The invention relates to a method of manufacture of a compound of formula LiM1-x-y-zNyQzFexPO4, and the compound thus obtained.
It also relates to a method of manufacture of a composite material comprising this compound and carbon, the composite material thus obtained, as well as an electrode comprising this composite material, and a lithium battery comprising said electrode.
Lithium batteries comprise at least two electrodes based on different active materials, and an electrolyte through which the Li+ cations are able to migrate from one electrode to the other depending on the manner of use. These lithium batteries are being used increasingly as autonomous energy sources, especially in portable equipment, where they are gradually replacing nickel-cadmium (Ni—Cd) and nickel-metal hydride (Ni-MH) batteries. For some years now, sales of Li-ion batteries have exceeded those of Ni-MH and Ni—Cd batteries. This development is explained by the continuous improvement in the performance of lithium batteries, thus endowing them with energy densities per unit mass and per unit volume far higher than those offered by the Ni—Cd and Ni-MH types. Whereas the first Li-ion batteries had an energy density of about 85 Wh/kg, nearly 200 Wh/kg can now be obtained (energy density referred to the mass of the complete Li-ion cell). For comparison, Ni-MH batteries peak at 100 Wh/kg and Ni-Cd batteries have an energy density of the order of 50 Wh/kg. The new generations of lithium batteries are already under development for ever more diversified applications (hybrid or all-electric cars, storing the energy from photovoltaic cells, etc.).
The active compounds of electrodes used in commercial batteries are, for the positive electrode, lamellar compounds such as LiCoO2, LiNiO2 and the mixed compounds Li(Ni, Co, Mn, Al)O2 or compounds of spinel structure with a composition close to LiMn2O4. The negative electrode is generally of carbon (graphite, coke, etc.) or optionally the compound of spinel structure Li4Ti5O12 or a metal forming an alloy with lithium (Sn, Si, etc.). The theoretical and practical specific capacities of the positive electrode compounds mentioned are about 275 mAh/g and 140 mAh/g respectively for the oxides of lamellar structure (LiCoO2 and LiNiO2) and 148 mAh/g and 120 mAh/g for spinel LiMn2O4. In all cases, an operating potential relative to metallic lithium close to 4 Volts is obtained.
Since the emergence of lithium batteries, several generations of positive electrode materials have successively made their appearance. The concept of insertion/extraction of lithium into/from the electrode materials was extended a few years ago to the three-dimensional structures constructed from polyanionic entities of the type XOnm− (X═P, S, Mo, W . . . ; 2≦n≦4; 2≦m≦4). Moreover, there is now keen interest in the lithium-containing metal phosphates with crystallographic structure of the olivine type and of general formula LiMPO4 (M=Fe, Mn, Co, Ni).
Among the four compounds of formula LiMPO4, only lithium iron phosphate LiFePO4 is currently capable of meeting expectations experimentally, bearing in mind a practical capacity that is now close to the theoretical value; namely 170 mAh/g. Nevertheless, this compound, stressing the electrochemical couple Fe3+/Fe2+, operates at 3.4 V vs. Li+/Li. This rather low potential leads at the maximum to an energy density per unit mass of 580 Wh/kg of LiFePO4. However, it is known that the phosphates of manganese, of cobalt and of nickel, isotypes of LiFePO4, have higher potentials of lithium ion extraction/insertion, respectively 4.1 V, 4.8 V and 5.1 V vs. Li+/Li. The theoretical specific capacities of these three compounds are close to that of LiFePO4.
The formation of a mixed compound of formula LiM1−xFexPO4 (0≦x≦1) obtained by substitution of the iron with transition metals of the type Mn, Co and Ni offers new perspectives. Such materials are promising as they have higher operating potentials than lithium iron phosphate while retaining equivalent theoretical specific capacities. Conversely, from an experimental standpoint, important progress still needs to be made in order to reach satisfactory values of practical specific capacities.
To summarize, to meet the ever increasing demands for energy (per unit of mass and/or of volume), new materials of electrodes of Li-ion batteries giving even better performance are indispensable.
The invention aims to solve this problem by proposing a method of synthesis of compounds of the lithium-containing mixed phosphate type having a particular morphology permitting improved conductivity, low electrochemical polarization and a high specific capacity, which can be used as electrode material, in particular positive, in commercial lithium batteries.
The method of synthesis of the invention is a rapid method that is implemented at low temperature.
For this purpose, the invention proposes a method of manufacture of a compound of the following formula I:
LiM1-x-y-zNyQzFexPO4 formula I
in which:
a) mixing the precursors of Li, M, N, Fe, P and ascorbic acid in an aqueous solvent preferably containing a glycol compound,
b) microwave heating of the mixture obtained in step a) at a temperature between 100 and 300° C., preferably at a temperature of 160° C. and at a pressure between 0.5 and 50 bar, preferably a pressure of 3 bar, for a time between 1 and 60 minutes, preferably for 30 minutes, and
c) washings of the product obtained in step b) with ethanol and water.
Preferably, these washings consist of one washing with ethanol, followed by two washings with water.
In the compound of formula I, the doping element N is preferably boron or aluminium or mixtures of boron and aluminium.
Preferably, in step a), the glycol compound is ethylene glycol and/or diethylene glycol and/or triethylene glycol and/or tetraethylene glycol.
Preferably, in step a), the aqueous solvent comprises a glycol compound and the volume ratio of water to glycol compound is between 9 and 1/9, and is preferably equal to 1/4.
Also preferably, in step a), the amount of ascorbic acid is between 0.01% and 0.5 wt %, relative to the amount of Fe.
Still preferably, in step a), the precursor of Li is selected from a lithium hydroxide, acetate, nitrate, chloride, hydrogen phosphate, and is preferably lithium hydroxide monohydrate.
Also preferably, in step a), the precursors of Mn, Fe, Ni and Co are selected from a sulphate, an acetate, an oxalate, a chloride, a hydroxide and a nitrate of Mn, Fe, Ni and Co respectively; preferably the precursor of Fe is iron sulphate heptahydrate (FeSO4.7H2O), the precursor of manganese is manganese sulphate monohydrate (MnSO4.H2O), the precursor of Ni is nickel sulphate hexahydrate, and the precursor of Co is cobalt sulphate heptahydrate.
Also preferably, in step a), the precursor of phosphorus is selected from phosphoric acid (H3PO4), diammonium hydrogen phosphate ((NH4)2HPO4), ammonium dihydrogen phosphate (NH4H2PO4), and is preferably phosphoric acid (H3PO4).
In a preferred embodiment, in step a), the precursors of M, N, Q, Fe and P are mixed in the desired stoichiometric amounts of M, N, Q, Fe and P in the final compound of formula I and the precursor of Li in an amount of Li greater than the desired stoichiometric amount of Li in the final compound of formula I.
Preferably, an amount of Li corresponding to 3 equivalents, in moles, will be used, to obtain one equivalent in mole of Li in the final compound of formula I.
The invention also proposes a method of manufacture of a composite material of the following formula II:
C—LiM1-x-y-zNyQzFexPO4 formula II
in which:
a) mixing the precursors of Li, M, N, Fe, P and ascorbic acid in an aqueous solvent preferably containing a glycol compound,
b) microwave heating of the mixture obtained in step a) at a temperature between 100 and 300° C., preferably at a temperature of 160° C. and at a pressure between 0.5 and 50 bar, preferably a pressure of 3 bar, for a time between 1 and 60 minutes, preferably for 30 minutes,
c) washings of the product obtained in step b) with ethanol and water, and
d) mixing the compound of formula I obtained in step c) with carbon powder having a specific surface greater than 700 m2/g.
In formula II, as in formula I, the doping element N is preferably boron or aluminium or mixtures thereof.
In step a), the glycol compound is preferably ethylene glycol and/or diethylene glycol and/or triethylene glycol and/or tetraethylene glycol.
The invention also proposes an electrode, characterized in that it comprises a composite material of formula I and/or of formula II obtained by the methods according to the invention.
The invention further proposes a Li-ion battery, characterized in that it comprises an electrode according to the invention.
The invention also proposes a compound of the following formula I:
LiM1-x-y-zNyQzFexPO4 formula I
in which:
The invention finally proposes a composite material of the following formula II:
C—LiM1-x-y-zNyQzFexPO4 formula II
in which:
Preferably, in the compound of formula I, as in the compound of formula II, the doping element N is aluminium or boron or mixtures thereof.
The invention will be better understood and other features and advantages of the invention will become clearer on reading the explanatory description which follows and which refers to the figures in which:
The invention aims to provide a method of manufacture of materials for the positive electrode for a lithium battery, in particular.
These materials are of the type LiM1−xFexPO4 (M=Co, Ni, Mn with 0≦x≦1). In particular, the mixed phosphate of manganese and iron of formula LiMn1−xFexPO4, and of olivine structure, is of considerable interest as the active material of a positive electrode on account of its operating potential that is relatively high, but is still compatible with conventional electrolytes. The potential is between 3.4 V (LiFePO4) and 4.1 V (LiMnPO4) vs. Li+/Li associated with a theoretical specific capacity of the order of 170 mAh/g. From a theoretical standpoint, this compound thus has a higher energy density than most of the known electrode materials (up to 700 Wh/kg).
Nevertheless, the practical capacities of the compounds LiMn1−xFexPO4 reported in the literature are still below the expected theoretical values. Moreover, it has not been clearly determined what ratio of manganese and iron would be optimum in these materials in terms of electrochemical performance, and to what extent the mixed compounds LiMn1−xFexPO4 are stable as cathodes in Li-ion batteries. As the redox potential of the Fe2+/Fe3+ couple in the compounds of olivine structure is 600-700 mV lower than for the Mn2+/Mn3+ couple, it is important to optimize the Mn/Fe ratio in LiMn1−xFexPO4 to ensure maximum capacity in the highest range of potential. It is a question of advantageously combining the qualities of the LiFePO4/FePO4 couple (better electronic and ionic conductivity) and LiMnPO4/MnO4 couple (higher energy density).
A specific method of synthesis giving a lithium-containing carbon/mixed phosphate composite [C—LiMn1−xFexPO4] of particular morphology permitting improved conductivity, low electrochemical polarization and a high specific capacity, is indispensable for really envisaging the future use of this material in commercial lithium batteries.
For this purpose, the invention proposes a method of manufacture of a compound of the following formula I:
LiM1-x-y-zNyQzFexPO4 formula I
in which:
C—LiM1-x-y-zNyQzFexPO4 formula II
in which:
Preferably, in the compound of formula I, 0<x+y+z<1, 2≦x≦0.6 and z=0.
The method of synthesis of the compound of formula I is microwave-assisted solvothermal synthesis.
This method comprises the following steps:
a) mixing the precursors of Li, M, N, Fe, P and ascorbic acid in an aqueous solvent preferably containing a glycol compound, such as ethylene glycol, and/or diethylene glycol, and/or triethylene glycol, and/or tetraethylene glycol,
b) microwave heating of the mixture obtained in step a) at a temperature between 100 and 300° C., preferably at a temperature of 160° C. and at a pressure between 0.5 and 50 bar, preferably a pressure of 3 bar, for a time between 1 and 60 minutes, preferably for 30 min, and
c) washings of the product obtained in step b) with ethanol and water.
The compounds that can be obtained by this method can be LiFePO4, a compound of the type LiM1−xFexPO4 where M represents a transition element selected from Co, Ni, Mn and Fe.
It is also possible to synthesize, by the method of the invention, a compound containing two transition elements, i.e. a compound of the type Li1-x-zNyQz, NyFexPO4 where M and N are selected from Co, Ni, Mn and Fe but are different from one another.
It is thus possible to obtain for example a compound of the type LiMm1-x-zNizFexPO4.
However, as is well known by a person skilled in the art, these compounds can in addition be doped with any element of the periodic table that is, of course, different from M, Q and Fe.
In particular, the doping element can be boron or aluminium or mixtures thereof.
N can also represent a vacancy on the site of the lithium, of M, of Q, of the phosphorus or of the oxygen. In fact, a vacancy on a site of the oxygen can improve the diffusion of the lithium ions.
Regarding a doping element, it is present in a very small amount in the compound of the invention, i.e. at a value below 15 mol %.
Various lithium precursors can be used such as a lithium hydroxide, in particular lithium hydroxide monohydrate LiOH.H2O, a lithium acetate such as LiOAc.2H2O, a lithium chloride LiCl, a lithium nitrate LiNO3, or else a lithium hydrogen phosphate LiH2PO4.
Preferably, in the method of the invention, lithium hydroxide monohydrate is used.
Various precursors of manganese, of iron, of nickel and of cobalt can also be used, such as a sulphate, an acetate, an oxalate, a chloride, a hydroxide or a nitrate of these compounds.
Thus, for manganese, precursors of formulae Mn0Ac2.4H2O, MnSO4.H2O, MnCl2, MnCO3, MnNO3.4H2O, Mnx(PO4)y.H2O in which x is between 1 and 5 and y is between 1 and 10, Mn(OH)z in which z is between 2 and 4, can be used. Preferably, a precursor of manganese that is manganese sulphate monohydrate MnSO4.H2O will be used.
Iron sulphate heptahydrate (FeSO4.7H2O) is preferably used as precursor of iron.
Nickel sulphate hexahydrate will preferably be used as precursor of nickel, and cobalt sulphate heptahydrate as precursor of cobalt.
As precursor of phosphorus, it will be possible to use phosphoric acid, ammonium mono- and dihydrogen phosphate and even lithium hydrogen phosphate.
Preferably, phosphoric acid will be used.
In the prior art, the syntheses of the compounds of formula I were carried out in the solid at high temperature, i.e. at a temperature greater than or equal to 600° C., such temperatures being necessary to permit decomposition of the precursors of lithium, of manganese, and of phosphorus, the complete reaction of formation of the compound as well as total evaporation of the volatile species.
However, although it is difficult to prepare the electrochemically active compound of formula I at low temperature, the inventors discovered that synthesis at low temperature was necessary in order to limit excessive growth of the particles or the formation of agglomerates as far as possible.
Thus, the method of the invention uses a method of synthesis in solution at a temperature between 100 and 300° C., at a pressure between 0.5 and 50 bar for a time of less than 60 minutes, preferably a time of 30 minutes, and synthesis is preferably carried out at a temperature of 160° C. at a pressure of 3 bar for 30 minutes.
This synthesis is carried out in a microwave-heated reactor.
The power of the microwave oven is fixed as a function of the mass of the sample to be treated, but the temperature of the reaction mixture is maintained in the temperature range and for a duration and at a pressure as defined above.
The reaction takes place in an aqueous solvent, which can consist of water only, but which preferably contains a glycol compound.
As glycol compound that can be used, we may mention ethylene glycol, diethylene glycol, triethylene glycol and tetraethylene glycol, and mixtures thereof.
However, diethylene glycol has proved particularly suitable.
The reaction mixture in step a) comprises ascorbic acid in order to prevent oxidation of the iron (II) ions.
Between 0.01 wt % and 0.5 wt % of ascorbic acid, relative to the amount of iron, is used.
To remove the solvent and the unwanted species such as the sulphates and hydroxides derived from the precursors, the product obtained after step b) is simply washed with ethanol and with water and then dried in a stove under air at about 50-60° C. One washing with ethanol followed by two washings with water has proved sufficient.
Thus, in contrast to the synthesis in the solid used in the prior art for synthesizing this type of compound, there is no evaporation of the unwanted species and solvents in an oven at high temperature.
Owing to the presence of PO43−, P2O74−, and PO3− groups, the compounds of formula I are relatively insulating from an electronic standpoint. That is why deposition of carbon in situ (during synthesis) or ex situ (post-treatment step) on the surface of the particles of the compounds of formula I is necessary for obtaining good electrical performance. Carbon makes it possible to increase the electronic conductivity but also to limit agglomeration of the particles under the effect of the synthesis temperature. In the prior art, this deposition of carbon is generally carried out by thermal decomposition of an organic substance under reducing atmosphere simultaneously with the synthesis of the compound of formula I.
Once again, to limit the temperatures of synthesis of the composite of the invention, the invention proposes synthesizing a composite material of the following formula II:
C—LiM1-x-y-zNyQzFexPO4 formula II
in which:
Preferably, in the compound of formula II, 0<x+y+z<1, 2≦x≦0.6 and z=0.
Thus, the reaction of formation proper of the composite material of formula II takes place during the mixing of the compound of formula I and carbon. Mixing is carried out, for example, by grinding in a 50-ml agate bowl containing 20 agate balls of 1 cm diameter rotating at 500 rev/min for 4 h.
It is preferable to use a high proportion of carbon relative to the compound of formula I.
Preferably from 5 to 20 wt % of carbon with high specific surface will be used, relative to the weight of the compound of formula I, more preferably 15 wt %.
Manganese phosphate, LiMn1−xFexPO4, crystallizes in the Pnma space group. This compound is of an olivine type of structure. The latter consists of a compact hexagonal stack of oxygen atoms. The lithium ions, manganese ions and the iron ions are localized in half of the octahedral sites whereas phosphorus occupies ⅛ of the tetrahedral sites. A simplified representation of the structure of LiMm1−xFexPO4 is presented in the insert of
The particles of the compound of formula I obtained by the method of the invention have little or no agglomeration together, as shown in
Moreover, the method of synthesis of the compounds of formula I of the invention at low temperature leads to a smoothed morphology of the particles, which are of nanometric size, i.e. as can be seen in
The composite material of formula II obtained from the compounds of formula I prepared according to the method of the invention has a quite different morphology: the carbon served for coating the particles, and as shown in
The compounds of formula I obtained by the method of the invention have a high specific surface, greater than or equal to 15 m2/g.
As the carbon used for obtaining the composite material of the invention has a specific surface preferably greater than 700 m2/g, the specific surface of the composite material obtained with the compounds of formula I of the invention, and by the method of the invention, have a specific surface greater than or equal to 80 m2/g.
The specific surface is measured here on the basis of a nitrogen adsorption isotherm at 77K on the surface of the material (BET)
The composite material of formula II of the invention is advantageously used for manufacturing a positive electrode of a lithium battery.
These electrodes are composed of a dispersion of the composite of formula II with an organic binder that confers a satisfactory mechanical durability.
This electrode is also an object of the invention.
The batteries comprising such an electrode are also an object of the invention.
Such batteries comprise an electrode according to the invention, which is deposited on a metal sheet serving as current collector. This is the positive electrode.
Another electrode, or the so-called negative electrode, is also deposited on a metal sheet.
Any material known by a person skilled in the art can be used to form this negative electrode.
This material can in particular be carbon, silicon, a compound of the type Li4Ti5O12, etc.
The two electrodes are separated by a mechanical separator. This separator is impregnated with electrolyte that serves as ionic conductor.
This electrolyte consists of a salt, whose cation is at least partly the lithium ion, and a polar aprotic solvent.
As salt whose cation is at least partly the Li+ ion, we may mention LiClO4, LiAsF6, LiPF6, LiBF4, LiRFSO3, LiCH3SO3, LiN(RFSO2)2, LiC(RFSO2)3, LiTFSI, LiBOB, LiBETI.
An ionic liquid such as ethylmethylimidazolium TFSI, or butylmethylpyrrolydinium TFSI can also be used as solvent. From a practical standpoint, the positive electrode consisting predominantly of the compound of formula II C—LiMn1-x-y-zNyQzFexPO4 of the invention can be formed by any known type of means. As an example, the material can be in the form of an intimate dispersion comprising, among other things, the composite of formula II of the invention and an organic binder. The dispersion is then deposited on a metal sheet serving as current collector, for example aluminium. The organic binder, intended to provide good ionic conduction and satisfactory mechanical durability, can, for example, consist of a polymer selected from the polymers based on methyl methacrylate, acrylonitrile, vinylidene fluoride, as well as polyethers or polyesters or else carboxymethylcellulose.
The negative electrode of the Li-ion battery can consist of any known type of material. As the negative electrode is not a source of lithium for the positive electrode, it must consist of a material that can initially accept the lithium ions extracted from the positive electrode, and restore them subsequently. For example, the negative electrode can consist of carbon, most often in the form of graphite, or of a material of spinel structure such as Li4Ti5O12. Thus, in a Li-ion battery, the lithium is never in metallic form. It is the Li+ cations that go to and fro between the two lithium insertion materials of the negative and positive electrodes, at each charge and discharge of the battery. The active materials of the two electrodes are generally in the form of an intimate dispersion of said lithium insertion/extraction material with an electronically conducting additive and optionally an organic binder as mentioned above.
Finally, the electrolyte of the lithium battery made from the compound of formula I or of formula II of the invention consists of any known type of material. It can, for example, consist of a salt having at least the Li+ cation. The salt is, for example, selected from LiClO4, LiAsF6, LiPF6, LiBF4, LiRFSO3, LiCH3SO3, LiN(RFSO2)2, LiC(RFSO2)3, LiTFSI, LiBOB, LiBETI. RF is selected from a fluorine atom and a perfluoroalkyl group having between one and eight carbon atoms. LiTFSI is the acronym of lithium trifluoromethanesulphonylimide, LiBOB that of lithium bis(oxalato)borate, and LiBETI that of lithium bis(perfluoroethylsulphonyl)imide. The lithium salt is preferably dissolved in a polar aprotic solvent and can be supported by a separating element arranged between the two electrodes of the battery; the separating element then being impregnated with electrolyte. In the case of a Li-ion battery with polymer electrolyte, the lithium salt is not dissolved in an organic solvent, but in a solid polymer composite such as PEO (polyethylene oxide), PAN (polyacrylonitrile), PMMA (polymethyl methacrylate), PVdF (polyvinylidene fluoride) or a derivative thereof.
For better understanding of the invention, several examples of application thereof will now be described, as purely illustrative and non-limiting examples.
Compounds of formula I: LiM1-x-y-zNyQzFexPO4 in which x=0.2; 0.4; 0.5; 0.6; 0.8 and 1 were synthesized.
The procedure used was identical to that described below for synthesis of LiMn0.5Fe0.5PO4, with just the amounts of iron sulphate heptahydrate and of manganese sulphate monohydrate being changed to correspond to the desired stoichiometry.
1. Synthesis of LiMn0.5Fe0.5PO4
0.695 g of iron sulphate heptahydrate (FeSO4.7H2O) and 0.423 g of manganese sulphate monohydrate (MnSO4.H2O) are dissolved in 10 mL of distilled water containing 65 mg of ascorbic acid (i.e. a concentration of iron and of manganese of 0.05 mol/L). 0.33 mL of aqueous solution of phosphoric acid (H3PO4) at 85% is added with magnetic stirring and then 0.63 g of lithium hydroxide monohydrate (LiOH.H2O or 3 equivalents). A precipitate then quickly forms from the start of addition of the lithium salt. After adding 40 mL of diethylene glycol, the suspension is then put in a sealed 100-mL reactor suitable for microwaving and is treated at 160° C. for 30 minutes in a CEM oven (power of 400 W). The final solution (colourless) contains a beige coloured precipitate. The latter is washed with ethanol and with water, centrifuged and dried for 24 h at 60° C. The powder recovered, of a beige colour, has the composition LiMn0.5Fe0.5PO4.
The vertical lines correspond to the Bragg positions calculated for the Pnma space group, and for the lattice parameters a˜10.44 Å; b˜6.09 Å and c˜4.75 Å. The insert of
The lithium ions are shown schematically by circles, the octahedra correspond to manganese (MnO6) and the tetrahedra to phosphorus (PO4).
2. Synthesis of the Composite C-Compound of formula I.
500 mg of powder of compound of formula I obtained in 1. above is put in an agate grinding bowl containing 88 mg of amorphous carbon Ketjen Black EC600J.
This carbon has a specific surface of 1300 m2/g.
The mixture is ground for 4 hours at 500 rev/min.
The composite C—LiMn0.5Fe0.5PO4 is shown in
A lithium battery of “button cell” format is assembled with:
This battery was tested at 20° C., in a C/10 regime.
As shown in
This is also the case for the batteries whose positive electrode was manufactured from the composite materials obtained by the methods of the invention, of formula II, C—LiMnFePO4, C—LiMn0.5Fe0.5PO4 and C—LiFePO4, as shown in
The cycling behaviour of the battery obtained with the composite material C—LiMn0.5Fe0.5PO4 at 20° C. is shown in
As can be seen in
As can be seen in
Number | Date | Country | Kind |
---|---|---|---|
1350399 | Jan 2013 | FR | national |