RU175681U1 - NEGATIVE LITHIUM-ION BATTERY ELECTRODE BASED ON SILICON-CARBON COMPOSITE FILM - Google Patents

Abstract

The utility model (PM) relates to the field of high performance electrodes for lithium-ion batteries. A negative electrode of a lithium-ion battery based on a silicon-carbon composite film made in the form of a titanium foil with a composite film consisting of a multilayer structure containing alternating layers of silicon and carbon and a silicon-carbon interface, which is obtained by simultaneous or sequential magnetron sputtering of two corresponding targets. The thickness of the silicon and carbon layers varies from 10 to 150 nm, the silicon-carbon interface varies from 0.5 to 2.0 nm. The technical result of PM is to increase the specific capacitance of the negative electrode of a lithium-ion battery due to the presence of silicon layers in it while increasing the efficiency of the electrodes in charge-discharge processes due to carbon layers. When using the aforementioned technical solution, the increase in cyclability and stability is achieved due to the multilayer structure containing alternating layers of silicon and carbon and the silicon-carbon interface.

Description

The utility model (PM) relates to the field of high performance electrodes for lithium-ion batteries.

It is currently proposed to use silicon as an active material for the implementation of high-performance electrodes for lithium-ion batteries. Silicon has an order of magnitude greater than carbon specific density. However, the main problem that arises when using silicon is a significant increase in volume caused by intercalation of lithium. This leads to the fact that during charging / discharging the battery, volumetric changes in the active material of the electrode cause its degradation and destruction of contact with the collector. So, under the influence of structural changes caused by the introduction of lithium, the silicon lattice is able to increase in volume up to 300%. For example, after the first ten cycles, the capacity of the anode material decreases from 3260 to 200 mA × h × g ^-1 .

It was expected that in nanocrystalline silicon, due to a decrease in the size of active silicon particles to the nanolevel, the cyclic behavior of the electrodes will improve due to a decrease in internal mechanical stresses due to the high surface-to-volume ratio of the particle and, accordingly, an increase in the adhesion of silicon nanoparticles to the collector. However, experiments showed that the above properties of nanocrystalline silicon are observed at film thicknesses up to 50 nm. At the same time, to obtain the maximum capacity of the silicon electrode, a film thickness of the order of 2 microns is required.

Recent research results have shown that an increase in the efficiency of energy storage properties due to a decrease in the structural degradation of the active substance can be realized by a combination of highly lithium-intensive materials (silicon) and nanostructured carbon materials, which do not have high capacity like silicon, but have high ductility.

Currently, the problem of increasing the efficiency of energy storage devices is solved by using silicon-carbon powder mixtures, which are obtained by grinding silicon in a mixture with graphite in a ball mill [B.-C. Kim, N. Uono, T. Sato, T. Fuse, T. Ishihara, M. Senna / Li-ion battery anode properties of Si-carbon nanocomposites fabricated by high energy multiring-type mill // Solid State Ionics, v. 172, no. 1-4, p. 33-37 (2004)], coating microparticles of silicon powder with carbon by chemical and thermal vapor deposition [S.-H. Ng, J. Wang, D. Wexler, K. Konstantinov, Z.-P. Guo, H.-K. Liu / Highly reversible lithium storage in spheroidal carbon-coated silicon nanocomposites as anodes for lithium-ion batteries // Angew. Chem. Int. Ed., V. 45, no. 41, p. 6896-6899 (2006)] or in high-energy plasma [Arie A.A., Song J.O., Lee J.K. / Structural and electrochemical properties of fullerenecoated silicon thin film as anode materials for lithium secondary batteries // Mat. Chem. Phys., V. 113, no 1, p. 249-254 (2009)], by pyrolysis of a mixture of precursors [Datta M.K., Kumta P.N. / Silicon, graphite and resin based hard carbon nanocomposite anodes for lithium ion batteries // J. Power Sources., V. 165, no. 1, p. 368-378 (2007)].

In these structures, carbon in combination with silicon performs several functions simultaneously:

- increases the conductivity of the active material (silicon conductivity ~ 10 ^-4 S / cm);

- acts as a buffer, mitigating changes in the volume of the alloy during cycling;

- isolates silicon particles from direct contact with electrolyte components.

In general, this should contribute to increasing the cycling parameters of the composite electrode. However, the physics of the improving effect of the carbon coating is still almost unstudied, so the choice of the optimal structural form of carbon and the conditions for its deposition on silicon can significantly increase the energy consumption of a lithium-ion battery.

US Pat. No. 6,254,427 B1 proposes a type of film anode of a lithium-ion battery, in which the active layer consists of a mixture of finely divided silicon powder and ceramics not reacting with lithium. In this case, finely dispersed single-crystal, polycrystalline, amorphous silicon, silicon alloy or silicide with particle sizes of 1-10000 nm are used.

The disadvantage of this anode is its multi-stage, and, accordingly, high energy intensity and the complexity of manufacturing the electrode. For example, silicide formation processes occur only at high temperatures, which requires high energy costs in their manufacture, and, accordingly, the creation of a negative electrode of a lithium-ion battery is a complex technical task.

The prototype of the proposed PM is the technical solution described in the patent for the invention US 6824922 B2, where to increase the cyclability of silicon films create an electrode of lithium-ion batteries, which is a metal foil on which a layer of silicon (Si) is deposited with a metal (M) that reacts with silicon, but not reacting with lithium, then a layer of silver (Ag), which increases the conductivity of the entire multilayer coating. These layers can alternate with the formation of a film structure of the type (Si-M) -Ag- (Si-M) -Ag- ... - (Si-M) -Ag. Such multilayer structures have small expansion-compression during charge and discharge cycles of lithium-ion batteries, which provides a sufficiently large number of charge-discharge cycles - up to 600.

The disadvantage of this electrode is the need for the processes of deposition of various materials in several stages from different sources at the same time or in turn, which complicates the process and leads to high energy costs in production.

This PM proposes a negative electrode of a lithium-ion battery based on a silicon-carbon composite film made in the form of a titanium foil with a composite film consisting of a multilayer structure containing alternating layers of silicon and carbon and a silicon-carbon interface that is obtained simultaneously or sequentially magnetron sputtering of two corresponding targets. The thickness of the silicon and carbon layers varies from 10 to 150 nm, the silicon-carbon interface varies from 0.5 to 2.0 nm. The proposed technical solution can significantly increase the cyclability of the working electrode while maintaining the specific capacity.

The technical result of the proposed PM is to increase the specific capacitance of the negative electrode of a lithium-ion battery due to the presence of silicon layers in it while increasing the efficiency of the electrodes in charge-discharge processes due to carbon layers.

) происходит свободное прохождение атомов лития сквозь всю структуру. Кроме высоких интеркаляционных свойств карбиноподобная пленка обладает высокой электрической проводимостью (сравнимой с проводимостью серебра).Carbon-like films sprayed by pulsed-plasma deposition are used as carbon layers. Due to the large distance between the carbine chains (about 4

) there is a free passage of lithium atoms through the entire structure. In addition to high intercalation properties, a carbin-like film has high electrical conductivity (comparable to silver conductivity).

Amorphous silicon films sprayed by high-frequency magnetron deposition are used as silicon layers. To increase the stability of cycling, aluminum is added to the silicon layers at a concentration of 5-10%.

Thus, the creation of an effective silicon-carbon electrode can be represented as sequential sputtering in a single cycle of carbon and silicon layers. The achieved thickness of the composite film is (5.0 ± 0.1) μm, the specific capacity reaches a value of about 2000 mAh / g, and due to reinforcement with carbon layers, the number of cycles increases 10 times (after 10 layers) and 3 times (after 100 layers).

In the proposed PM, an increase in cyclability and stability is achieved due to the multilayer structure.

The implementation of the claimed PM is illustrated in FIG. 1, FIG. 2 and FIG. 3, which shows a schematic diagram of the inventive negative electrode of a lithium-ion battery based on a silicon-carbon composite film, where:

FIG. 1 - Multilayer structure obtained as a result of sequential magnetron sputtering of a silicon target and deposition by the method of pulsed plasma deposition of carbon-like carbon in argon on a titanium foil;

FIG. 2 - Multilayer structure obtained as a result of simultaneous magnetron sputtering of a silicon target and application of pulsed-plasma deposition of carbin-like carbon in argon;

FIG. 3 - The multilayer structure according to claim 1 of the PM formula, after thermal annealing to create a smooth transition between silicon and carbon films.

The negative electrode of a lithium-ion battery based on a silicon-carbon composite film in a specific embodiment, corresponding to claim 1 of the PM formula, has a structure that includes sequentially: a titanium foil (current collector (Ti)) with a composite film consisting of a multilayer structure containing the following layers: carbon, silicon, carbon; and silicon-carbon interfaces.

According to paragraph 2 of the PM formula, the silicon-carbon interface (from 0.5 to 2.0 nm) is determined depending on the annealing temperature.

According to p. 3 of the PM formula, silicon layers (from 10 to 150 nm) are sprayed using high-frequency magnetron deposition.

According to p. 4 of the PM formula, carbon layers (from 10 to 150 nm) are sprayed by pulsed plasma deposition.

According to paragraph 5 of the PM formula, to increase the stability of cycling, aluminum is added to the silicon layers at a concentration of 5-10%.

Claims (5)

1. The negative electrode of a lithium-ion battery based on a silicon-carbon composite film made in the form of a titanium foil with a composite film consisting of a multilayer structure containing alternating layers of silicon and carbon and a silicon-carbon interface, characterized in that as the layers silicon use films made of amorphous silicon, and carbin-like films are used as carbon layers. 2. The negative electrode of a lithium-ion battery based on a silicon-carbon composite film according to claim 1, characterized in that the silicon-carbon interface is from 0.5 to 2.0 nm. 3. The negative electrode of a lithium-ion battery based on a silicon-carbon composite film according to claim 1, characterized in that the thickness of the silicon layers is from 10 to 150 nm. 4. The negative electrode of a lithium-ion battery based on a silicon-carbon composite film according to claim 1, characterized in that the thickness of the carbon layers is from 10 to 150 nm. 5. The negative electrode of a lithium-ion battery based on a silicon-carbon composite film according to claim 1, characterized in that aluminum is added to the silicon layers in a concentration of from 5 to 10%.

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