the present invention, the D50 is the volumetric median particle size and is superior or equal to 20.00 μm, preferably 25.00 μm, and inferior or equal to 45 μm. Preferably, the cathode active material powder according to the present invention has a D50 superior or equal to 30.00 μm and inferior or equal to 40.00 μm.
Due a larger D50 of the LCO cathode active material powder according to the invention, in comparison with conventional D50 values (less than 20.00 μm) for this type of cathode active material, the claimed LCO cathode active material powder shows packing density values which are much higher than the conventional ones. The D50 should however be less than 45.00 μm, because surface scratching of the cathode during its preparation from the LCO cathode active material powder is observed for D50 values higher than this upper limit.
The present invention concerns the following embodiments:
In a first aspect, the present invention concerns a lithium cobalt-based oxide cathode active material powder, which comprises particles having a median particle size D50 of superior or equal or superior to 20.00 μm+/−1.00 μm, preferably 25.00 μm+/−1.00 μm, and inferior or equal to 45.00 μm+/−1.00 μm, said particles having an averaged circularity of superior or equal to 0.85 and inferior or equal to 1.00, said particles having a general formula Li1+aCo1−x−y−zAlxM′yMezO2, wherein M′ and Me comprise at least one element of the group consisting of: Ni, Mn, Nb, Ti, W, Zr, and Mg, with −0.01≤a≤0.01, 0.002≤x≤0.050, 0≤y≤0.020 and 0≤z≤0.050, said lithium cobalt-based oxide active material powder being obtained by a process comprising the steps of:
Preferably, y and z=0.
In the Embodiment 1 according to the invention, the D50 value and the averaged circularity value of the particles of the intermediate powder (or the first sintered agglomerated powder after milling and screening—step c.) are similar to the D50 value and the averaged circularity values of the particles of the lithium cobalt-based oxide cathode active material powder according to the invention.
The D50 is a volumetric-based value (see section 1.1 below) expressed in μm+/−0.01 μm.
The averaged circularity is a number-based value (see section 1.7 below).
Preferably, the cathode active material powder of the Embodiment 1 has a press density superior or equal to 3.95 g/cm3 and inferior or equal to 4.40 g/cm3.
More preferably, the cathode active material powder according to the Embodiment 1 or 2 has a volumetric capacity of at least 570 mAh/cm3, preferably of at most 700 mAh/cm3.
In a fourth Embodiment, the cathode active material powder according to any of the preceding Embodiments, wherein said particles have an averaged circularity of superior or equal to 0.90 and inferior or equal to 1.00, preferably of superior or equal to 0.95 and inferior or equal to 1.00, more preferably of superior or equal to 0.85 and inferior or equal to 0.95, most preferably of superior or equal to 0.90 and inferior or equal to 0.95.
In said fourth Embodiment, the intermediate powder has particles having an averaged circularity of superior or equal to 0.90 and inferior or equal to 1.00, preferably of superior or equal to 0.95 and inferior or equal to 1.00, more preferably of superior or equal to 0.85 and inferior or equal to 0.95, most preferably of superior or equal to 0.90 and inferior or equal to 0.95.
Preferably, in a fifth Embodiment according to any of the preceding Embodiments, the first Co-bearing precursor has a D50 superior or equal to 20.00 μm+/−1.00 μm, preferably 25.00 μm+/−1.00 μm, and inferior or equal to 45 μm+/−1.00 μm.
More preferably, the first Co-bearing precursor has a D50 superior or equal to 35.00 μm+/−1.00 μm, and inferior or equal to 45.00 μm+/−1.00 μm, so that the lithium cobalt-based oxide cathode active material powder comprises particles having a median particle size D50 of superior or equal to 35.00 μm+/−1.00 μm, and inferior or equal to 45.00 μm+/−1.00 μm.
If the D50 of the first Co-bearing precursor is inferior to 20.00 μm+/−1.00 μm, it is required to increase the Li to (Co+Al+M′) molar ratio of the second mixture or to sinter said second mixture at a temperature superior to 1100° C.
Optionally, the first Co-bearing precursor contains Al and M′.
Preferably, the second Co-bearing precursor has a D50 inferior to 10.00 μm, more preferably inferior to 5.00 μm to maximize the volumetric density of the second cathode active material according to the Embodiment 1.
Li sources can be either one or more of Li2O, LiOH, LiOH.H2O, Li2CO3, and LiNO3.
Co-bearing precursors can be either one or more of CoOz, CoCO3, CoO(OH), and Co(OH)2.
Preferably, in a sixth Embodiment according to any of the preceding Embodiments, the first sintering step is performed during a period of at least 3 hours and at most 20 hours.
Preferably, in a seventh Embodiment according to any of the preceding
Embodiments, the second sintering step is performed during a period of at least 1 hour and at most 20 hours.
The invention is further illustrated in the following examples:
1.1. Particle Size distribution
The D50 is an indicator of a powder particle size distribution (hereafter referred to as psd) and is obtained by a laser psd measurement method. In this invention, the laser psd is measured by using a Malvern Mastersizer 2000 with Hydro 2000MU wet dispersion accessory, e.g. after having dispersed the powder in an aqueous medium. In order to improve the dispersion of the powder in the aqueous medium, sufficient ultrasonic irradiation and stirring are applied and an appropriate surfactant is introduced in the aqueous medium.
If the powder according to the invention has a multimodal psd profile, then said multimodal profile is deconvoluted, then if one or several deconvoluted modes having a D50 comprised in the 20.00 μm, preferably 25.00 μm, and 45.00 μm range are identified, said powder has a D50 according to claim1.
If the powder according to the present invention has a monomodal psd profile with a single mode having a D50 comprised in the in the 20.00 μm, preferably 25.00 μm, and 45.00 μm range, said powder has therefore a D50 according to claim1.
1.2. Pressed Density
The pressed density (PD) is measured according to the following procedure: 3 grams of a LCO cathode active material powder is filled into a pellet die with a diameter “d” of 1.3 cm. A pressure of 207 MPa is applied for 30 seconds. After relaxing the load, the thickness “t” of the pressed LCO cathode active material powder is measured. The pressed density PD is 3 g divided by the volume of the pressed powder (π×(d/2)2×t).
1.3. Inductively Coupled Plasma
The inductively coupled plasma (ICP) method is used to measure the content of elements such as Li, Co, and Al by using an Agillent ICP 720-ES device.
2 g of a powder sample is dissolved in 10 mL high purity hydrochloric acid in an Erlenmeyer flask. The flask is covered by a glass and heated on a hot plate until complete dissolution of the precursor is achieved. After being cooled to the room temperature, the solution is moved to a 100 mL volumetric flask. After having filled the flask with the solution, the volumetric flask is filled with deionized water up to the 100 mL mark. 5 mL of the resulting solution is transferred into a 50 mL volumetric flask for a 2nd dilution, where the volumetric flask is filled with 10% hydrochloric acid up to the 50 mL mark and then homogenized. Finally, this 50 mL solution is used in the ICP measurement.
1.4. High Angular Resolution Synchrotron X-Ray Diffraction
High angular resolution synchrotron powder x-ray diffraction (SXRD) is carried out on the BL04-MSPD beamline of the ALBA synchrotron (Cerdanyola del Vallès, Spain). All powders were packed in 0.5 mm diameter capillaries. The typical 20 angular range was from 0° to 70° with 0.006° angular step and 3 minutes accumulation time. The patterns were recorded in a Debye-Scherrer geometry with a wavelength of λ=0.825Å+/−0.010Å.
1.5. Crystallographic Characterization
Inorganic Crystal Structure Database (ICSD, provided by FIZ Karlsruhe and the U.S. Secretary of Commerce) contains information on all inorganic crystal-structures published since 1913. peak positions in the obtained diffraction pattern and the elements in a powder sample (e.g. Li, Co, O, Al) are searched in the ICSD so as to determine a crystal-structure of a power sample.
1.6. Electrochemical Analysis: Capacity and a Floating Test Analysis
1.6.1. Coin Cells Preparation
Coin cells that are used in a discharge capacity and floating test analysis are assembled according to the following steps:
Step 1) Preparation of a Cathode:
A slurry that contains the solids: a LCO cathode active material powder, a conductor (Super P, Timcal) and a binder (KF #9305, Kureha) in a weight ratio 90:5:5, and a solvent (NMP, Sigma-Aldrich) are mixed in a high speed homogenizer so as to obtain a homogenized slurry. The homogenized slurry is spread on one side of an aluminum foil using a doctor blade coater with a 230 μm gap. the slurry-coated aluminum foil is dried in an oven at 120° C., then pressed using a calendaring tool, and dried again in a vacuum oven to remove the solvent completely.
Step 2) Coin Cell Assembly:
A coin cell is assembled in a glovebox which is filled with an inert gas (argon). For the discharge capacity analysis, a separator (Celgard) is located between the cathode and a piece of lithium foil used as an anode. For the floating test, two pieces of separator are located between the cathode and an anode, which consists of graphite. 1M LiPF6 in EC:DMC (1:2 in volume) is used as electrolyte and dropped between separator and electrodes. Then, the coin cell is completely sealed to prevent leakage of electrolyte.
1.6.2. Discharge Capacity Analysis
The first charge and discharge capacity (CQ1 and DQ1) are measured by constant current mode with 0.1C rate, where 1C is defined as 160 mAh/g and charge cutoff voltage is 4.30V and discharge cutoff voltage is 3.0V. The volumetric discharge capacity DQ1V (mAh/cm3) is obtained according to multiplying DQ1 by PD.
1.6.3. Floating Test Analysis
The floating test analyses the crystal-stability of LCO compounds at a high voltage at an elevated temperature.
The prepared coin cell is tested according to the following charge protocol: the coin cell is first charged to 4.5V at constant current mode with C/20 rate (1C=160 mAh/g) in a 50° C. chamber. The coin cell is then kept at constant voltage (4.5V) for 5 days (120 hours), which is a very severe condition.
Once side reactions or metal dissolution happen, there will be a voltage drop. The electrochemical instrument will automatically compensate the (loss of) current to keep the voltage constant. Therefore, the recorded current is a measure of the ongoing side reactions during cycling.
The specific floating capacity (QF) is the total amount capacity (mAh/g) during the floating test. After the floating test, the coin cell is disassembled. The anode and the separator (localized close to the anode) are analyzed by ICP for a metal dissolution analysis. The measured cobalt content is normalized by the total amount of active material in the electrode so that a specific cobalt dissolution value (CoDis) is obtained.
1.7. Morphology Analysis
The morphology of a powder sample is analyzed with a Scanning Electron Microscopy (SEM) technique. The measurement is performed with a JEOL JSM-6000. An image of the powder sample is recorded with a magnification of 500 times to demonstrate the averaged circularity of the powder sample particles. In the SEM image, ten particles are selected and the circularity of these particles is calculated as follows:
, wherein A is an area of a particle, P is a perimeter of a particle, these parameters being obtained using an ImageJ software (reference is made to the Sections 30.2 to 30.7—“Set measurement” of the Image J User Guide version IJ 1.46r).
The averaged circularity according to the invention may be expressed as follows:
wherein n is the number of particles i analyzed according to the below-provided protocol. The averaged circularity is then a number-based average value.
A sufficient number of particles is at least 10 for a SEM image recorded with a magnification of 500 times. The at least 10 particles have a size of at least 20.00 μm.
As mentioned above, the calculation of the circularity implies the measurement of:
An averaged circularity of 1.00 means that the particles representative of a sample have a spherical shape.
An averaged circularity inferior to 1.00 means that the particles representative of a sample have a non-spherical shape.
An averaged circularity superior to 0 and inferior to 1 refers to an ellipsoidal shape.
The invention is further illustrated in the following examples:
A CoCO3 powder having a D50 of 38.00 μm and an Al2O3 powder are mixed so as to obtain a mixture having an Al to (Co+Al) molar ratio of 0.04 and the mixture is heated at 600° C. for 3 hours under a flow of air to prepare an Al coated Co oxide “CAO1”. The CAO1 powder and Li2CO3 are mixed so as to obtain a mixture having a Li to (Co+Al) molar ratio of 1.04 and the mixture is heated at 1000° C. for 10 hours under a flow of air. The sintered powder is grinded and named LCO1A-EX1 having a general formula of Li1.04Co0.96Al0.04O2 and a D50 of 37.00 μm.
LCO1B-EX1, which is prepared by a same procedure as LCO1A-EX1 except that the Li to (Co+Al) molar ratio is 1.06, has a general formula of Li1.06Co0.96Al0.04O2 and a D50 of 39.00 μm.
A Co3O4 powder having a D50 of 3.00 μm and Al2O3 powder are mixed so as to obtain a mixture having an Al to (Co+Al) molar ratio of 0.04, and the mixture is heated at 1000° C. for 10 hours under a flow of air to prepare an Al coated Co oxide “CAO2”.
LCO1A-EX1 and CAO2 are mixed to prepare EX1A having a general formula Li1.00Co0.96Al0.04O2. The mixture is heated at 980° C. for an hour under a flow of air. The sintered powder is grinded and named EX1A.
EX1B is prepared by a same procedure as EX1A except that LCO1B-EX1 is used instead of LCO1A-EX1.
EX1A and EX1B are according to the present invention.
CAO2 and Li2CO3 are mixed so as to obtain a mixture having an Al to (Co+Al) molar ratio of 1.00, and the mixture is heated at 1000° C. for 10 hours under a flow of air. The sintered powder is grinded and named LCO1A-CEX1 which has a general formula Li1.00Co0.96Al0.04O2 and a D50 of 4 μm.
LCO1B-CEX1, LCO1C-CEX1, and LCO1D-CEX1 are prepared by a same procedure as LCO1A-CEX1 except that the Li to (Co+Al) molar ratios in the mixture are 1.02, 1.04, and 1.06, respectively. The general formulas of LCO1B-CEX1, LCO1C-CEX1, and LCO1D-CEX1 are Li1.02Co0.96Al0.04O2, Li1.04Co0.96Al0.04O2, and Li1.06Co0.96Al0.04O2, respectively. The D50 of LCO1B-CEX1, LCO1C-CEX1, and LCO1D-CEX1 are 8 μm, 15 μm, 20 μm, respectively.
LCO1A-CEX1 is heated at 980° C. for an hour under a flow of air. The sintered powder is grinded and named CEX1A which has a general formula Li1.00Co0.96Al0.04O2.
LCO1B-CEX1 and CAO2 are mixed so as to obtain a mixture having Li to (Co+Al) molar ratio of 1.00. The mixture is heated at 980° C. for an hour under a flow of air. The sintered powder is grinded and named CEX1B having a general formula Li1.00Co0.96Al0.04O2.
CEX1C and CEX1D are prepared by a same procedure as CEX1B except that LCO1C-CEX1 and LCO1D-CEX1 are used instead of LCO1B-CEX1.
CEX1A, CEX1B, CEX1C, and CEX1D are not according to the present invention.
Table 1 shows the key preparation conditions of the LCO cathode active material powders according to Example 1 and Comparative example 1. EX1A and EX1B are prepared by the two sintering steps according to the method claimed in the present invention. The methods to prepare CEX1A and CEX1B are not according to the present invention because neither the D50 of Co precursor of LCO1 is superior to 20 μm nor the ratio 1+a′ is superior or equal to 1.03. The methods to prepare CEX1C and CEX1D are also not according to the present invention because the D50 of LCO1 is not superior to 20 μm.
Table 2 shows analytical results, obtained according to the analysis method described in the section 1.2. Pellet density, 1.6.2. discharge capacity analysis, 1.6.3. floating test analysis, and 1.4. cross-SEM Al EDX mapping analysis, of LCO compounds in Example 1, Comparative example 1, and Comparative example 2.
DQ1V corresponds the volumetric capacity of batteries. The parameters QF and CoDis are obtained by the floating test (cfr. section 1.6.3) and are indicators of the crystal-structural stability at a high voltage such as 4.50V or higher. QF and CoDis should be as low as possible.
EX1A and EX1B have lower QF and CoDis as well as higher DQ1V.
The present invention is covered by the following clauses:
1. A lithium cobalt-based oxide cathode active material powder, which comprises particles having a median particle size D50 of superior or equal to 20.00 μm+/−1.00 μm, preferably 25.00 μm+/−1.00 μm, and inferior or equal to 45.00 μm+/−1.00 μm, said particles having an averaged circularity of superior or equal to 0.85 and inferior or equal to 1.00, said particles having a general formula Li1+aCo1−x−y−zAlxM′yMezO2, wherein M′ and Me comprise at least one element of the group consisting of: Ni, Mn, Nb, Ti, W, Zr, and Mg, with −0.01≤a≤0.01, 0.002≤x≤0.050, 0≤y≤0.020 and 0≤z≤0.050, said lithium cobalt-based oxide active material powder being obtained by a process comprising the steps of:
2. The lithium cobalt-based oxide cathode active material powder according to clause 1, having a press density superior or equal to 3.95 g/cm3 and inferior or equal to 4.40 g/cm3.
3. The lithium cobalt-based oxide cathode active material powder according to clause 1 or 2, having a volumetric capacity of at least 570 mAh/cm3, preferably of at most 700 mAh/cm3.
4. The lithium cobalt-based oxide cathode active material powder according to according to any of the preceding clauses, wherein said particles have a R-3m crystal structure.
5. The lithium cobalt-based oxide cathode active material powder according to any of the preceding clauses, comprising particles having an averaged circularity of superior or equal to 0.90 and inferior or equal to 1.00, preferably inferior or equal to 0.95.
6. The lithium cobalt-based oxide cathode active material powder according to any of the preceding clauses, wherein y and z=0.
7. A lithium-ion secondary batteries comprising the lithium cobalt-based oxide cathode active material powder according to any of the preceding clauses.
Number | Date | Country | Kind |
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PCT/IB2019/056282 | Jul 2019 | IB | international |
PCT/IB2019/056284 | Jul 2019 | IB | international |
This application claims priority to U.S. Provisional Application No. 62/877,364, filed Jul. 23, 2019; International Application No. PCT/IB2019/056282, filed Jul. 23, 2019; and International Application No. PCT/IB2019/056284, filed Jul. 23, 2019. The entire contents of each are incorporated by reference herein.
Number | Date | Country | |
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62877364 | Jul 2019 | US |