1. Field of the Invention
The invention relates to a lithium ionic energy storage element, in particular to a lithium ionic energy storage element comprising a positive electrode active substance including a lithium ion donor and a positive electrode frame active substance.
2. Description of the Related Art
In various energy storage technologies, lithium ionic batteries are regarded as a portable chemical power source with a high efficiency in next generation because they have advantages of high energy density, light weight and less pollution. Nowadays, the lithium ionic batteries are widely used in the fields of digital cameras, smart phones and notebooks. As the energy density of the lithium ionic battery is enhanced, the fields of use are extended. There is a higher need for the performance of the lithium ionic battery as the requirement of high capacity and long life of the lithium ionic battery for the mobile electric equipment is increased
Typically, a lithium ionic battery comprises a negative electrode, a positive electrode and an electrolyte. The positive electrode active substance is not only used as an electrode material to take part in the chemical reaction, but also used as a lithium source. The positive electrode active substance is generally lithium metallic oxides which contain lithium atoms intercalated therein. Currently, lithium metallic oxides such as lithium cobalt oxide, lithium nickel oxide and lithium manganese oxide are available commercially. However, the above lithium metallic oxides cannot exhibit a proper combinative property of high initial electrical capacity, high thermal stability and excellent electrical capacity sustainability after a lithium ionic battery is charged and discharged repeatedly.
The lithium ionic battery is limited by the capacity capacity (mA/g) of the positive electrode of the lithium metallic oxides, so that it cannot exhibit a higher capacitycapacity. Therefore, the lithium sources have to be increased if it is desired to increase the capacity of the lithium ionic battery. Several methods were proposed, wherein one of the methods is coating lithium metal used as lithium source on the negative electrode, and another method is forming lithium metal as a third electrode on the negative electrode by electroplating. However, the above two methods are difficult to perform and the coating and electroplating film are not uniform because the lithium metal is very active.
Because lithium metal has disadvantages of safety and stability, the current commercial lithium ion secondary battery is used a working system having a positive electrode material containing lithium ions and a negative electrode material for intercalating lithium ions. In recent years, the energy density of the lithium ion secondary battery has to be enhanced, because the electric devices have a large energy demand. However, the stability of the positive electrode material structure is not high and the amount of lithium ions intercalation is not large, so that the capacity per gram cannot be further enhanced.
Several materials, for example FeF3, FePO4 and V2O5 were proposed. The above materials are preferable to be the positive electrode material for a high energy density, because they have good electrical capacity and a higher platform voltage. However, the above materials do not contain lithium ions, so they have to combine with lithium metal. As a result, they would be only used in half cell tests but fail to be used in a full cell.
Therefore, the inventor conducted researches according to the scientific approach in order to improve and resolve the above drawback, and finally proposed the present invention, which is reasonable and effective.
It is an object of present invention to provide a lithium ionic energy storage element. It can exhibit a high capacity by using a positive electrode active substance which comprises a lithium ion donor and a positive electrode frame active substance.
In order to achieve the above object, the present invention provides a lithium ionic energy storage element comprising a positive electrode having a first current collector and a positive electrode active substance provided on the first current collector; a negative electrode having a second current collector and a negative electrode active substance provided on the second current collector, wherein the negative electrode active substance is a material selected from the group consisting of carbon-containing materials, Si alloy and Sn alloy; and an electrolyte, wherein the positive electrode active substance comprises a lithium ion donor including lithium peroxide, lithium oxide or the mixture thereof and a positive electrode frame active substance.
The present invention also relates to a positive electrode active substance used in a lithium ionic energy storage element, the positive electrode active substance comprising a lithium ion donor and a positive electrode frame active substance, wherein the lithium ion donor includes lithium peroxide, lithium oxide or a combination of lithium peroxide and lithium oxide; and the positive electrode frame active substance is a material selected from the group consisting of anatase titanium dioxide, carbon-sulfur composite, carbon-containing materials and carbon fluoride or is lithium metallic oxides.
The present invention also relates to a method for making a lithium ionic energy storage element. At first, lithium peroxide, a positive electrode frame active substance, e.g. anatase titanium dioxide and a binder, e.g. PVDF are mixed with a predetermined weight ratio to form a mixture, and the mixture is added into a dispersant, e.g. N-methyl-2-pyrrolidone to form a slurry. Next, the slurry is coating on an aluminum foil to form a film by a blade coater. The film is baked in an oven at a temperature of 80-90° C. to remove a solvent, and raise the temperature to 120-130° C. for a period of time to form a positive electrode with lithium peroxide/anatase titanium dioxide. In order to increase conductivity of lithium peroxide, conductive carbon, for example super P carbon black, KS6 graphite or a combination thereof may be added.
A lithium ionic energy storage element is formed by assembling the positive electrode with lithium peroxide/anatase titanium dioxide, a negative electrode having a negative electrode active substance, e.g. graphitized mesocarbon microbeads (MCMB) and a porous separate strip interposed between the positive electrode and the negative electrode, and an electrolyte, e.g. a concentration of 1M LiPF6 dissolving in a mixing solution of ethylene carbonate (EC) and diethyl carbonate (DEC) with mixing ratio 1:1 by volume is filled into the porous separate strip.
Further, the present invention relates to a method for making a lithium ionic energy storage element. At first, lithium peroxide, a positive electrode frame active substance, e.g. carbon-sulfur composite and a binder, e.g. carboxymethyl cellulose (CMC) are mixed with a predetermined weight ratio to form a mixture, and the mixture is added into a dispersant, e.g. N-methyl-2-pyrrolidone to form a slurry. Next, the slurry is coating on an aluminum foil to form a film by a blade coater. The film is baked in an oven at a temperature of 80-90° C. to remove a solvent, and raise the temperature to 120-130° C. for a period of time to form a positive electrode with lithium peroxide/carbon-sulfur composite. In order to increase conductivity of lithium peroxide, conductive carbon, for example super P carbon black, KS6 graphite or a combination thereof may be added.
A lithium ionic energy storage element is formed by assembling the positive electrode with lithium peroxide/carbon-sulfur composite, a negative electrode having a negative electrode active substance, e.g. hard carbon and a porous separate strip interposed between the positive electrode and the negative electrode, and an electrolyte, e.g. a concentration of 1M lithium bis(trifluoromethanesulfonly)imide dissolving in a mixing solution of tetraethylene glycol dimethyl ether (TEGDME) and 1,3-dioxolane (DOL) with mixing ratio 1:1 by volume is filled into the porous separate strip.
Compared to the conventional lithium ionic battery comprising lithium metallic oxides, the lithium ionic energy storage element of the present invention comprises a lithium ion donor having lithium peroxide and/or lithium oxide and a positive electrode frame active substance, wherein lithium peroxide and/or lithium oxide can be decomposed to produce lithium ions by electrochemical charging, and lithium ions intercalate repeatedly in and out of the positive electrode frame active substance and the negative electrode active substance in a full cell. The full cell can exhibit a high capacity.
The technical content of invention will be explained in more detail below with reference to a few figures. However, the figures are intended solely for illustration and not to limit the inventive concept.
In the embodiment, the positive electrode active substance 114 used in a lithium ionic energy storage element, the positive electrode active substance 114 comprising a lithium ion donor and a positive electrode frame active substance, wherein the lithium ion donor includes lithium peroxide, lithium oxide or a combination of lithium peroxide and lithium oxide; and the positive electrode frame active substance is a material selected from the group consisting of anatase titanium dioxide, carbon-sulfur composite, carbon-containing materials and carbon fluoride or is lithium metallic oxides.
The lithium ion donor of the invention may include but not be limited to lithium peroxide. For example, lithium oxide is also suitable to be the lithium ion donor. Alternative, lithium peroxide and lithium oxide are mixed for the use. In addition, the positive electrode frame active substance may use carbon-containing material, and thus both of the positive electrode and negative electrode use carbon-containing materials to form lithium ion electric capacity accordingly. Carbon fluorides (CFx) that have a high mass capacity ratio are suitable to be the positive electrode frame active substance of the invention. Si alloy or Sn alloy that has a very high theoretical electrical capacity is also suitable to be negative electrode active substance 116 of the invention.
An electrolyte that is suitable to a lithium ionic energy storage element with lithium peroxide/anatase titanium dioxide system comprises an inorganic compound such as LiPF6, LiClO4 or LiBF4 and an organic solvent that is a material selected from the group consisting of ethylene carbonate (EC) and diethyl carbonate (DEC). In addition, an electrolyte comprises a concentration of 1M lithium bis(trifluoromethanesulfonly)imide dissolving in a mixing solution of tetraethylene glycol dimethyl ether (EGDME) and 1,3-dioxolane (DOL) with mixing ratio 1:1 by volume that is suitable to a lithium ionic energy storage element with lithium peroxide/carbon-sulfur system.
In a charge/discharge mode of the unit cell structure 100 of the embodiment, lithium peroxide of the positive electrode active substance 114 is decomposed to lithium ions and oxygen to intercalate into carbon-containing materials of the negative electrode 108 when unit cell is charged, and the lithium ions located in the negative electrode 108 diffuse to the positive electrode 106 and intercalate in the positive electrode active substance through the electrolyte when unit cell is discharged.
At first, electric property of lithium peroxide is investigated. The lithium ionic energy storage element of the present invention comprises a lithium ion donor having lithium peroxide and/or lithium oxide and a positive electrode frame active substance, wherein lithium peroxide and/or lithium oxide can be decomposed to produce lithium ions by electrochemical charging, and lithium ions intercalate repeatedly in and out of the positive electrode frame active substance and the negative electrode active substance in a full cell without containing Li ions. Because the conductivity of lithium peroxide is not high, a conductive carbon may be added to enhance the conductivity of lithium peroxide.
The present invention provides a method for making a lithium ionic energy storage element. At first, lithium peroxide, a positive electrode frame active substance, e.g. anatase titanium dioxide, a conductive carbon, for example super P carbon black, KS6 graphite or a combination thereof and a binder, e.g. PVDF are mixed with a predetermined weight ratio to form a mixture, and the mixture is added into a dispersant, e.g. N-methyl-2-pyrrolidone (NMP) to form a slurry. Next, the slurry is coating on an aluminum foil to form a film by a blade coater. The film is baked in an oven at a temperature of 80° C. for 6 hours to remove a solvent, and raise the temperature to 120° C. for 4-6 hours to form a positive electrode with lithium peroxide/anatase titanium dioxide.
A lithium ionic energy storage element is formed by assembling the positive electrode with lithium peroxide/anatase titanium dioxide, a negative electrode having a negative electrode active substance, e.g. graphitized mesocarbon microbeads (MCMB) and a porous separate strip interposed between the positive electrode and the negative electrode, and an electrolyte, e.g. a concentration of 1M LiPF6 dissolving in a mixing solution of ethylene carbonate (EC) and diethyl carbonate (DEC) with mixing ratio 1:1 by volume is filled into the porous separate strip. The lithium ion donor of the invention may include but not be limited to lithium peroxide. For example, lithium oxide is also suitable to be the lithium ion donor. Alternative, lithium peroxide and lithium oxide are mixed for the use. In addition, the positive electrode frame active substance may use carbon-containing material, and thus both of the positive electrode and negative electrode use carbon-containing materials to form a lithium ion electric capacity accordingly. Carbon fluorides (CFx) that have a high mass capacity ratio are suitable to be the positive electrode frame active substance of the invention. Si alloy or Sn alloy that has a very high theoretical electrical capacity is also suitable to be negative electrode active substance 116 of the invention.
Further, the present invention relates to a method for making a lithium ionic energy storage element. At first, lithium peroxide, a positive electrode frame active substance, e.g. carbon-sulfur composite, a conductive carbon, for example super P carbon black, KS6 graphite or a combination thereof and a binder, e.g. carboxymethyl cellulose (CMC) are mixed with a predetermined weight ratio to form a mixture, and the mixture is added into a dispersant, e.g. N-methyl-2-pyrrolidone to form a slurry. Next, the slurry is coating on an aluminum foil to form a film by a blade coater. The film is baked in an oven at a temperature of 80-90° C. to remove a solvent, and raise the temperature to 120-130° C. for a period of time to form a positive electrode with lithium peroxide/carbon-sulfur composite.
The lithium ion donor of the invention may include but not be limited to lithium peroxide. For example, lithium oxide is also suitable to be the lithium ion donor. Alternative, lithium peroxide and lithium oxide are mixed for the use. In addition, the positive electrode frame active substance may use carbon-containing material, and thus both of the positive electrode and negative electrode use carbon-containing materials to form a lithium ion electric capacity accordingly. Carbon fluorides (CFx) that have a high mass capacity ratio are suitable to be the positive electrode frame active substance of the invention. Si alloy or Sn alloy that has a very high theoretical electrical capacity is also suitable to be negative electrode active substance 116 of the invention.
A lithium ionic energy storage element is formed by assembling the positive electrode with lithium peroxide/carbon-sulfur composite, a negative electrode having a negative electrode active substance, e.g. hard carbon and a porous separate strip interposed between the positive electrode and the negative electrode, and an electrolyte, e.g. a concentration of 1M lithium bis(trifluoromethanesulfonly)imide dissolving in a mixing solution of tetraethylene glycol dimethyl ether (TEGDME) and 1,3-dioxolane (DOL) with mixing ratio 1:1 by volume is filled into the porous separate strip.
The above tests show the various combinations of lithium peroxide, a conductive carbon and binder, and the influence of charging and discharging of lithium peroxide in the different current density. However, lithium peroxide of the positive electrode is a functional material for use in one time, i.e. only may be decomposed by charging in one time. Therefore, another positive electrode active substance, for example anatase titanium dioxide or carbon-sulfur composite is required to use for receiving Li ions that may diffuse to the positive electrode from the negative electrode in a discharging process.
The initial lithium peroxide may be decomposed to produce Li ions by charging of the invention that is called as a charging period of prelithiation, and Li ions diffuse to the positive electrode from the negative electrode by discharging that is called as a discharging period of prelithiation. The subsequent Li ions intercalate in and out in the positive electrode and negative electrode that is called as a regular working system.
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Li2O2 vs MCMB: (372 mAh/g*0.5 g*0.7)/(410 mAh/g*xg)=1
x=0.4219 g Li2O2
TiO2 vs MCMB: (350 mAh/g*0.5 g*0.7)/(335 mAh/g*yg)=1
y=0.4858 g TiO2
According to the formulas based on the electric capacity of MCMB, the weight of each Li2O2, super P carbon black and KS graphite is 0.4219 g (22%) and the weight of PVDF is 0.1406 g (7%) and the weight of titanium dioxide is 0.4858 g (27%). During charging period of prelithiation, lithium peroxide may be charged to 4.8V against MCMB by applying the current density of 50 mA/gLi2O2. During discharging period of prelithiation and subsequent charging/discharging, TiO2 may be charged and discharged at 0-3V against MCMB by 0.1 C (1 C=335 mAh/g). The resultant charging/discharging curves of half cells are shown in
It could be found from the above experiments that Li ions prelithiation in the positive is successful. However, oxygen is produced in the process, and will affect the electrochemical performance. It is important to have an oxygen removal step for removing oxygen produced in a first cycle of charge and discharge the lithium ionic energy storage element. In manufacturing a large scale of lithium ionic battery such as battery with aluminum foil soft pack (pouch cell), a battery active step is performed in a first cycle of charging and discharging the lithium ionic battery after filling the electrolyte into the porous separate strip to form a solid electrolyte interphase (SEI) on the negative electrode, and the electrolyte decomposes in part at the same time. Next, the original electrolyte is withdrawn by evacuation, and a new electrolyte is filled. Accordingly, a regular charging and discharging the lithium ionic battery can be performed.
In another embodiment, carbon-sulfur composite may be used for the positive electrode frame active substance of the positive electrode active substance. Lithium peroxide is mixed with carbon-sulfur composite to replace Li metal. A full cell is assembled by the positive electrode having the positive electrode active substance comprising lithium peroxide and carbon-sulfur composite and the negative electrode having the negative electrode active substance comprising hard carbon. Before assembling a full cell, the electrochemical properties of lithium peroxide and carbon-sulfur composite in ethers should be determined Because Li-sulfur battery uses ethers as an electrolyte, a half cell that is used for test is formed by assembling a positive electrode formed with mixing lithium peroxide, a conductive carbon and binder by weight ratio of 30:60:10; and a porous separate strip filled with an electrolyte, e.g. a concentration of 1M lithium bis(trifluoromethanesulfonly)imide dissolving in a mixing solution of tetraethylene glycol dimethyl ether (TEGDME) and 1,3-dioxolane (DOL) with mixing ratio 1:1 by volume. Conditions of operation comprise charging/discharging current density of 100 mA/g Li2O2 vs. Li metal and charging/discharging voltage of 2-4.3V in the embodiment, shown as
The lithium ionic energy storage element of the present invention comprises a lithium ion donor having lithium peroxide and/or lithium oxide and a positive electrode frame active substance, wherein lithium peroxide and/or lithium oxide can be decomposed to produce lithium ions by electrochemical charging, and lithium ions intercalate repeatedly in and out of the positive electrode frame active substance and the negative electrode active substance in a full cell. The full cell can exhibit a high capacity. The positive electrode frame active substance of the positive electrode active substance can be a material selected from the group consisting of anatase titanium dioxide, carbon-sulfur composite, carbon-containing materials and carbon fluoride, but not limited to the above groups, as long as the materials that are stable and have excellent electric capacity are suitable as the positive electrode frame active substance. Even lithium metallic oxides may be the positive electrode frame active substance to mix with lithium peroxide and/or lithium oxide as the positive electrode active substance that can exhibit a higher capacity than the full cell using lithium metallic oxides only as the positive electrode active substance.
The invention is not limited to these embodiments, but various variations and modifications may be made without departing from the scope of the invention.
Number | Date | Country | Kind |
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103138190 | Nov 2014 | TW | national |