CN209266514U - A kind of hybrid solid-state electrolyte - Google Patents

Abstract

The utility model discloses a kind of hybrid solid-state electrolyte, the hybrid solid-state electrolyte includes at least sulfide solid-state electrolyte layer and non-crystal oxide solid-state electrolyte layer.The utility model is by improving the interface problem between sulfide solid electrolyte and electrode material in sulfide solid electrolyte surface recombination non-crystal oxide solid electrolyte.

Description

A kind of hybrid solid-state electrolyte

Technical field

The utility model relates to technical field of lithium ion, and in particular to a kind of hybrid solid-state electrolyte.

Background technique

Growing digital electric consumption and emerging electric car industry propose higher want to energy storage device It asks.Lithium secondary battery has that energy density is high, cyclicity is superior, memory-less effect and many advantages, such as non-environmental-pollution, and by To the favor in market.But using the lithium ion battery of organic electrolyte the higher and higher safety in market, energy density with And it gradually has too many difficulties to cope in face of the requirement of cycle life etc..

The safety for having liquid lithium secondary battery incomparable using all solid lithium secondary battery of solid electrolyte, and It is expected to thoroughly eliminate the security risk in use process, more meets the demand of electric car and scale energy storage field future development. The solid electrolyte studied extensively at present is broadly divided into two classes: polymer dielectric and inorganic electrolyte.Inorganic electrolyte can It is divided into two class of oxide and sulfide, and oxide and sulfide can be further separated into as crystalline state, devitrified glass state and amorphous state.

Polymer dielectric has the advantages that flexibility, preparation is simple, and density is small, good film-forming property.But polymer dielectric Room temperature ionic conductivity it is low, be not able to satisfy requirement.Moreover, its bad mechanical property, can not inhibit Li dendrite.

Inorganic electrolyte has many advantages, such as that nonflammable, electrochemical stability window is wide, modulus of shearing is big, has organic electrolyte The advantages such as incomparable safety and service life.Meanwhile metal can also be used using the solid state battery of solid electrolyte Lithium abandons diaphragm and negative current collector structure as cathode, to greatly promote energy density.

Oxide electrolyte has very high modulus of shearing, theoretically can effectively inhibit Li dendrite.But oxide is electric It is relatively low (most to be in 10 to solve matter conductivity at room temperature^-6S/cm~10^-4It S/cm), still cannot be with organic electrolysis Liquid phase ratio.And since the oxide electrolyte hardness of crystalline state is larger, when matching with electrode, solid-solid contact is poor, causes big Interface impedance.Meanwhile hard and crisp oxide electrolyte is easy embrittlement when coping with the volume expansion problem of electrode, thus anxious Speed deteriorates performance.

Sulfide electrolyte flexible relative, moreover, being obtained with very high ionic conductivity by the method being cold-pressed. The Li of Thio-LiSICON structure₁₀GeP₂S₁₂Conductivity at room temperature reached 1.2 × 10^-2S/cm has reached organic electrolysis The conductivity level of liquid.So high ionic conductivity can effectively improve the energy storage density and power density of all-solid-state battery. But single sulfide electrolyte still has following problems: (1) the high price Ge in sulfide⁴⁺It is unstable to lithium metal, such as Fruit directly contacts, and can be restored by Li, generates low conductivity miscellaneous phase；(2) sulfide differs greatly with oxide anode chemical potential, and And electron-ion mixed conductor when oxide electrode, wide Schottky type space charge layer is easily formed, big interface is caused to hinder It is anti-；(3) the sulfide modulus of shearing of cold moudling is lower, inhibits the effect of Li dendrite undesirable.

As it can be seen that single electrolyte is constantly present short slab in a certain respect in comprehensive performance, it is unable to satisfy solid state battery pair The requirement of electrolyte comprehensive performance.Therefore, the advantages of how combining the electrolyte of different component, plays the advantage of solid state battery, It is the key technical problem of solid state battery development.

Patent CN201710833796.2 discloses the inorganic solid electrolyte and its system that a kind of surface is amorphous substance Preparation Method, comprising the following steps:

A) identical with solid electrolyte basis material chemical component non-using melting-quenching method or high-energy ball milling method preparation Amorphous material；

B) amorphous substance, binder and solvent are mixed, obtain composite material sizing agent；

C) composite material sizing agent is coated on to the surface of the solid electrolyte basis material, remove solvent and bonding Agent simultaneously softens the amorphous substance, obtains the inorganic solid electrolyte that surface is amorphous substance.

The patent, will be with basic electrolyte by melting-quenching method or high-energy ball milling method based on oxide electrolyte The identical oxide of ingredient is prepared into relatively soft amorphous state, and is coated in oxide electrolyte surface.By this method, Obtain the buffer layer that still there is certain modulus of shearing and flexible relative can preferably be combined with Li cathode.Improve oxide electrolyte Problem that is unstable with when Li cathode solid-solid contact and contacting difference.

Its existing main problem is:, can be to a certain degree although non-crystal oxide is softer with respect to crystalline oxide Upper improvement solid-solid contact still based on oxide electrolyte, and carries out surface with the oxide amorphous of homogeneity and is modified Substantially or oxide, comprehensive performance can be promoted, therefore there are still following in conjunction with the advantages of different electrolyte Problem:

(1) conductivity of oxide electrolyte is lower, the oxide conductivity after amorphous state also by by certain damage, Therefore, the electrolytic conductivity that the program obtains is lower compared to traditional oxide electrolyte, solid-state electricity based on this Energy storage density and the power density performance in pond are poor；

(2) oxide electrolyte matrix is still very rigid, although being coated with one layer of non-crystal oxide in negative side, It is since the conductivity of non-crystal oxide is lower, reasonable amorphous layer thickness is smaller, can not completely buffer cathode Volume expansion in charge and discharge process.Meanwhile volume change can also occur in charge and discharge process for anode.Oxide electrolyte Matrix can not obtain effective solution in charge and discharge process the problem of fragmentation.

Patent CN201580084439.x and document " Cu₂ZnSnS₄/graphene nanocomposites for ultrafast.long life all-solid-state lithium batteries using lithium metal " etc. anode. files disclose a kind of structure of double-deck sulfide electrolyte, main contents are as follows:

By the Li of high conductivity₁₀GeP₂S₁₂With the Li with opposite high stability₂S-P₂S₅-P₂O₅Laminated construction is prepared into, Make final battery structure are as follows: anode | Li₁₀GeP₂S₁₂|Li₂S-P₂S5-P₂O₅| cathode containing Li.

This document passes through in high conductivity Li₁₀GeP₂S₁₂Introducing conductivity is slightly lower between cathode containing Li but stability is preferable Li₂S-P₂S₅-P₂O₅Layer, improve electrolyte layer to Li stability.

Its existing main problem is: although in high conductance Li₁₀GeP₂S₁₂Opposite high stable is introduced between cathode containing Li The Li of property₂S-P₂S₅-P₂O₅It can inhibit to a certain extent the interfacial reaction of Li negative side, and retain relatively high conductivity, But it is same as described above, still there is short slab in comprehensive performance using sulfide merely, the program still has following problems:

(1) sulfide itself flexible relative can preferably be combined with positive and negative anodes, but simultaneously its mechanical strength relative to Oxide is lower, and in terms of inhibiting Li dendrite, effect is poor compared with oxide；

(2) there are biggish difference in chemical potential between sulfide electrolyte and oxide electrode, therefore, the oxygen with current commercialization Compound electrode will form very wide Schottky type space charge layer when matching, and cause very big interface impedance, deteriorate solid-state electricity The performance in pond.

Therefore, current solid electrolyte still needs to improve.

Utility model content

Technical problem to be solved in the utility model is to overcome the technological deficiency of background technique, is provided a kind of compound solid State electrolyte.The utility model is by improving in sulfide solid electrolyte surface recombination non-crystal oxide solid electrolyte Interface problem between sulfide solid electrolyte and electrode material；Meanwhile the utility model is true by thermoforming way It is compound good to protect heterogeneous interface (oxide/sulfide interface).

It is as follows that the utility model solves technical solution used by above-mentioned technical problem:

A kind of hybrid solid-state electrolyte, the hybrid solid-state electrolyte include at least sulfide solid-state electrolyte layer, And non-crystal oxide solid-state electrolyte layer.

Preferably, the hybrid solid-state electrolyte is by one layer of sulfide solid-state electrolyte layer and two layers of amorphous state oxygen Compound solid-state electrolyte layer composition；The non-crystal oxide solid-state electrolyte layer is set to the sulfide solid-state electrolyte layer Two sides.

Preferably, the hybrid solid-state electrolyte is by one layer of sulfide solid-state electrolyte layer and one layer of amorphous state oxygen Compound solid-state electrolyte layer composition.

Preferably, the sulfide solid-state electrolyte layer with a thickness of 5~1000 μm, non-crystal oxide solid-state electricity Solve matter layer with a thickness of 0.1~10 μm.

It is highly preferred that the sulfide solid-state electrolyte layer with a thickness of 10~400 μm, the non-crystal oxide solid-state Electrolyte layer with a thickness of 0.5~5 μm.

Most preferably, the sulfide solid-state electrolyte layer with a thickness of 20~100 μm, the non-crystal oxide solid-state Electrolyte layer with a thickness of 0.5~2 μm.

Preferably, the component of the sulfide solid-state electrolyte layer includes sulfide solid electrolyte.

It is highly preferred that the sulfide solid electrolyte includes crystalline state sulfide solid electrolyte or the vulcanization of devitrified glass state Object solid electrolyte.

It is further preferred that the crystalline state sulfide solid electrolyte includes the sulfide or Thio- of argyrodite structure The sulfide of LiSICON structure.

It is further preferred that the sulfide of the argyrodite structure is Li₆PS₅Cl。

It is further preferred that the sulfide of the Thio-LiSICON structure includes Li₁₀GeP₂S₁₂Or it is based on Li₁₀GeP₂S₁₂Carry out the sulfide solid electrolyte obtained after element doping.

Still further preferably, the element of the doping includes Al, Si, Ga, Sn, N, O, Cl, Br, one of I or several Kind.

It is further preferred that the devitrified glass state sulfide solid electrolyte includes being based on Li₂S-P₂S₅The vulcanization of system Object is based on Li₂S-P₂S₅The sulfide of system carries out the multicomponent system sulfide obtained after element doping.

It is further preferred that the Li₂S-P₂S₅System includes Li₂S∶P₂S₅The sulfide or Li of=70: 30 compositions₂S∶ P₂S₅The sulfide of=75: 25 compositions.

Preferably, the component of the non-crystal oxide solid-state electrolyte layer includes non-crystal oxide solid electrolyte.

It is highly preferred that the non-crystal oxide solid electrolyte is the oxide lithium ion conductor of amorphous material.

It is further preferred that the oxide lithium ion conductor includes NASICON structure, perovskite structure, garnet knot Any one in the oxide of structure.

It is further preferred that the oxide of the garnet structure is Li₇La₃Zr₂O₁₂。

Most preferably, the oxide of the garnet structure is Li_6.5La₃Zr_1.5Ta_0.5O₁₂。

A kind of hybrid solid-state electrolyte preparation method, which comprises the steps of:

(1) sulfide solid electrolyte is prepared；

(2) non-crystal oxide solid electrolyte is prepared；

(3) by step (1) the sulfide solid electrolyte and step (2) described non-crystal oxide solid electrolyte into Row is compound, obtains hybrid solid-state electrolyte.

Preferably, in the step (1), the method for preparing sulfide solid electrolyte includes the following steps:

A. ingredient ingredient: is selected according to target sulphide solid electrolyte chemical formula；

B. the ingredient ball milling: is subjected to ball milling；

C. it is heat-treated: the sulfide after the ball milling is heat-treated；

D. it forms: the sulfide after the heat treatment is formed.

Preferably, in the step a, the target sulphide solid electrolyte include crystalline state sulfide solid electrolyte or Devitrified glass state sulfide solid electrolyte.

It is highly preferred that the crystalline state sulfide solid electrolyte includes the sulfide or Thio- of argyrodite structure The sulfide of LiSICON structure.

It is further preferred that the sulfide of the argyrodite structure is Li₆PS₅Cl。

It is further preferred that the sulfide of the Thio-LiSICON structure includes Li₁₀GeP₂S₁₂Or it is based on Li₁₀GeP₂S₁₂Carry out the sulfide solid electrolyte obtained after element doping.

It is further preferred that the element of the doping includes Al, Si, Ga, Sn, N, O, Cl, Br, one of I or several Kind.

It is highly preferred that the devitrified glass state sulfide solid electrolyte includes being based on Li₂S-P₂S₅The sulfide of system or Based on Li₂S-P₂S₅The sulfide of system carries out the multicomponent system sulfide obtained after element doping.

It is further preferred that the Li₂S-P₂S₅System includes Li₂S∶P₂S₅The sulfide or Li of=70: 30 compositions₂S∶ P₂S₅The sulfide of=75: 25 compositions.

Preferably, in the step b, the ball milling method includes high-energy ball milling, any one in vibratory milling.

Preferably, in the step b, the ratio of grinding media to material when ball milling is ball: material=(10~50): 1.

It is highly preferred that in the step b, the ratio of grinding media to material when ball milling is ball: material=(20~30): 1.

Preferably, in the step b, the revolving speed when ball milling is 200~700r/min.

It is highly preferred that in the step b, the revolving speed when ball milling is 300~600r/min.

Preferably, in the step b, the Ball-milling Time is >=4h.

It is highly preferred that the Ball-milling Time is 8~48h in the step b.

Most preferably, in the step b, the Ball-milling Time is 12~36h.

Preferably, in the step b, the mechanical milling process is continuous or interval.

Preferably, in the step c, the temperature of the heat treatment is 200~800 DEG C, and the time is >=30min.

It is highly preferred that the temperature of the heat treatment is 300~700 DEG C in the step c, the time is 4~12h.

Preferably, in the step d, the forming method includes cold pressing, hot pressing, or after mixing with binder, solvent Using any one forming method in curtain coating, casting, spin coating method.

It is highly preferred that the forming method is cold-press method in the step d；The cold-press method includes the following steps:

The sulfide powders for weighing certain mass, pressure maintaining 2min obtains electrolyte sheet under the pressure of 20MPa.

It is highly preferred that the forming method is the tape casting in the step d；The tape casting includes the following steps:

Sulfide solid electrolyte powder is mixed with 8: 1: 1 with binder and solvent after sizing mixing, is applied to the tape casting On PET film, dielectric film is removed after dry, in 260 DEG C of (75Li₂S-25P₂S₅) it is heat-treated 3h, PVDF is discharged simultaneously in controlled micro crystallization, Obtain fine and close sulfide film.

Preferably, the binder is PVDF.

Preferably, the solvent is NMP.

Preferably, in the step (2), the method for preparing sulfide solid electrolyte includes melting-quenching method, height It can ball-milling method, hydro-thermal method, microemulsion method, any one in magnetron sputtering deposition method.

It is highly preferred that the method for preparing non-crystal oxide solid electrolyte is to melt-quench in the step (2) Cold process includes the following steps:

A. ingredient, mixing ingredient: are selected according to target non-crystal oxide solid electrolyte chemical formula；

B. melting-quenching: the powder mixed is kept the temperature, quenching is carried out after heat preservation, obtains amorphous state oxygen Compound solid electrolyte；

C. it crushes: the non-crystal oxide solid electrolyte being crushed, non-crystal oxide solid electrolyte powder is obtained；

D. it sizes mixing: the non-crystal oxide solid electrolyte powder being mixed with binder and solvent and is sized mixing, amorphous is obtained State oxide solid electrolyte slurry；

Preferably, in the step a, the target non-crystal oxide solid electrolyte is the oxide lithium of amorphous material Ion conductor.

It is highly preferred that the oxide lithium ion conductor includes NASICON structure, perovskite structure, garnet structure Any one in oxide.

It is further preferred that the oxide of the garnet structure is Li₇La₃Zr₂O₁₂。

Most preferably, the oxide of the garnet structure is Li_6.5La₃Zr_1.5Ta_0.5O₁₂。

Preferably, in the step a, the hybrid mode is hybrid mode generally known in the art.

Preferably, in the step b, the temperature of the heat preservation is 1500~1800 DEG C, the time is 1~for 24 hours.

It is highly preferred that the temperature of the heat preservation is 1600~1700 DEG C in the step b, the time is 5~10h.

Preferably, in the step b, the medium when quenching includes liquid nitrogen, oil, water, appointing in inorganic salt solution It anticipates one kind.

It is furthermore preferred that in the step b, the medium when quenching is liquid nitrogen.

Preferably, in the step d, the binder and the solvent are selected from the common binder and solvent in this field.

It is highly preferred that the method for preparing non-crystal oxide solid electrolyte is high-energy ball milling in the step (2) Method；The high-energy ball milling method uses the high-energy ball milling method as disclosed in patent CN201710833796.2.

It is highly preferred that the method for preparing non-crystal oxide solid electrolyte is hydro-thermal method in the step (2)； The hydro-thermal method uses the hydro-thermal method as disclosed in patent CN201310698212.7.

It is highly preferred that the method for preparing non-crystal oxide solid electrolyte is microemulsion in the step (2) Method；The microemulsion method uses the microemulsion method as disclosed in patent CN201810259936.4.

It is highly preferred that the method for preparing non-crystal oxide solid electrolyte is magnetron sputtering in the step (2) Sedimentation；The magnetron sputtering deposition method uses the magnetron sputtering deposition method as disclosed in CN200710039147.1.

Preferably, in the step (3), the complex method includes pressure sintering, discharge plasma sintering method, vacuum sputtering Method, vacuum vapour deposition, any one in chemical vapour deposition technique.

It is highly preferred that the complex method is pressure sintering in the step (3), include the following steps:

A. it coats: the non-crystal oxide solid electrolyte slurry is coated to the sulfide solid electrolyte matrix Surface, the solid electrolyte after must coating；

B. it dries: the hybrid solid-state electrolyte after the coating is dried, the solid electrolyte after must drying；

C. hot pressing: the solid electrolyte after the drying is subjected to hot-pressing processing, obtains hybrid solid-state electrolyte.

Preferably, in the step a, the method that when coating uses is in curtain coating, blade coating, spraying, silk-screen printing Any one.

Preferably, described applied to single side coating or dual coating in the step a.

Preferably, in the step a, the coat thickness are as follows: 0.1 μm≤coat thickness≤10 μm.

It is highly preferred that in the step a, the coat thickness are as follows: 0.5 μm≤coat thickness≤5 μm.

Most preferably, in the step a, the coat thickness are as follows: 0.5 μm≤coat thickness≤2 μm.

Preferably, in the step a, the thickness of the sulfide solid electrolyte matrix are as follows: 5 μm≤sulfide solid-state electricity Solve matter matrix≤1000 μm.

It is highly preferred that in the step a, the thickness of the sulfide solid electrolyte matrix are as follows: 10 μm≤sulfide is solid State electrolyte matrix≤400 μm.

Most preferably, in the step a, the thickness of the sulfide solid electrolyte matrix are as follows: 20 μm≤sulfide is solid State electrolyte matrix≤100 μm.

Preferably, in the step c, the pressure when hot-pressing processing is 10~300MPa.

It is highly preferred that in the step c, the pressure when hot-pressing processing is 20~200MPa.

Preferably, in the step c, the heating temperature when hot-pressing processing is 150~600 DEG C.

It is highly preferred that in the step c, the heating temperature when hot-pressing processing is 250~500 DEG C.

Preferably, in the step c, the time of the hot-pressing processing is >=10min.

It is highly preferred that the time of the hot-pressing processing is 30min~10h in the step c.

It, will be non-while softening surface amorphous oxide solid-state electrolyte layer by hot pressing in above-mentioned technical proposal Crystalline oxide solid-state electrolyte layer and sulfide solid-state electrolyte layer good combination, avoid the occurrence of out-phase structure in subsequent processing The case where with being mutually disengaged in use process；The hot pressing can be the closed pressurization using mold.

It is highly preferred that the complex method is discharge plasma sintering method in the step (3)；The plasma discharging Sintering process uses the discharge plasma sintering method as disclosed in patent CN200710177048.X, specific as follows:

A. by step (2) the non-crystal oxide solid electrolyte powder-step (1) sulfide solid electrolyte Powder-step (2) the non-crystal oxide solid electrolyte powder (such as single layer processing can cancel the side) is with 1: (20~200) : 1 ratio is packed into sintering grinding tool；

B. 1~10min is handled at 200~600 DEG C, heating rate is 20~100 DEG C/min, sintering pressure 500MPa ~1GPa, sintering atmosphere are vacuum or Ar gas shielded；

C. 2~5h is heat-treated in dry air atmosphere at 200~400 DEG C.

In above-mentioned technical proposal, the vacuum sputtering, the vacuum vapour deposition and described chemical vapour deposition technique etc. are originally The common vapour deposition process of area research personnel is relatively inefficient, but can prepare the accurate controllable compound thin layer of thickness, And guarantee that biphase interface is well combined.

In above-mentioned technical proposal, the step (1) and the step (3) carry out in the atmosphere of strict control moisture.

A kind of solid state battery, including hybrid solid-state electrolyte as described above.

The basic principle of the utility model:

(1) non-crystal oxide is higher than the modulus of shearing of sulfide, therefore, coats amorphous state in sulfide bath surface Oxide can be effectively improved the inhibiting effect to Li dendrite；

(2) sulfide ionic conductivity itself is very high；Meanwhile sulfide itself is very soft, therefore to electrode in charge and discharge Volume change in journey has stronger tolerance；To the non-crystal oxide solid-state of low ionic conductivity in the structure The thickness requirements of electrolyte layer are lower, and the conductivity of electrolyte entirety is then made to be protected；

(3) between sulfide and Li cathode be inserted into one layer of non-crystal oxide solid-state electrolyte layer, can to avoid Li with The direct contact of sulfide, to avoid Li to Ge in sulfide electrolyte⁴⁺The reduction of equal elements, and then avoid electrolyte performance Deterioration；

(4) non-crystal oxide relative to crystalline oxide electrolyte want it is soft (but still maintain certain modulus of shearing, It is enough to inhibit Li dendrite, this is the reason of not selecting sulfide and polymer to be coated), it therefore, can when being contacted with electrode To provide relatively good contact interface, the solid-solid that crystalline oxide generates between electrode since itself is too hard is avoided the occurrence of The problem of poor contact；Meanwhile amorphous substance without grain boundary features can avoid the occurrence of the feelings that Li dendrite is grown in crystal boundary Condition；

(5) the non-crystal oxide solid-state electrolyte layer that diversion but non-conductive son are introduced in side of the positive electrode, can inhibit sulphur The growth of compound/oxide interface space charge layer and form wide Schottky type space charge layer, to avoid big boundary The generation of surface resistance, thus allow the sulfide electrolyte of the structure directly with the ternary material of current commercialization, ferric phosphate The positive electrodes such as lithium, cobalt acid lithium match.

Compared with prior art, the utility model has the beneficial effects that

(1) the utility model uses the sulfide solid electrolyte of high conductance for matrix, in conjunction with opposite high shear mould The non-crystal oxide solid electrolyte thin layer of amount and interface stability is ensuring that conductivity and electrolyte/electrode well contact Under the premise of: a. improves the inhibition to Li dendrite in negative side；B. in the amorphous state oxidation of side of the positive electrode diversion and non-conductive son Object solid-state electrolyte layer can effectively inhibit the growth of space charge layer, reduce interface impedance；

(2) the utility model is using the sulfide solid electrolyte of flexible relative as matrix, to anode and cathode in charge and discharge Volume change in the process has better tolerance；

(3) the utility model is due to being Heterogeneous Composite, and oxide is different with the thermal capacitance and coefficient of thermal expansion of sulfide, in Re Chu It is easy to happen interface mismatch when reason, leads to modified failure；Therefore, in the present invention, using hot pressing means, heat treated External pressure is kept in journey, to guarantee the good compound of heterojunction structure.

Detailed description of the invention

Fig. 1 is a kind of structure chart of the utility model hybrid solid-state electrolyte；

Fig. 2 is another structure chart of the utility model hybrid solid-state electrolyte；

Fig. 3 is the utility model hybrid solid-state electrolyte preparation flow figure.

The corresponding component names of each appended drawing reference are in figure:

1- sulfide solid-state electrolyte layer；2- non-crystal oxide solid-state electrolyte layer.

Specific embodiment

The content of the utility model in order to better understand, is described further with attached drawing combined with specific embodiments below. It should be understood that these embodiments are only used for, the present invention will be further described, rather than limitation the scope of the utility model.This Outer to should be understood that after having read content described in the utility model, person skilled in art makes the utility model Nonessential change or adjustment, still fall within the protection scope of the utility model.

The utility model term is explained:

Coating: substance A is covered on substance B surface in the form of thin layer/film using certain method.

Hot pressing: apply certain pressure while heat treatment.

Heterogeneous interface: the different interface of the substance and phase structure at both ends (in turn, homogeneity, that is, substance is identical).

Ionic conductivity: the non-electronic conductivity that electrical transmission is carried out for carrier with ion (lithium ion)；It is described in text Conductivity, if plus illustrate refer to be all ionic conductivity.

Space charge layer: it is originated from semiconductor PN concept and refers to herein due to being deposited between sulfide and oxide In biggish difference in chemical potential, Li ion spontaneous can be migrated from sulfide to oxide, to form the poor region Li in sulfide side. Due to poor Li, ionic conductivity is very low in the region.Simultaneously as oxide electrode is electron-ion mixed conductor, enrichment Li⁺Ion, can by external circuit electronics neutralize (built in field can not be formed), therefore the Li ion in sulfide can continue to It is migrated in oxide, so that the very wide poor area Li is formed, the space charge layer of this form, also known as Schottky type space electricity Lotus layer.

Oxide lithium ion conductor: can be with the oxide solid state medium of conducting lithium ions, Wen Zhongsuo under the conditions of charge and discharge Stating oxide solid electrolyte is also the same meaning.The concept of sulfide solid electrolyte described in text is similar, material Main body is changed to sulfide.

Embodiment 1

A kind of hybrid solid-state electrolyte, the hybrid solid-state electrolyte are included at least by sulfide solid electrolyte group At sulfide solid-state electrolyte layer 1 and the non-crystal oxide solid-state electricity that is made of non-crystal oxide solid electrolyte Solve matter layer 2.

The present embodiment is by improving sulphur in sulfide solid electrolyte surface recombination non-crystal oxide solid electrolyte Interface problem between compound solid electrolyte and electrode material.

Embodiment 2

The present embodiment is advanced optimized on the basis of embodiment 1, as shown in Figure 1, the hybrid solid-state is electrolysed Matter is made of one layer of sulfide solid-state electrolyte layer 1 and two layers of non-crystal oxide solid-state electrolyte layer 2；The amorphous state Oxide solid-state electrolyte layer 1 is set to 2 two sides of sulfide solid-state electrolyte layer.

When just extremely oxide, the cathode of solid state battery are lithium, using the compound of double-layer structure described in the present embodiment Solid electrolyte.

Embodiment 3

The present embodiment is advanced optimized on the basis of embodiment 1, as shown in Fig. 2, the hybrid solid-state is electrolysed Matter forms 2 by one layer of sulfide solid-state electrolyte layer 1 and one layer of non-crystal oxide solid-state electrolyte layer.

When the just extremely sulfide, such as nickel sulfide of solid state battery, when cathode is lithium, using side of the positive electrode described in the present embodiment without The single layer structure hybrid solid-state of non-crystal oxide solid-state electrolyte layer, negative side tool non-crystal oxide solid-state electrolyte layer Electrolyte；When the just extremely oxide of solid state battery, when cathode is graphite, using the tool amorphous state oxidation of side of the positive electrode described in embodiment The single layer structure hybrid solid-state electrolyte of object solid-state electrolyte layer, negative side without non-crystal oxide solid-state electrolyte layer.

Embodiment 4

The present embodiment is advanced optimized on the basis of embodiment 2 and embodiment 3, the sulfide solid electrolyte Layer 1 with a thickness of 5~1000 μm, the non-crystal oxide solid-state electrolyte layer 2 with a thickness of 0.1~10 μm；Above-mentioned thickness For the thickness limit of hybrid solid-state electrolyte described in the utility model.

The sulfide solid-state electrolyte layer 1 with a thickness of 10~400 μm, the non-crystal oxide solid-state electrolyte layer 2 with a thickness of 0.5~5 μm；The hybrid solid-state electrolyte preparation of above-mentioned thickness is the easiest.

The sulfide solid-state electrolyte layer 1 with a thickness of 20~100 μm, the non-crystal oxide solid-state electrolyte layer 2 with a thickness of 0.5~2 μm；The hybrid solid-state electrolyte performance of above-mentioned thickness is optimal.

The thickness of the sulfide solid-state electrolyte layer 1 and the thickness of the non-crystal oxide solid-state electrolyte layer 2 Selection is ionic conductivity based on solid electrolyte and structural stability and makes.

The component of the sulfide solid-state electrolyte layer 1 includes sulfide solid electrolyte.

The sulfide solid electrolyte includes crystalline state sulfide solid electrolyte or devitrified glass state sulfide solid-state electricity Xie Zhi.

The crystalline state sulfide solid electrolyte includes the sulfide or Thio-LiSICON structure of argyrodite structure Sulfide.

The sulfide of the argyrodite structure is Li₆PS₅Cl。

The sulfide of the Thio-LiSICON structure includes Li₁₀GeP₂S₁₂Or it is based on Li₁₀GeP₂S₁₂Carry out element doping The sulfide solid electrolyte obtained afterwards.

The element of the doping includes Al, Si, Ga, Sn, N, O, Cl, Br, one or more of I.

The devitrified glass state sulfide solid electrolyte includes being based on Li₂S-P₂S₅The sulfide of system is based on Li₂S- P₂S₅The sulfide of system carries out the multicomponent system sulfide obtained after element doping.

The Li₂S-P₂S₅System includes Li₂S∶P₂S₅The sulfide or Li of=70: 30 compositions₂S∶P₂S₅=75: 25 compositions Sulfide.

The component of the non-crystal oxide solid-state electrolyte layer 2 includes non-crystal oxide solid electrolyte.

The non-crystal oxide solid electrolyte is the oxide lithium ion conductor of amorphous material.

The oxide lithium ion conductor include NASICON structure, perovskite structure, garnet structure oxide in Any one.

The oxide of the garnet structure is Li₇La₃Zr₂O₁₂。

The oxide of the garnet structure is Li_6.5La₃Zr_1.5Ta_0.5O₁₂。

The present embodiment uses the sulfide solid electrolyte of high conductance for matrix, in conjunction with opposite high shear modulus and boundary The non-crystal oxide solid electrolyte thin layer of face stability is ensuring conductivity and the good accessible premise of electrolyte/electrode Under: a. improves the inhibition to Li dendrite in negative side；B. in the non-crystal oxide solid-state of side of the positive electrode diversion and non-conductive son Electrolyte layer can effectively inhibit the growth of space charge layer, reduce interface impedance；

Meanwhile the present embodiment is using the sulfide solid electrolyte of flexible relative as matrix, to anode and cathode in charge and discharge Volume change in the process has better tolerance.

Embodiment 5

By Li₂S, GeS₂And P₂S₅By 5: 1: 1 molar ratio weighing, it is encapsulated into ball grinder by ratio of grinding media to material 30: 1, with 550rpm Revolving speed ball milling 8h after, take out, grinding distribution after scraper, Reseal into tank, continue ball milling 8h.After the powder tabletting of acquisition It is heat-treated 8h at 700 DEG C, then grinds, obtains Li₁₀GeP₂S₁₂Powder.The powder of acquisition is pushed in 100MPa pressure Piece obtains sulfide matrix.

By Li₂CO₃, La₂O₃And ZrO₂Stoichiometrically Li₇La₃Zr₂O₁₂After weighing, with the revolving speed ball milling of 400rpm 24h.After the powder of acquisition is kept the temperature 8h at 1600 DEG C, liquid nitrogen quenching is poured into.The non-crystal oxide that quenching is obtained crushes And further ball milling 12h obtains non-crystal oxide powder at 550rpm.By the powder and PVDF, NMP with 7: 2: 1 ratio After mixing is sized mixing, blade coating arrives sulfide matrix both side surface, dries in 80 DEG C of vacuum drying ovens.

Obtained composite electrolyte is obtained into the good combined electrolysis of interfacial contact at 450 DEG C with 120Mpa hot pressing 3h Matter.Wherein for sulfide electrolyte layer with a thickness of 200 μm, non-crystal oxide layer is obstruction electricity with stainless steel with a thickness of 2.4 μm Pole, it is 3.8 × 10 that test, which obtains conductivity at room temperature,^-3S/cm.With LiCoO₂For anode, Li piece is cathode, and test is put Electric specific capacity is 124mAh/g, after 0.1C is recycled 50 weeks, capacity retention ratio 95.5%.

Embodiment 6

By Li₂S, GeS₂And P₂S₅By 5: 1: 1 molar ratio weighing, it is encapsulated into ball grinder by ratio of grinding media to material 30: 1, with 550rpm Revolving speed ball milling 8h after, take out, grinding distribution after scraper, Reseal into tank, continue ball milling 8h.After the powder tabletting of acquisition It is heat-treated 8h at 700 DEG C, then grinds, obtains Li₁₀GeP₂S₁₂Powder.In mass ratio 8: 1: 1 weigh Li₁₀GeP₂S₁₂, PVDF and NMP mixing size mixing, by the tape casting by the slurry coating of acquisition on a pet film, removed after drying, obtain Li₁₀GeP₂S₁₂Film.

By Li₂CO₃, La₂O₃, ZrO₂And Ta₂O₅Stoichiometrically Li_6.5La₃Zr_1.5Ta_0.5O₁₂After weighing, with 400rpm Revolving speed ball milling for 24 hours.After the powder of acquisition is kept the temperature 8h at 1600 DEG C, liquid nitrogen quenching is poured into.The amorphous state that quenching is obtained Oxide crushes the step ball milling 12h at 550rpm that goes forward side by side and obtains non-crystal oxide powder.By the powder and PVDF, NMP with 8 : after 1: 1 ratio mixing is sized mixing, Li is coated to by the tape casting₁₀GeP₂S₁₂On film, dried in 80 DEG C of vacuum drying ovens.

Obtained composite electrolyte is obtained into the good combined electrolysis of interfacial contact at 500 DEG C with 150Mpa hot pressing 2h Matter.Wherein sulfide electrolyte layer is with a thickness of 50 μm, and non-crystal oxide layer is with a thickness of 1.0 μm, using stainless steel as blocking electrode, It is 5.3 × 10 that test, which obtains conductivity at room temperature,^-3S/cm.With LiCoO₂For anode, Li piece is cathode, and test obtains electric discharge ratio Capacity is 135mAh/g, after 0.1C is recycled 50 weeks, capacity retention ratio 97.6%.

Embodiment 7

By Li₂S, P₂S₅By 70: 30 molar ratio weighing, it is encapsulated into ball grinder by ratio of grinding media to material 25: 1, with the revolving speed of 400rpm Ball milling for 24 hours after.The powder of acquisition is heat-treated 2h at 260 DEG C, obtains Li₇P₃S₁₁Powder.By Li₇P₃S₁₁Powder is in 100MPa Lower sheeting obtains sulfide electrolyte matrix.

By Li₂CO₃, La₂O₃And ZrO₂Stoichiometrically Li₇La₃Zr₂O₁₂After weighing, with the revolving speed ball milling of 500rpm 24h.After the powder of acquisition is kept the temperature 12h at 1700 DEG C, liquid nitrogen quenching is poured into.The non-crystal oxide that quenching is obtained crushes And further ball milling 12h obtains non-crystal oxide powder at 550rpm.By the powder and PVB, toluene with 8: 2: 1 ratio After mixing is sized mixing, blade coating arrives sulfide matrix both side surface, dries in 80 DEG C of vacuum drying ovens.

Obtained composite electrolyte is obtained into the good combined electrolysis of interfacial contact at 300 DEG C with 200Mpa hot pressing 5h Matter.Wherein for sulfide electrolyte layer with a thickness of 100 μm, non-crystal oxide layer is obstruction electricity with stainless steel with a thickness of 2.2 μm Pole, it is 2.6 × 10 that test, which obtains conductivity at room temperature,^-3S/cm.With LiCoO₂For anode, Li piece is cathode, and test is put Electric specific capacity is 122mAh/g, after 0.1C is recycled 50 weeks, capacity retention ratio 94.3%.

Embodiment 8

By Li₂S, P₂S₅By 75: 25 molar ratio weighing, it is encapsulated into ball grinder by ratio of grinding media to material 20: 1, with the revolving speed of 500rpm After ball milling 18h.The powder of acquisition is heat-treated 4h at 250 DEG C, obtains β-Li₃PS₄Powder.By β-Li₃PS₄Powder exists 100MPa lower sheeting obtains sulfide electrolyte matrix.

By Li₂CO₃, La₂O₃, ZrO₂And Ta₂O₅Stoichiometrically Li_6.4La₃Zr_1.4Ta_0.6O₁₂After weighing, with 500rpm Revolving speed ball milling 20h.After the powder of acquisition is kept the temperature 15h at 1650 DEG C, liquid nitrogen quenching is poured into.The amorphous state that quenching is obtained Oxide crushes the step ball milling 12h at 550rpm that goes forward side by side and obtains non-crystal oxide powder.By the powder and PVDF, NMP with 8 : after 2: 1 ratio mixing is sized mixing, sulfide matrix surface is sprayed to, is dried in 80 DEG C of vacuum drying ovens.

Obtained composite electrolyte is obtained into the good combined electrolysis of interfacial contact at 270 DEG C with 200Mpa hot pressing 5h Matter.Wherein for sulfide electrolyte layer with a thickness of 200 μm, non-crystal oxide layer is obstruction electricity with stainless steel with a thickness of 2.6 μm Pole, it is 2.3 × 10 that test, which obtains conductivity at room temperature,^-3S/cm.With LiCoO₂For anode, Li piece is cathode, and test is put Electric specific capacity is 119mAh/g, and 0.51 circulation is after 50 weeks, capacity retention ratio 94.9%.

Comparative example 1

By Li₂CO₃, La₂O₃, ZrO₂And Ta₂O₅Stoichiometrically Li_6.5La₃Zr_1.5Ta_0.5O₁₂After weighing, with 400rpm Revolving speed ball milling for 24 hours.After the powder of acquisition is kept the temperature 6h at 1100 DEG C, furnace cooling obtains Li_6.5La₃Zr_1.5Ta_0.5O₁₂Powder End.Above-mentioned powder is mixed with PVDF and NMP with 8: 1: 1 mass ratioes and is sized mixing, by the tape casting by the slurry coating of acquisition in PET It on film, is removed after drying, obtains Li_6.5La₃Zr_1.5Ta_0.5O₁₂Film；Li_6.5La₃Zr_1.5Ta_0.5O₁₂Crystalline film is with a thickness of 50 μ m。

Amorphous state Li_6.5La₃Zr_1.5Ta_0.5O₁₂Preparation method is as described in Example 6, amorphous state Li_6.5La₃Zr_1.5Ta_0.5O₁₂ Layer is with a thickness of 1.0 μm.

Using stainless steel as blocking electrode, it is 3.3 × 10 that test, which obtains conductivity at room temperature,^-4S/cm.With LiCoO₂It is positive Pole, Li piece are cathode, and it is 112mAh/g that test, which obtains specific discharge capacity, after 0.1C is recycled 50 weeks, capacity retention ratio 78.4%.

Comparative example 2

Li is prepared according to preparation method described in embodiment 6₁₀GeP₂S₁₂Film.

By Li₂CO₃, La₂O₃, ZrO₂And Ta₂O₅Stoichiometrically Li_6.5La₃Zr_1.5Ta_0.5O₁₂After weighing, with 400rpm Revolving speed ball milling for 24 hours.After the powder of acquisition is kept the temperature 6h at 1100 DEG C, furnace cooling obtains crystalline state Li_6.5La₃Zr_1.5Ta_0.5O₁₂Powder.After above-mentioned powder and PVDF, NMP are sized mixing with 8: 1: 1 ratio mixing, pass through the tape casting It is coated to Li₁₀GeP₂S₁₂On film, dried in 80 DEG C of vacuum drying ovens.

Obtained composite electrolyte is obtained into the good combined electrolysis of interfacial contact at 500 DEG C with 150Mpa hot pressing 2h Matter.Wherein sulfide electrolyte layer is with a thickness of 50 μm, and crystalline oxide layer is with a thickness of 1.0 μm, using stainless steel as blocking electrode, surveys It is 5.4 × 10 that examination, which obtains conductivity at room temperature,^-3S/cm.With LiCoO₂For anode, Li piece is cathode, and test obtains electric discharge specific volume Amount is 134mAh/g, after 0.1C is recycled 50 weeks, capacity retention ratio 37.6%.

Comparative example 1 is compound by crystalline oxide solid electrolyte and the progress of non-crystal oxide solid electrolyte, resulting The ionic conductivity of hybrid solid-state electrolyte, which is compared, described in the utility model uses sulfide solid electrolyte answering for matrix Mould assembly solid electrolyte wants low, while capacity retention ratio also wants low.

Comparative example 2 is compound by sulfide solid electrolyte and the progress of crystalline oxide solid electrolyte, resulting compound Although solid electrolyte can obtain relatively high ionic conductivity, promotion is limited, in cyclic process, due to crystalline state Oxide coating quality is harder, is easy to generate crack in electrode/electrolyte interface and oxide/sulfide interface, causes to hold Amount generates the decline of cliff of displacement formula.

Above description is not limitation of the utility model, and the utility model is also not limited to the example above.This technology neck In the essential scope of the utility model, the variations, modifications, additions or substitutions made also should belong to the those of ordinary skill in domain The protection scope of the utility model.

Claims (10)

1. a kind of hybrid solid-state electrolyte, which is characterized in that the hybrid solid-state electrolyte includes at least sulfide solid-state Electrolyte layer (1) and non-crystal oxide solid-state electrolyte layer (2).

2. a kind of hybrid solid-state electrolyte as described in claim 1, which is characterized in that the hybrid solid-state electrolyte by One layer of sulfide solid-state electrolyte layer (1) and two layers of non-crystal oxide solid-state electrolyte layer (2) composition；The amorphous state Oxide solid-state electrolyte layer (2) is set to sulfide solid-state electrolyte layer (1) two sides.

3. a kind of hybrid solid-state electrolyte as described in claim 1, which is characterized in that the hybrid solid-state electrolyte by One layer of sulfide solid-state electrolyte layer (1) and one layer of non-crystal oxide solid-state electrolyte layer (2) composition.

4. a kind of hybrid solid-state electrolyte as described in claim 1, which is characterized in that the sulfide solid-state electrolyte layer (1) with a thickness of 5~1000 μm, the non-crystal oxide solid-state electrolyte layer (2) with a thickness of 0.1~10 μm.

5. a kind of hybrid solid-state electrolyte as described in claim 1, which is characterized in that the sulfide solid-state electrolyte layer (1) with a thickness of 10~400 μm, the non-crystal oxide solid-state electrolyte layer (2) with a thickness of 0.5~5 μm.

6. a kind of hybrid solid-state electrolyte as described in claim 1, which is characterized in that the sulfide solid-state electrolyte layer (1) with a thickness of 20~100 μm, the non-crystal oxide solid-state electrolyte layer (2) with a thickness of 0.5~2 μm.

7. a kind of hybrid solid-state electrolyte as described in claim 1, which is characterized in that the sulfide solid-state electrolyte layer (1) component includes sulfide solid electrolyte.

8. a kind of hybrid solid-state electrolyte as claimed in claim 7, which is characterized in that the sulfide solid electrolyte packet Include crystalline state sulfide solid electrolyte or devitrified glass state sulfide solid electrolyte.

9. a kind of hybrid solid-state electrolyte as described in claim 1, which is characterized in that the non-crystal oxide solid-state electricity The component for solving matter layer (2) includes non-crystal oxide solid electrolyte.

10. a kind of hybrid solid-state electrolyte as claimed in claim 9, which is characterized in that the non-crystal oxide solid-state Electrolyte is the oxide lithium ion conductor of amorphous material.