In a rechargeable lithium battery including inter alia a lithium anode, a lithium ion reducible cathode bonded with a polymer, as well as a polymer electrolyte, potassium ions are introduced either in the cathode or in the electrolyte, or in both of them at the same time, so that potassium is distributed in the cathode and the electrolyte when the generator has reached equilibrium. This has the effect of stabilizing the performances of the battery during cycling in terms of energy and power.
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15. polymer electrolyte for a rechargeable lithium battery, containing potassium ions introduced therein, said potassium ions being in such amount that the concentration of lithium and potassium in the polymer electrolyte of a generator made with said polymer electrolyte when said generator has reached equilibrium, expressed as O/(LiK), is between about 8/1 and 40/1 while the weight ratio Li/K is between about 0.5 and 5.
14. lithium ion reducible cathode for a rechargeable lithium battery bonded to a polymer, said cathode containing potassium ions distributed therein, said potassium ions being in such an amount that the concentration of lithium and potassium in a polymer electrolyte of a generator made with said cathode when said generator has reached equilibrium, expressed as O/(Li+K), is between about 8/1 and 40/1 while the weight ratio Li/K is between about 0.2 to 15.
1. rechargeable lithium battery comprising at least one lithium anode, one lithium ion reducible cathode bonded to a first polymer, and a polymer electrolyte comprising a lithium salt in solution in a second polymer, said lithium battery containing an additive comprising potassium ions, said potassium ions being distributed in at least one of said cathode and said polymer electrolyte, the concentration of lithium and potassium in the second polymer when said battery has reached equilibrium, expressed as O/(Li+K), being between about 8/1 and 40/1 while the ratio Li/K is between about 0.2 to 15, said potassium ions being selected so as to stabilize performances of the battery during cycling in terms of energy and power.
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a) Field of the Invention
The present invention concerns polymer electrolyte batteries, for example, polymer electrolyte generators having a potassium salt enabling to stabilize the performances and service life of the battery. More specifically, the invention relates to rechargeable lithium generators containing a potassium salt which is distributed in the cathode, in the polymer electrolyte, or both of these at the same time. In particular, the present invention is directed to rechargeable electrochemical generators in which the potassium ions introduced in the form of additives in the cathodes as well as in the polymer electrolyte define an in situ treatment which lasts the entire service life of the generator so as to improve performances during cycling, for example, in terms of energy and power. The present invention also concerns potassium base additives distributed in at least one, and even two, of the components of a rechargeable lithium electrochemical generator, preferably the polymer electrolyte and the composite cathode bound to a polymer, in which the effect is to stabilize the energy and power performances during cycling.
The invention also describes preferred means for introducing potassium into the generator by either one of its components and describes how the potassium is distributed in more than one component so as to optimize the operation of the electrodes during cycling. The additive has the beneficial effect of maintaining the morphology of the lithium anode during cycling and to optimize the physical properties of the cathode during cycling.
b) Description of Prior Art
The life of a battery is dependent on many factors including the reversibility of the electrochemical processes at both electrodes. The addition of alkali earth or transition metals to the active material of the cathodes of lithium batteries is known and is used generally to stabilize or optimize the insertion cathodes (FR 2,616,013; U.S. Pat. No. 5,013,620; U.S. Pat. No. 5,114,809; FR 2,573,250). The additives used are generally intended to stabilize the insertion structures and sometimes to optimize the number of sites available in the host structure (WO 91/02383; U.S. Pat. No. 4,668,594). In some cases, the additives are also intended to increase the electronic conductivity of the insertion materials (U.S. Pat. No. 4,965,151; JP 89/15317; JP 89/67063; U.S. Pat. No. 5,114,811; U.S. Pat. No. 5,147,737). In most of the cases known, the addition metals are integrated in the host structure and are present at relatively high rates which vary between 1% and 50% with respect to the main transition metal. These additives are generally immobilized in the host insertion structure and are not diffused in the other components of the generator, for example, the electrolyte and the anode. In the case where the addition metals would be soluble in the electrolyte, they would be reduced with metallic lithium and could not remain in equilibrium in the generator. Moreover, in Applicant's view, no example of additive which is present in more than one component of a lithium generator has been described up to now.
As a matter of fact, a few of these metals are chemically compatible with a lithium anode and are capable of coexisting with the lithium salts which are in solution in the electrolyte of the generator. Potassium, with magnesium is one of the only metals which are not reduced (thermodynamically and kinetically) by lithium in aprotic media and therefore constitutes a unique material to carry out the present invention.
The utilization of polymer electrolytes with mixed alkali cation has been mentioned during conductivity measurements (ACFAS 1993) and for the constitution of vehicular conduction electrolytes (cf. U.S. Pat. No. 5,350,646). None of these cases mention an equilibrium between the mixed cations of the electrolyte and the materials of the electrode or a beneficial effect on the cycling of the generator or on the lithium anode.
It is an object of the present invention to provide for a beneficial effect noted on the stabilization of the material of the cathode V2O5 which is presently used in the technology of polymer electrolyte batteries and simultaneously to provide an improvement to the reversibility of the dissolution-redeposition of the lithium anode and its morphology in order to improve the performances and service life of the battery.
It is therefore an object of the invention to provide improvements by the introduction of a potassium salt, such as KTFSI (potassium trifluoromethanesulfonyl imide) in the polymer separator and/or in the polymer which constitutes the composite positive or cathode.
It is another object of the invention to introduce potassium ions in the polymer, which are subsequently present in the electrodes by electrochemical means.
It is also an object of the invention to provide for the manufacture of a battery characterized by an improved cycling with respect to energy and power obtained by in situ addition of a stabilizing agent, such as potassium, without necessarily utilizing a chemical means.
It is another object of the invention to permit the introduction of a stabilizing agent, such as in the polymer electrolyte separator and/or in the cathode, so that it is uniformly distributed in the entire battery from the interface Li to the collector of the positive.
It is also an object of the invention to produce depolarizing effects during recharge (decrease of voltage of more than 20 mV in the case of dendrite formation, contact of the anode with the cathode) following the morphological development of lithium (modification of a plane surface of lithium into a rugged surface), which enables the battery to cycle again in a reversible manner for many tens of cycles without any appearance of dendrites.
In order to achieve these objects and to overcome the disadvantages of the prior art, the invention proposes a rechargeable lithium battery including at least one lithium anode, one lithium ion reducible cathode bound with a first polymer, and a polymer electrolyte comprising a second polymer, and a lithium salt in solution in the second polymer. The lithium generator according to the invention is characterized in that it contains potassium ions, which are distributed in at least one among the cathode and the polymer electrolyte, the concentration of lithium and potassium under equilibrium in the second polymer expressed as O/(Li+K), being between about 8/1 and 40/1, with a Li/K molar ratio between about 0.2 and 15. The potassium ions are selected so as to stabilize the energy and power performances of the generator during cycling.
In general, the potassium ions are introduced by means of potassium salts. The potassium salt may be distributed in the cathode, in the electrolyte, or both in the polymer electrolyte and the cathode.
Moreover, the first and second polymers may be identical or different depending on circumstances, as this will appear to one skilled in the art.
Among the potassium salts that may be used according to the invention
The addition of potassium, for example, in the form of KN(CF3SO2)2 in the electrolyte enables to maintain a rate of use of the active material of the cathode higher than what has been obtained in the case of a similar generator containing no potassium. It is also shown by means of elementary analysis after cycling that potassium which is introduced through the electrolyte is equally distributed in all the components of the battery without however being deposited at the anode which confirms the stability of the electrolytes with mixed alkali cations (Li++K+) used in the generators of the invention.
Another benefit of the present invention concerns the quality of the contact between metallic lithium and the polymer electrolyte which is maintained during discharge/charge cyclings which largely contributes to excellent properties of cycling and power of the generators according to the invention.
The possibility of introducing potassium in equilibrium in more than one component of the generator by means of the material of the cathode, is also within the spirit of the invention. In these cases, the addition of potassium may be carried out by chemically pre-inserting potassium in the structure of vanadium oxide by means of a solution of an oxidizable salt such as KI in an aprotic solvent such as acetonitrile so as to give KxV2O5 and iodine (or triiodide). It will also be shown by elementary analysis that in these cases potassium is also present in the electrolyte of the separator after cycling and analysis of the battery.
The examples which follow are given only as illustration and without limiting the scope of the invention.
In this example a comparison is made of the results obtained during cycling (
The batteries are cycled at an imposed current density of the order of 100 μA/cm2 in discharge and 50 μA/cm2 in charge at 60°C C. between limits of 3.3 V and 1.5 V, thus enabling to produce deep discharges (100% DOD).
In this Example a comparison is made between the performances of three generators in which the Li/K composition varies. KTFSI is introduced into the polymer electrolyte of the separator. The batteries are essentially composed of the same anode and cathode as in Example 1. The method of assembly is also identical as well as the current densities imposed in discharge and in charge under the same limits of voltage. All the batteries are composed of a total quantity of salt O/M=30/1. The Li/K ratio in the generator is equal to 0.8 in the case of battery 1, 7 for battery 3 and 25 for battery 4.
In this Example, the intention is to illustrate that the potassium additive is dispersed in a homogenous manner in the entire generator, whether it be introduced into the separator electrolyte and/or in the cathode. The present Example (battery 5) illustrates the case where KTFSI is introduced into the separator. The quantity of salt O/M is equal to 40/1 while the ratio Li/K in the generator is equal to 0.8. The thickness of the separator is 40 microns while the other components of the generator are identical to battery 1. After 200 cycles this battery was examined by X-ray fluorescence (EDX) following a cryogenic fracture enabling to have a cross-section view of the battery.
The relative composition in "K+" in the separator electrolyte and in the positive electrode is identical, as demonstrated in
The presence of K in the structure of vanadium oxide (
This equilibrium probably exists at the level of the interface Li/polymer electrolyte. As a matter of fact,
Thus, through these analyses it is established that K is present in more than two components and/or sections of the battery; the polymer electrolyte separator, the binder of the cathode which is made of the same electrolyte as the separator, and the granular particle of the oxide of the positive electrode. The probability of finding ionic potassium at the interface Li/polymer is also not excluded.
In order to establish once again the beneficial effect of the presence of K+ at the lithium anode, two symmetrical batteries (6 and 7) having lithium anodes and cathodes have been assembled.
The developed morphology of the lithium anode of battery 7 is three times that of battery 6 even for a lower duration of cycling (nearly less than half the number of cycles). The only major difference between these two batteries is the presence of KTFSI in battery 6. Thus, these pictures establish very clearly the beneficial effect of K on the profilometry of cycled lithium and thus on the duration of the fife of the battery. The front face microscopic views are also quite revealing. Similar conclusions have been realized following an examination of battery 8 which has achieved 20 cycles.
In this Example a post mortem analysis of batteries 1 and 3 was made (cryogenic cross-section view) to illustrate (
In this Example the beneficial effect of the additive K+ on the evolution of the instantaneous power as a function of the life of the generator is confirmed. The two batteries which were investigated are essentially the same as those of Example 1. The instantaneous power (Pi) is determined when the generator is fully charged. Current densities (I) of the order of 1 to 5 mA/cm2 are provided on the battery for 20 seconds. Between each call for power the battery is allowed to rest for 120 seconds. The final voltage (V) of each impulsion is then registered and the instantaneous power (mW) is given by the equation Pi=VI.
In this Example, the physical properties of batteries with and without K with respect to their sustained power (Ragone curve for configurations of optimized batteries for metallic collectors) are compared. Battery 9 (
As already mentioned, the lower power energy of battery 9 is higher than that of battery 10 since its rate of utilization (up to about 375 cycles) is higher. The initial power is also higher than the battery having K. On the other hand, after 200 cycles, battery 9 without K shows a considerably reduced specific energy (wh/kg) especially under high power of the order of 200 W/kg, which is not the case for battery 10. As a matter of fact, although it is lower at the start of the service life of the generator, the sustained power of the battery having K is maintained, and this for more than 300 cycles, which demonstrates the stabilizing effect brought about by K in the polymer electrolyte lithium battery.
In this Example, it is shown that the equilibrium of the species Li and K may be obtained in at least three components including vanadium oxide, the polymer which binds the cathode, and the polymer of the electrolyte, due to the chemical addition of potassium in the structure of vanadium oxide by means of a solution of KI in acetonitrile so as to give KxV2O5 and iodine (or triiodide). After a cycling of the same type as described in Example 1, battery 11 was examined by X-ray fluorescence (EDX) following a cryogenic fracture enabling to obtain a cross-section view of the battery. The electrochemical configuration of battery 11 is identical to that of battery 1 except that the electrolyte contains no salt and that vanadium oxide V2O5 contains about 0.18 mole of K. The spectrum EDX is illustrated in FIG. 17. The presence of K in the polymer electrolyte and/or the cathode may be observed while no potassium has been introduced into the starting electrolyte of the polymer binding the cathode.
It is understood that the invention is not restricted to the Examples given above, and that modifications and alternatives are possible without departing from the scope of the invention.
Armand, Michel, Choquette, Yves, Simoneau, Martin, Gagnon, René , Belanger, André
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