EP4731574A1 - Fast preparation method for producing lithium argyrodite solid electrolyte for solid-state batteries - Google Patents

Abstract

The present invention relates in a first aspect to a battery, typically a secondary cell battery which can be recharged, in a second aspect to a an improved electrolyte for such a solid-state battery, that is, a medium that comprises ions and that is charge conducting through the movement of those ions, rather than conducting through electrons, such as in the battery, in a third aspect to a method of producing such a solid crystalline electrolyte, and in a fourth aspect to a product obtained by said method. The present invention provides and improved battery performance.

Description

P100875PC00 FAST PREPARATION METHOD FOR PRODUCING LITHIUM ARGYRODITE SOLID ELECTROLYTE FOR SOLID-STATE BATTERIES FIELD OF THE INVENTION The present invention relates in a first aspect to a battery, typically a secondary cell battery that can be recharged, in a second aspect to a an improved electrolyte for such a solid-state battery, that is, a medium that comprises ions and that is charge conducting through the movement of those ions, rather than conducting through electrons, such as in the battery, in a third aspect to a method of producing such a solid crystalline electrolyte, and in a fourth aspect to a product obtained by said method. The present invention provides and im- proved battery performance. RELATED APPLICATIONS The present application claims the benefit of priority from Dutch Patent Application NL2035165, filed on June 23, 2023, in the name of Technische Universiteit Delft, The Neth- erlands. The entire contents of the above-referenced applications and of all priority documents referenced in the Application Data Sheet filed herewith are hereby incorporated by reference for all purposes. BACKGROUND OF THE INVENTION The present invention is in the field of a secondary electrochemical cell, commonly referred to as a rechargeable battery. Such a cell is capable of generating electrical energy from (electro)chemical reactions or using electrical energy to cause (electro)chemical reac- tions, such as when recharged. The electrochemical cells which generate an electric current are called voltaic cells or galvanic cells and those that generate chemical reactions, via elec- trolysis for example, are called electrolytic cells. The present invention is focused on gal- vanic cells, such as a battery. A battery may consist of one or more cells. Cells can be con- nected in parallel, in series, or a combination thereof. When discharged/recharged such a cell effectively is both a galvanic cell and an electrolytic cell. It is used to store electric energy upon charging, and to deliver electric energy during discharging. A single valence ion battery, such as lithium-ion battery or sodium-ion battery, may be used for energy storage, which may be a type of rechargeable battery. These single va- lence cation batteries are widely used, such as for portable electronics, electric vehicles, and electrical energy storage devices. In the batteries, lithium ions may move back and forth, from the negative electrode to the positive electrode during discharge, and vice versa when charging. For rechargeable cells, the term cathode designates the electrode where reduction is taking place during the discharge cycle; for lithium-ion cells, the positive electrode is re- ferred to as cathode, which typically is the lithium-based one. Li-ion batteries may use an in- tercalated lithium compound as one electrode material. The batteries have certain advantages over other electric energy storage devices, such as a relatively high energy density, low self- discharge, and no memory effect. Typical density characteristics are a specific energy den- sity of up to 250 Wh/kg, a volumetric energy density of up to 700 Wh/l, and a specific power density of up to 1500 W/kg. The performance of the batteries can be improved, such as in terms of life extension, energy density, safety, costs, and charging speed. The present invention in particular relates to a solid state battery. A solid-state battery that uses solid electrodes and a solid electrolyte, instead of the typically used liquid or poly- mer gel electrolytes, such as those found in lithium-ion batteries. Several drawbacks have prevented widespread application of these batteries. On the other hand solid-state batteries are considered to provide solutions for many problems typically occurring in liquid Li-ion batteries, such as flammability, limited voltage, lithium dendrite growth, unstable solid-elec- trolyte interphase formation, poor cycling performance and strength. Materials proposed for use as solid electrolytes in solid-state batteries include ceramics, and solid polymers. These materials are potentially safer, with higher energy densities, but at a much higher cost, com- pared to the liquid variant. Challenges to widespread adoption include energy and power density, durability, material costs, sensitivity, stability, capacity, ion depletion, charging speed, and cycling performance of power supply units. In addition prior art devices tend to have too many inactive parts and/or too large inactive part. Some of these devices have inter- nal mechanical stress, a lower capacity, and shortening of cycle life. In this respect Si could be considered as anode material, but it is often not suited in view of its large volumetric ex- pansion when forming Li_xSi_y (such as Li_4.4Si). Some materials are considered for solid-state electrolytes, such as argyrodite; the term may refer to an uncommon silver germanium sulphide mineral with formula Ag₈GeS₆. However, this is not the material of interest. The argyrodite group of minerals encompasses various other sub-groups, other than the Ag-comprising one. The term argyrodite is thus also used for other materials with a similar crystal structure, in particular lithium based argy- rodite-type materials, which actually have received interest from researchers as a potential solid-state electrolyte for lithium-ion batteries. These materials provide some improvements over e.g., prior art materials, such as garnet-type materials, or NASICON-like, e.g. in terms of ionic conductivity. However, production methods are typically expensive, and a quality of the obtained materials is still sub-optimal. Also, only relatively large particles are produced, typically in the order of 10 µm or orders of magnitude larger. Li-ion batteries usually consist of a LiCoO₂ cathode and graphite anode. During charging Li ions are transported towards and absorbed by the electrode, typically a graphite electrode, by intercalation of the Li ions in planar atomic graphite structure. The specific ca- pacity of materials used in these batteries is in the order of 372 mAh/g (Ashuri et al., Na- noscale, vol.8, 74 (2016)). It is typical to use one Li-ion or Na-ion salt, and sometimes to use two salts, of which one is than a dominant salt, with a higher concentration, typically LiPF6. Typically, a liquid Li-ion battery electrolyte further comprises at least two solvents, for example EC/DMC, and a few additives. If an electric potential is applied to the battery cations are drawn to the electrode that has an abundance of electrons, while the anions are drawn to the electrode that has a deficit of electrons. The movement of anions and cations in opposite directions within the battery amounts to an electrical current. So, when electrodes are in contact with the electrolyte, and a voltage is applied to the electrodes or is obtained from the electrodes, the electrolyte will conduct charges. An electrochemical reaction will occur as a consequence, at the cathode, providing electrons to the electrolyte and the electrolyte providing ions to the electrodes. An- other electrochemical reaction will occur at the anode, consuming electrons from the electro- lyte. As a result, a charge distribution, such as in the form of a negative charge cloud, which typically also has a gradient, forms around the cathode, and likewise a positive charge forms around the anode. Without the ions, the charges around the electrode would slow down con- tinued electron flow; diffusion of charged species to the other electrode is limited. In batter- ies, two materials with different electron affinities are used as electrodes; electrons flow from one electrode to the other outside of the battery, while inside the battery the circuit is closed by the electrolyte's ions. Here, the electrode reactions may convert chemical energy to electrical energy. Incidentally, Huang Wenze et al. (https://doi.org/10.1039/D0MA00115E) recites the conduction mechanism in oxygen-substituted lithium conductors composed of the Li_6.15Al_0.15Si_1.35S_6−xO_x (LASSO) system, a member of the argyrodite-type family and has su- perionic conductivities, making it suitable for all-solid-state batteries. The crystal structures, ionic conductivities, and electrochemical properties of these systems were examined using powder X-ray and neutron diffractometry combined with impedance spectroscopy and cyclic voltammetry measurements. WO 2022/210471 A1 recites a solid electrolyte containing Li, P, S, a halogen, and element M (where M represents at least one element from among silicon (Si), tin (Sn), antimony (Sb), germanium (Ge), and boron (B)), the solid electrolyte including a crystal phase that has an argyrodite-type crystal structure. The molar ratio S/(P+M) of S relative to the total of P and element M satisfies 3.5. US 2022/166056 A1 recites a lithium- argyrodite ionic superconductor containing a halogen element and a method for preparing the same, wherein an argyrodite-type crystal structure can be maintained and lithium ion conductivity can be improved by combining specific elements at a specific molar ratio. US 2021/119247 A1 recites a sulfide-based lithium-argyrodite ion superconductor containing multiple chalcogen elements and a method for preparing the same. More specifically, pro- vided are a sulfide-based lithium-argyrodite ion superconductor containing multiple chalco- gen elements and a method for preparing the same that are capable of significantly improv- ing lithium ion conductivity by substituting a sulfur (S) element in a PS43- tetrahedron with a chalcogen element such as a selenium (Se) element, other than the sulfur (S) element, while maintaining an argyrodite-type crystal structure of a sulfide-based solid electrolyte represented by Li6PS5Cl. The present invention therefore relates to an improved power supply unit, in particu- lar a battery, which solves one or more of the above problems and drawbacks of the prior art, providing reliable results, without jeopardizing functionality and advantages. SUMMARY OF THE INVENTION It is an object of the invention to overcome one or more limitations of power supply units of the prior art and methods of making these and at the very least to provide an alterna- tive thereto. The present invention provides an improved electrolyte for a solid-state battery, such as in terms of electrolytes with higher ion conductivity, and a faster and more energy efficient synthesis method of the solid electrolyte material. High conductivities are consid- ered to be required for fast charging, and for high power applications, and more generally provides a more efficient use of the electrode capacities. Existing synthesis methods are time- and energy consuming (such as an annealing time of seven to fourteen days at 550 °C), and consume more energy, while producing only small amounts of solid electrolytes. Inven- tors developed a synthesis method that can produce the materials in a much more efficient way. It is noted that Lithium argyrodite superionic conductors have gained attention as po- tential solid electrolytes for all-solid-state batteries, in view of their high ionic conductivity, and ease of processing. These materials provide the ability to introduce halides (Li_6-xPS_{5- x}Hal_1+x, Hal = Cl, Br and I) into the argyrodite crystal structure, which may greatly impact the lithium distribution over a wide range of the accessible crystal sites. Also, a structural disorder between the S2− and Hal− anion on Wyckoff 4d site is provided. Both are found to strongly influence ionic conductivity. In the present invention the argyrodite synthesis method is different from the prior art and leads to an increase of the (therefore higher) ionic conductivity as well as fast crystallization method of argyrodites family. Inventors specifi- cally investigated the effect of bromide substitution on lithium argyrodite (Li_6−xPS_5−xHal_1+x, Hal = Cl, Br, I, Cl_yBr_1-y, and Cl_0.33Br_0.33I_0.33 with a range of 0.0 ≤ x ≤ 0.5) and engineered structural disorder by changing the synthesis protocol. A correlation was found between lith- ium substructure, structural disorder, and ionic transport, e.g. using X-ray diffraction, neu- tron diffraction, and electrochemical impedance spectroscopy. Inventors found that higher ionic conductivity is can obtained with a lower average negative charge on the 4d site, lo- cated in the centre of the Li+ “cage”, as a result of the partial replacement of S2− by halide and mixed halide. This promoted Li-ion diffusivity across the unit cell. Additionally and ex- tra T4 Li+ site was identified, which opened the additional pathway for long-range lithium- ion diffusion. The ionic conductivity is increased up to 9-10 mS cm-1, for exemplary quenched Li_5.5PS_4.5Br_1.5, having the relatively highest degree of structural disorder, which is an 11-fold improvement compared to slow-cooled Li₆PS₅Br having the relatively lowest de- gree of structural disorder. Moreover, modifying the synthesis method for chloride-rich argy- rodite to include increased pressure during the synthesis and a higher chloride content re- sulted in a 5-fold improvement in ionic conductivity compared to Li₆PS₅Cl. Structural disor- der and halide substitution are found to impact the lithium substructure, and transport proper- ties, which may be tuned through the present synthesis method, e.g. for achieving higher ionic conductivity. In a first aspect the present invention relates to an electrolyte for a solid- state battery comprising at least one solid single crystalline electrolyte wherein the solid sin- gle crystalline electrolyte is selected from at least one of A_6-xZE_5-xHal_1+x and A_6+xZ_1-xM_1-xE_{5- x}Hal_1+x, wherein A is selected from Li, Na, and first combinations thereof, wherein Z is se- lected from P, As, Sb, and second combinations thereof, wherein M is selected from Si, As, Ge, As, Sn, and Sb, and third combinations thereof, wherein E is selected from O, S, Se, Te, and fourth combinations thereof, wherein Hal is selected from Cl, Br, I, or mixed halide, that is fifth combinations thereof, and wherein x is from <-1;1.0], in particular from <-1;0.75], in particular wherein x is not from -0.9--1. The term solid single-phase crystalline electrolyte as used herein refers to a solid electrolyte which is single-phase crystalline. The term crystalline is a well-known chemical term for a solid material which constituents (such as atoms, mole- cules, or ions) are arranged in a highly ordered microscopic structure, forming a crystal lat- tice that extends in all directions. Three forms or main categories of crystalline are i) single crystalline, also known as monocrystalline, ii) polycrystalline, and iii) amorphous. In a sin- gle crystalline material the crystal lattice of the entire sample is continuous and unbroken to the edges of the sample, with no grain boundaries. The atoms are in a near-perfect arrange- ment. In polycrystalline materials the material is composed of many microscopic crystals, which are called crystallites or grains. Although a polycrystal is a crystal with a periodic ar- rangement of atoms, the polycrystal as a whole does not have a periodic arrangement of at- oms, because the periodic pattern is broken at the grain boundaries. Within the group of pol- ycrystalline materials there may be some variety in the number of grain types. If a polycrys- tal consists of one type of grains, the particular polycrystal is called a single-phase polycrys- tal. If a polycrystal consists of more types of grains, such as for example three types, such polycrystal is called a three-phase polycrystal. Solids that are neither single crystalline nor polycrystalline, such as glass, are called amorphous solids, and have no periodic arrange- ment, not even microscopically. The present invention relates to a solid electrolyte which is single phase crystalline, which is thus arranged in a particular structure with higher lithium- ion mobility in a unit cell. A single crystalline material may be in the form of a mixed crys- tal. A mixed crystal refers to a crystal which comprises two or more elements, also known as ions, or molecules, which occupy different sites of the crystal lattice. Such elements can re- place each other in the crystal lattice due to their similar molecular structure and shape. The abbreviations Fe, Mn, Li, Na, Co, Ni, Al, Sn, Mg, Ag, P, As, Sb, In, Si, B, C, N, Ge, O, H, Sn, S, Se, Te, F, Cl, Br and I, as used in the present disclosure, refer to the particular chemi- cal elements which are known from the periodic table of elements, and refer e.g. to Lithium (Li), Sodium (Na), Phosphorus (P), Arsenic (As), Antimony (Sb), Silicon (Si), Arsenic (As), Germanium (Ge), Tin (Sn), Oxygen (O), Sulphur (S), Selenium (Se), Tellurium (Te), Chlo- rine (Cl), Bromine (Br) and Iodine (I). Terms like alloy, transition metal and transition metal alloy as used herein are known to the skilled person. An allow is the common chemical name for a mixture of chemical elements of which at least one is a metal, which results in an im- pure substance that retains the characteristics of a metal. Transition metals, also known as transition elements, are the chemical elements of the d-block of the periodic table (groups 3 to 12). It is demonstrated that solid single phase crystalline electrolytes of the invention have great benefits over electrolytes from the prior art, e.g. in terms of their ionic conductivity. In a second aspect the present invention relates to a solid state battery comprising at least one first electrode, at least one second electrode, in between the first and second elec- trode and in contact with the first and second electrode at least one solid state single Phase crystalline electrolyte as taught herein. In a third aspect the present invention relates to a method of producing a solid crys- talline electrolyte, wherein the to be produced solid electrolyte comprises at least one of A_{6- x}ZE_5-xHal_1+x and A_6+xZ_1-xM_1-xE_5-xHal_1+x, wherein A is selected from Li, Na, and first combi- nations thereof, wherein Z is selected from P, As, Sb, and second combinations thereof, wherein M is selected from Si, Ge, As, Sn, and Sb, and third combinations thereof, wherein E is selected from O, S, Se, Te, and fourth combinations thereof, wherein Hal is selected from Cl, Br, I, and fifth combinations thereof, and wherein x is from <-1;1.0], in particular from <-1;0.75], in particular wherein x is not from -0.99 to -1, providing precursors in sub- stantially molar amounts and forming a mixture thereof, wherein precursors are selected from A, M, Z, E, combinations of ZE, and from AHal, in particular wherein E is provided in an excess amount of 1.01-1.2 times the molar amount, milling the mixture during a milling time therewith obtaining a milled mixture, heating the milled mixture at an elevated tempera- ture during a heating time therewith forming electrolyte, and cooling the heated mixture therewith obtaining solid crystalline electrolyte. The phrase “molar amount” as used herein is a chemical expression which is well known to the skilled person. It refers to the expression of the amount of a material, compound or element in moles (mol), and is known to be calcu- lated by dividing mass (g) by the molar mass (g/mol) of the material, compound or element. The term “substantially” herein, will be understood by the person skilled in the art, and may also include embodiments with “entirely”, “completely”, “all”, etc. Hence, in embodiments the adjective substantially may also be removed. Where applicable, the term “substantially” may also relate to 90% or higher, such as 95% or higher, especially 99% or higher, even more especially 99.5% or higher, including 100%. The terms heating and cooling are known to the skilled person. Both the heating as well as cooling may comprise or consist of any possible way to heat the milled mixture or to cool the heated mixture. Cooling is preferably carried out in the form of quenching or in a form comprising quenching. Quenching is a known term, e.g. from material science, and refers to rapid cooling of a material in a fluid, such as water, liquid nitrogen, oil, polymer, other fluids, or in air. Quenching is preferably carried out in a fluid, preferably in water or liquid nitrogen, in particular in water. In general, quenching prevents potentially undesired low-temperature processes by reducing the win- dow of time during the cooling process. The inventors synthesized Bromide, Chloride and Iodide -enriched lithium argyrodites Li_6−xPS_5−xHal_1+x with compositions ranging from x = 0.0 to 0.5 using two cooling methods, that is executed chemical reactions to form a more complex molecule from chemical precursors. It was found that cooling method controlled the halide structural disorder as on 4d site in the Li_6−xPS_5−xHal_1+x series. Rietveld refinement against X-ray diffraction, and neutron diffraction is analyzed the occupancies of cations and anions, and lithium substructure. As the halide content increased, the Li+ ions move away from the center of the cage (4d site), as indicated by R_mean (Average mean lithium distance) and higher long-range connection between lithium cages. In the case of Bromide-rich argy- rodite, the slow-cooled method resulted in an increase in ionic conductivity from 0.78 mS cm-1 (Li₆PS₅Br) to 6.2 mS cm-1 (Li_5.5PS_4.5Br_1.5), while the quenched method showed an in- crease from 3.21 mS cm-1 (Li₆PS₅Br) to 9.0 mS cm-1(Li_5.5PS_4.5Br_1.5). These findings demon- strate how chemical changes and synthesis conditions affect the structural disorder and lith- ium substructure in order to tailor the transport properties of these materials. It is also demonstrated that the method of the present invention provides for a synthesis method which is faster and more efficient in terms of time needed as well as in terms of costs. In a fourth aspect the present invention relates to a product obtained by the method as taught herein, wherein the product is crystalline, in particular single phase crystalline mate- rial. In a fifth aspect the present invention relates to a system for power supply comprising at least one solid-state battery as taught herein. The present invention provides a solution to one or more of the above mentioned problems and overcomes drawbacks of the prior art. In addition, a very fast synthesis is pro- vided, typically an order of magnitude faster. Advantages of the present description are detailed throughout the description. DETAILED DESCRIPTION OF THE INVENTION In an exemplary embodiment of the present solid electrolyte for a solid-state battery, the solid electrolyte is in the form of single crystalline particles, wherein the particles have a size distribution with an average size of 200-5000 nm, in particular 300-1000 nm, and wherein a standard deviation of the size distribution is 2-20% relative to the average size, in particular 5-12% relative to the average size, as measured with a Shimadzu SALD- 7500nano. The phrase 'size distribution with an average size’ refers to the way wherein the size of particles is generally described. As using a single average number for describing the average size of particles does not provide information on how much and to what extend the particle sizes are distributed around an average number, the average size normally goes to- gether with a particular standard deviation in order to describe the distribution. The skilled person knows that, next to a certain average number of size, the width of the size distribution provides insight of a particular particle size distribution. A suitable method of measuring the said particle size distribution is by using a Shimadzu SALD-7500nano instrument, which is a laser diffraction particle size instrument, having a measurement range of 7 nm to 800 µm. In an exemplary embodiment of the present solid electrolyte for a solid-state battery, the solid electrolyte is a mixed crystal. A single phase crystalline material may be in the form of a mixed crystal. The term mixed crystal as used herein refers to a crystal which comprises two or more elements, also known as ions, or molecules, which occupy different sites of the crystal lattice. Such elements can replace each other in the crystal lattice due to their similar molecular structure and shape. In an exemplary embodiment of the present solid electrolyte for a solid-state battery, at least one of first combinations, second combinations, third combinations, fourth combina- tions, and fifth combination is present, in particular wherein two or three of said combi-na- tions are present. The first, second, third, fourth and fifth combinations as used herein refer to the com- binations as described in the first aspect of the present invention, wherein A is selected from Li, Na, and first combinations thereof, wherein Z is selected from P, As, Sb, and second combinations thereof, wherein M is selected from Si, As, Ge, Sn, and Sb, and third combina- tions thereof, wherein E is selected from O, S, Se, Te, and fourth combinations thereof, wherein Hal is selected from Cl, Br, I, and fifth combinations thereof. In an exemplary embodiment of the present solid electrolyte for a solid-state battery, a unit cell of the solid electrolyte comprises a plurality of crystallographic Hal-sites (Wyckoff 4a), respectively, wherein a first of said crystallographic Hal-site is partly occupied by E and Hal, in particular a Wyckoff 4a Hal-site and a Wyckoff 4d Hal-site, in particular having a crystal site Hal distribution, in particular Hal distribution wherein a first site is occupied for up to 95%, in particular up to 88%, more in particular up to 60%, even more in particular up to 37%, wherein a second site is occupied for more than 5%, in particular for 12-80%, more in particular for 40-75%. In materials science, crystal lattice structures are the primary met- rics used to measure the structure–property paradigm of a crystal structure. Crystal com- pounds are understood by the number of various atomic chemical settings, which are associ- ated with Wyckoff sites. In crystallography, a Wyckoff site is a point of conjugate sym- metry. Therefore, features associated with the various atomic settings in a crystal can be fed into the input layers of deep learning models. Methods to analyse crystals using Wyckoff sites can help to predict crystal structures. The term crystallographic sites as used herein re- fers to sites in the crystal lattice, being the positions of elements (atoms, molecules, etc.) within the lattice. In an exemplary embodiment of the present solid electrolyte for a solid-state battery, the solid single crystalline electrolyte has at least one site disorder of 1-75%, in particular at least one site disorder of 15-70%, more in particular at least one site disorder of 25-65%, such as 30-55%, in particular two or three site disorders. The term site disorder, as used herein, also known as crystallographic disorder, refers to the co-crystallization of more than one rotamer, conformer, or isomer where the centre of mass of each form is identical. As a consequence of disorder, the crystallographic solution is the sum of the various forms. Disor- der, in particular anion disorder, thus refers to the random arrangement of various anions within the same crystallographic site. Because of the periodicity of crystals, every object is regularly repeated in three-dimensional space, however in the case of disorder, the orienta- tions of some atoms differ in different unit cells. The synthesis method as developed by the present inventors, was found to control disorder in order to further improvement of the elec- trolyte of the present invention in a higher ionic conductivity. In an exemplary embodiment of the present solid electrolyte for a solid-state battery, the solid single crystalline electrolyte has an ion conductivity of > 1 mScm-1, in particular of > 8 mScm-1, such as of 10-50 mScm-1. The term ion conductivity as used herein refers to a measure of a substance's tendency towards ionic conduction. Ionic conduction means the movement of ions. In most solids, ions rigidly occupy fixed positions, strongly embraced by neighbouring atoms or ions. In other solids, selected ions are highly mobile allowing ionic conduction. Materials like electrolytes for batteries do have this property. Ion conductivity is expressed in Siemens per meter (S/m), and depending on the particular value, ion conductiv- ity can thus also be expressed in milliSiemens (mS/cm), microSiemens (μS/cm), per unit length, etc. In an exemplary embodiment of the present solid electrolyte for a solid-state battery, the solid single crystalline electrolyte has a crystallinity of >95%, in particular > 98%, such as > 99%, and/or wherein the unit cell of the solid single crystalline electrolyte has a plural- ity of A-crystal sites, in particular a Wyckoff T2-site, a Wyckoff T4-site, a Wyckoff T5a site, and a Wyckoff T5 site, wherein at least two of the plurality of A-crystal sites are partly or fully occupied by A, in particular three or four A-crystal sites, and having a crystal site A distribution, in particular an A distribution wherein a first site is occupied for more than 55%, wherein a second site is occupied for 1-25%, in particular for 10-20%, wherein a third site is occupied for less than 26%, in particular 0-10%, and wherein a fourth site is occupied for a remainder of the A-occupation, as determined with neutron diffraction data, in particu- lar from Rietveld refinement thereof, and/or wherein solid single phase crystalline electrolyte has a capacitances of 0.1 to 20 x 10-10 F cm-2, in particular of 1 to 10 x 10-10 F cm-2, and/or wherein solid single crystalline electrolyte has an α value of 0.89−0.97 represent the bulk transport, grain boundary contribution has not been observed. The term crystallinity as used herein refers to the degree of structural order in a solid. In a crystal, the atoms and/or molecules are arranged in a regular and periodic way. The de- gree of crystallinity can have influence on characteristics like hardness, density, transparency diffusion, and higher ionic conductivity. In an exemplary embodiment of the present solid-state battery, the material of the cath- ode is selected from Fe comprising cathodes, from Mn comprising cathodes, from Li or Na comprising cathodes, from Co comprising cathodes, from transition metal alloys, from Ni comprising cathodes, in particular from nickel comprising alloys, more in particular from nickel alloys with >75% Ni, such as > 80 atom% Ni, and/or wherein the anode comprises a material selected from alloys, in particular from Al-alloys, from Sn-alloys, from Mg-alloys, from Ag-alloys, from Sb alloys, from In alloys, and from silicon alloys (a-Si_yA_x:Q_z), wherein element A is selected from B, C, N, Ge, O, and combinations thereof, wherein element Q is selected from H, F, and combinations thereof, and from silicon, wherein the silicon alloy or silicon is porous for accommodating electrolyte ions, such as Li ions, wherein the silicon alloy or silicon has a porosity from 1-50%, wherein the silicon alloy or silicon is amorphous, and wherein the silicon or silicon alloy is preferably hydrogenated, from conversion-type an- ode materials, in particular from metal sulphides, metal oxides, metal phosphides, metal ni- trides, metal fluorides, and metal selenides, more in particular wherein the metal thereof is a transition metal, from carbon based compounds, such as graphite, and graphene, and from a Li- or Na- metal anode, and/or wherein the at least one first electrode and/or the at least one second electrode comprise a nano-crystalline material. The term porosity as used herein refers to the fraction of voids per unit volume of the particular material, such as silicon or silicon alloy; or in other words the ratio between the total volume of the pores to the volume of the material as a whole. A volume fraction is ex- pressed in percentage. This may in general easily be determined by techniques such as weight measurement. The term nano-crystalline material as used herein refers to a known category of crystalline materials which are ultrafine-grained single-phase or multiphase poly- crystals with grain sizes in the range of 1–100 nm. In an exemplary embodiment of the present solid-state battery, the battery further comprises at least one separator, wherein the at least one separator is provided in between the at least one solid state crystalline electrolyte and the first or second electrode, respec- tively. In an exemplary embodiment of the present solid-state battery, the at least one first electrode has a thickness of 50-500 µm, in particular 100-300 µm, such as 150-250 µm, and/or the at least one second electrode has a thickness of 20-300 µm, in particular 40-200 µm, such as 50-100 µm, and/or wherein the at least one solid state crystalline electrolyte has a thickness of 100-1000 µm, in particular 200-800 µm, such as 300-500 µm. In an exemplary embodiment of the present method of producing a solid crystalline electrolyte, the milling time is from 10-60 minutes, in particular 20-30 minutes, and/or wherein milling is performed at a rpm of 500-600 rpm, in particular 505-520 rpm, and/or wherein a pressure during formation of the electrolyte is applied, in particular a pressure from 49-500 MPa, in particular 100-200 MPa, during a pressure time of 10-60 seconds, such as 20-40 seconds, wherein the milled mixture is heated to a heating temperature of 400-550 °C, and/or during a heating time of 5-120 minutes, in particular 20-105 minutes, and/or wherein cooling is from the heating temperature to a temperature of 15-30 °C, during a cool- ing time of 1-30 seconds. In an exemplary embodiment of the present method of producing a solid crystalline electrolyte, the heating temperature is from 300-750 °C, in particular 400-550 °C, and/or the heating time is from 1- 10 minutes, in particular wherein a pre-heated oven at the heating temperature is used. In an exemplary embodiment of the present method of producing a solid crystalline electrolyte, the precursors are selected according to; A is selected from Li, Na, and first combinations thereof, Z is selected from P, As, Sb, and second combinations thereof, M is selected from Si, Ge, As, Sn, and Sb, and third combinations thereof, E is selected from O, S, Se, Te, and fourth combinations thereof, Hal is selected from Cl, Br, I, and fifth combina- tions thereof, in particular wherein precursors are selected from Li, P, S, Si, Cl, Br, and I, and combinations of A, Z, M, E, and Hal, in particular AHal, and ZE, Such as LiHal, and P₄S₁₀, and with the proviso that Li₂S is not selected. The invention will hereafter be further elucidated through the following examples which are exemplary and explanatory of nature and are not intended to be considered limit- ing of the invention. To the person skilled in the art it may be clear that many variants, being obvious or not, may be conceivable falling within the scope of protection, defined by the present claims. SUMMARY OF THE FIGURES Figs.1-10, 11a-f and 12 show schematic views or representations as well as experi- mental results of the present invention. FIGURES In the figures: 10 first electrode 20 second electrode 30 solid state electrolyte 41 first separator 42 second separator Figure 1 shows a schematical solid-state battery, with a first electrode 10, typically a Li-comprising electrode, a second electrode 20, typically a composite electrode, optional separators 41,42, such as polymeric and/or ceramic separators, and in the middle a solid-state electrolyte. Separators are mostly not used. The battery provides a voltage V over the +/- electrodes, respectively. Figure 2 shows a schematic perspective view of a solid-state battery, with a first elec- trode 10, the anode, a second electrode 20, the cathode, and in the middle a solid-state elec- trolyte 30 which is in electrical contact with the first and second electrode. Such a solid-state battery typically has a shape which is substantially cylindrical, or likewise prismatic, and has a particular width x and height y which may vary. In view of the present disclosure the electrolyte 30 comprises at least one solid single phase crystalline electrolyte wherein the solid single crystalline electrolyte may comprise at least one of A_6-xZE_5-xHal_1+x and A_6+xZ_1-xM_1-xE_5-xHal_1+x, wherein A is selected from Li, Na, and first combinations thereof, wherein Z is selected from P, As, Sb, and second combina- tions thereof, wherein M is selected from Si, As, Ge, Sn, and Sb, and third combinations thereof, wherein E is selected from O, S, Se, Te, and fourth combinations thereof, wherein Hal is selected from Cl, Br, I, and fifth combinations thereof, and wherein x is from <-1;1.0], in particular from <-1;0.75], in particular wherein x is not from -0.99--1. The material of the cathode, which is second electrode 20, may be selected from Fe comprising cathodes, from Mn comprising cathodes, from Li or Na comprising cathodes, from Co comprising cathodes, from transition metal alloys, from Ni comprising cathodes, in particular from nickel comprising alloys, more in particular from nickel alloys with >75% Ni, such as > 80 atom% Ni; The material of the anode, which is first electrode 10, may or may in addition com- prise a material selected from alloys, in particular from Al-alloys, from Sn-alloys, from Mg- alloys, from Ag-alloys, from Sb alloys, from In alloys, and from silicon alloys a-Si_yA_x:Q_z, wherein element A is selected from B, C, N, Ge, O, and combinations thereof, wherein ele- ment Q is selected from H, F, and combinations thereof, and from silicon, wherein the sili- con alloy or silicon is porous for accommodating electrolyte ions, such as Li ions, wherein the silicon alloy or silicon has a porosity from 1-50%, wherein the silicon alloy or silicon is amorphous, and wherein the silicon or silicon alloy is preferably hydrogenated, from conver- sion-type anode materials, in particular from metal sulphides, metal oxides, metal phos- phides, metal nitrides, metal fluorides, and metal selenides, more in particular wherein the metal thereof is a transition metal, from carbon based compounds, such as graphite, and gra- phene, and from a Li- or Na- metal anode. First electrode 10 and/or second electrode 20, may or may in addition comprise a nano- crystalline material. In solid-state batteries the electrolyte may function as separator between the anode and the cathode. However, the solid-state battery may further comprise at least one separator. Optional additional separators are not shown in fig.2, but are shown in schematic solid-state battery of fig.1 (41, 42). Such optional at least one separator is provided in between electro- lyte 30 and the first 10 or second electrode 20. First electrode 10 preferably has a thickness a of 50-500 µm, in particular 100-300 µm, such as 150-250 µm. Second electrode 20 preferably has a thickness b of 20-300 µm, in particular 40-200 µm, such as 50-100 µm. Electrolyte 30 preferably has a thickness c of 100-1000 µm, in particular 200-800 µm, such as 300-500 µm. Figure 3 shows a schematic representation of the crystal structure of an argyrodite- type Li₆PS₅X. In this particular example the crystal structure of Li₆PS₅Br is shown in an an- ion ordered state with Br− located on the Wyckoff 4a site and the sulphide anion (S2−) on the Wyckoff 4d site. The crystal structure is shown in the ordered structure with space group F- 43m; the halide ions arrange in a face-centred cubic lattice (Wyckoff position 4a) with PS₄3− polyhedra located in the octahedral voids (P on Wyckoff 4b and S on Wyckoff 16e) and a “free” S2− (not bound in polyhedra) in half of the tetrahedral sites, Wyckoff 4d. Li+ forms an arrangement similar to a cage around the 4d site. In this particular example the letters y and z represent partial substitutes in the lattice structure: y represents partially substituted S > Se, and z represents partially substituted P < Si, Ge, Sn, As. Figure 4 shows the occupancy of various Li sites in the argyrodite series by quench- ing and slow cooling method as a function of bromide content. The left-side three bars (0, 0.3 and 0.5) represent quenching as a cooling method, the right-side three bars (0, 0.3 and 0.5) represent slow cooling as a cooling method. Figure 5 demonstrates the ionic conductivity as a function of % of site disorder. The measurement was carried out at room temperature and relates to an example electrolyte of Li₆PS₅Br with a Br−/S2− site-disorder. The obtained room temperature conductivities are demonstrated in figure 5 as a function of the Br−/S2− site-disorder. It is clearly demonstrated that increasing disorder leads to an improvement, that is, an increase of the ionic conductiv- ity. Figure 6 demonstrates the site-disorder as a function of % Br content in lithium argy- rodite with two cooling methods. Slow-cooled samples (Li₆PS₅Br) have a lower site-disor- der, as determined by Rietveld refinements of the neutron diffraction patterns. As the total Br content increases, the site-disorder increases, starting from 12% at x = 0.0 and reaching 63% at x = 0.5 for the slow-cooled method. The quenched method has an even higher site-disor- der, starting from 39% at x = 0.0 to 72% at x = 0.5, most likely because fast cooling "freezes in" the higher site-disorder that is achieved at higher temperatures. Figure 7 shows percentage of Br content distributed across Wyckoff 4a sites, and to- tal Br content in each composition (Li_6−xPS_5−xBr_1+x) as a function of x. Figure 8 demonstrates the XRD spectra according to an example electrolyte Li_5.5PS_4.5Cl_1.5 which was synthesized by the method of the present invention under different pressures (MPa). The electrolyte was synthesized under 98, 245 and 490 MPa, respectively. The bottom lines 1-3 represent the electrolyte synthesized under 98 MPa, the line called ex- ample 4 represents the electrolyte synthesized under 245 MPa, and the two lines 5 and 6 on top represent the electrolyte synthesized under 490 MPa. The different examples relate to different approaches to produce the particular electrolytes. First a hand press was used at dif- ferent pressures, followed by a heating step of 500 °C for 15 minutes. Example 1 shows XRD pattern of initial precursor Li2S, P2S5, LiCl Example 2 shows XRD pattern of 3 cycles (15 min ) ball milling (BM) samples of Li2S, P2S5, LiCl. Example 3 shows XRD pattern of 3 cycles (15 min) BM precursors, press the powder manually. For the first three examples hand press was used at 98 MPa pressure to form the pellet and was then heated at 500 C for 15 minutes to form the crystalline Li_5,5PS_4,5Cl_1,5. Example 4 shows XRD pattern of 3 cycles (15 min) BM precursors, pressing of the powder was performed manually. For example 4 a hand press was used at 245 MPa pressure to form the pellet and was then heated at 500 C for 15 minutes to form the crystalline Li_5,5PS_4,5Cl_1,5. Example 5 shows XRD pattern of 3 cycles (15 min) BM precursors, pressing of the powder was performed manually. For example 5 a hand press was used at 490 MPa pressure to form the pellet and was then heated at 500 C for 15 minutes to form the crystalline Li_5,5PS_4,5Cl_1,5. Example 6 shows a repetition of Example 5. It is demonstrated that when the pressure as used during the synthesis method is increased, the intensity (counts) of the XRD spectrum increases accordingly. Figure 9 demonstrates the ionic conductivity as a function of applied pressure in the synthesis method of the present invention. The reference numbers 3, 4, 5 and 6 in figure 9 refer to the examples 3, 4, 5 and 6 as described in the figure description of figure 8. Example 3 was synthesized under pressure of 98 MPA, example 4 under 245 MPa and examples 5 and 6 under a pressure of 490 MPa. In this particular example it concerns Li_5.5PS_4.5Cl_1.5 electrolyte, which was synthe- sized under 98, 245 or 490 MPa respectively. For the particular examples 3, 4, 5 and 6, synthesized under pressures of respectively 98, 245, 450 and 450 MPa, the resulting ionic conductivities were as follows: Pressure (MPa) Ionic conductivity mS/cm 98 8.58 245 10.7 450 10.8 450 11.2 It is demonstrated that when the electrolyte was synthesized either under 245 or under 490 MPa, the resulting electrolyte has a much higher ionic conductivity as compared to an elec- trolyte which was synthesized under a pressure of 98 MPa. Figure 10 demonstrates the ionic conductivity as a function of x in the general for- mula of the electrolyte Li_6-xPS_5-xBr_1+x. Ionic conductivity was determined for electrolytes wherein x was respectively 0 or 0.3 or 0.5. It is clearly demonstrated that with increasing value of x from 0 to 0.5, the ionic conductivity as determined increased accordingly. Addi- tionally, it was found that the result was different depending on the particular way of cooling was applied: either a method step of slow cooling was applied, or a method step comprising quenching was applied. In both cases the ionic conductivity increased when x increased from 0 to 0.3 to 0.5. It is further demonstrated that after application of quenching, the resulting ionic conductivity of the particular electrolyte was higher compared to the electrolyte synthe- sized in a method wherein slow cooling was applied. Figs.11a-c show SEM pictures of particle sizes of Li_5.5PS_4.5Cl_1.5 as prepared accord- ing to the present method (milling for 10-25 min., heating to 400-500 °C for about 5 minutes, and quenching thereafter), and figs.11d-f as prepared according to the prior art (milling during about 10 min, heating to 450-550 °C for about 7 days). The particle sizes ac- cording to the invention are from 200 nm to 2000 nm, and those of the prior art from 5 µm to about 100 µm, hence at least an order of magnitude larger. Fig.12 shows pulse field gradient NMR measurements. This shows promoted Li-ion diffusivity across the unit cell. The diffusion coefficient increased from 1.27x10-12 m2/s (Li₆PS₅Br, slow cooling, lower symbols) to 1.01x10^-12 m2/s (Li_5.5PS_4.5Br_1.5, quenching, top symbols). EXPERIMENTS In this study, an effect of halide substitution (Li_6−xPS_5−xBr_1+x, Li_6−xPS_5−xCl_1+x, Li₆S_xSi_{1- x}S_5-xI_1+x , in the range 0.0 ≤ x ≤ 0.5) on lithium argyrodite was investigated; also the structural disorder was engineered by changing the synthesis protocol. Additionally, this method was also applied to synthesize the halide mixed lithium argyrodite (Li_6−xPS_5−xHal_1+x, Hal = Cl, Br, I, Cl_yBr_1-y, and Cl_0.33Br_0.33I_0.33 with a range of 0.0 ≤ x ≤ 0.5). Similar experiments are per- formed with Na, replacing Li, with As and Sb, each replacing P, and with O, replacing S. Experiments with Se and Te, replacing S, are planned. For the second structural argyrodite, A_6+xZ_1-xM_1-xE_5-xHal_1+x, similar results are obtained for A = Li or Na, the afore mentioned halogenides, for Z = P, and E = S. Experiments with Se and Te, replacing S, are planned. The obtained structural disorder was also found in the second structural argyrodite. First, an argyrodite precursor was prepared via mechanical milling, followed by heat treatment at a particular temperature to obtain the crystalline argyrodite. Two different cooling methods were employed to influence the extent of structural disorder. Rietveld refinement of neutron diffraction patterns showed that this preparation method influences the structural dis- order. It was found that higher ionic conductivity is correlated with a less negative charge on the 4d site, by replacing the S2− with Hal− (Hal=Cl, Br or I). An additional T4 Li+ site was identified in halide-based argyrodite. The result provided an increased ionic conductivity of ~8-12 (e.g.9) mS cm-1. Mechanochemical Milling and Post-annealing: Li_6−xPS_5−xBr_1+x syntheses were performed under an argon atmosphere to prevent contamination of oxygen (O₂ < 2 ppm) and water (H₂O < 1 ppm). Li_6−xPS_5−xHal_1+x, Hal = Cl, Br, I, Cl_yBr_1-y, and Cl_0.33Br_0.33I_0.33 was synthesized using mechanochemical milling (Fritsch Pulverisette 7 premium line). The initial precursors; lithium sulfide (Li₂S, 99.98%) or likewise Li and S of 99.98% purity, lithium bromide (LiBr, 99.99%), and phosphorus pentasulfide (P₄S₁₀, 99%) were purchased from Merck and Sigma Aldrich. All precursors were mixed in an appropriate (or close to) stoichiometric ratio using a mortar and pestle. The obtained 1.0 g, 5 g, 10 g, of the precursor was then mechanochemically milled (20:1, 30:1, 40:1 mass ratio of milling media to precursors) using 3mm, 5mm, and 10-mm- diameter zirconia balls at 450-600 (e.g. 510) rpm for 10-30 min. The obtained powder was manually pressed into a 0.8, 1, 1.5 -cm-diameter pellet and then placed inside quartz ampoules. The quartz ampoules were sealed under a vacuum (<10-3 mbar). The sealed quartz ampoules were placed inside a furnace for crystallization, and the furnace is preheated at a temperature of 450-550 °C for x = 0.0 and 430 °C; for Li_6−xPS_5−xBr_1+x compositions. After a reaction time of 10-15 min, two different cooling methods were applied: (1) quenching in liquid water for fast cooling. (2) slow cooling using the cooling rate of 4 K/h for 4 days. The final powder was obtained, then hand-ground, and stored in an argon atmosphere glove box. The phase purity, lithium substructure, and ionic transport of the argyrodite series were analyzed by X-ray dif- fraction, neutron powder diffraction, and electrochemical impedance spectroscopy. X-ray Diffraction: X-ray diffraction was carried out to determine the phase purities and rel- evant structural parameters with a XˈPert Pro X-ray diffraction (PaNalytical) in Bragg-Bren- tano θ-θ geometry with Cu K^ radiation ( ^₁ = 1.540598 Å and ^₂ =1.544426 Å, at 45 kV and 40 mA ). Measurements were taken in the 2θ range between 10° and 90°. All powders were placed on airtight sample holder with a Kapton lid under an argon atmosphere to prevent air exposure. Neutron Powder Diffraction: Neutron powder diffraction data were collected on a neutron powder diffractometer PEARL at the research reactor of the TU Delft, operating at room tem- perature with the 533 reflection of the germanium monochromator (neutron wavelength of λ = 1.667 Å). Electrochemical Impedance Spectroscopy: Temperature-dependent electrochemical imped- ance spectroscopy was performed using an Autolab EC10M impedance analyzer with 0.01V amplitude with frequency ranging from 10 MHz to 1 Hz to determine the ionic conductivity of the samples. Rietveld Refinement: The TOPAS software was used to perform Rietveld refinements of X- ray diffraction and neutron diffraction data. As a starting point for this study, earlier structural information obtained by neutron power diffraction of Li₆PS₅Br was used. The quality of the fits was determined using the goodness-of-fit (GOF) fit indicator and R_wp. The following pa- rameters were refined: (1) 15 coefficients for a Chebyshev function were used to fit the back- ground and peak shape modeled by the modified Thomson–Cox–Hasting pseudo-Voigt func- tion, (2) scale factor, zero error, (3) lattice parameter, isotropic atomic displacement parame- ter, (4) atomic occupancies of the free S2− (Wyckoff 4d) and Hal− (Wyckoff 4a) anions, since these two anions can be exchanged. The occupancies of total occupancies of Hal- and S2- on the Wyckoff 4a site Wyckoff 4d site were constrained to one (occupancies of Hal− (4a) + S2− (4a) = 1, occupancies of S2− (4d) + Hal− (4d) = 1) assuming full occupancy of these sites by S2− and Hal− . The stability of the refinements was ensured by allowing the refinement of mul- tiple correlated parameters simultaneously. Finally, lithium occupancies on the possible inter- stitial sites as identified by the Fourier difference map (FDM). From a crystallographic point of view Se, Te, and O can replace S in the mentioned Wyckoff locations, I and Cl may replace Br, Na may substitute/replace Li, and As and Sb may replace P. Results Structural changes induced by Br content and synthesis method: Lithium argyrodite Li₆PS₅Hal, where Hal− represents Cl, Br, or I, exhibits structural disorder between the Hal− and S2− positions, where higher disorder lead to faster Li-ion transport. Recently, it was dis- covered that structural disorder can be tuned in single composition Li₆PS₅Br via the synthesis method. Furthermore, replacing the S2− with Br− has been shown to increase ionic conductiv- ity. A mechanochemical synthesis method was used to synthesize a series of Li_6−xPS_5−xBr_1+x materials (x ≤ 0.5), the precursors were mechanically milled to ensure uniform mixing as re- ported previously, and then heated at different temperatures (550°C for x = 0.0, or 430°C for x = 0.3, and 0.5) for 10-15 min, which was sufficient to achieve crystalline lithium argyrodite. In order to control site disorder (in this case Br occupancy on 4d site), two distinct cooling methods were applied: (1) The material was cooled at a rate of 4 °C per h over several days to minimize Br occupancy on 4d site in each composition, (2) The material was quenched in liquid water (fast cooling) to achieve higher Br occupancy on 4d site. The quenching was expected to "freeze in" the higher Br occupancy on 4d site that was achieved at higher (syn- thesis) temperatures. Samples contained minor impurity phases of less than 1.0 wt.%, with negligible impact on ionic transport or structural analysis. While increasing the Br and Cl and mixed Cl, Br and I content up to x = 0.5, the cubic polymorphs are maintained. The analysis focused on the cubic polymorphs within the solubility limit (x ≤ 0.5). The Pawley-fit-refined lattice parameter of slow-cooled Li₆PS₅Br is a = 9.98356 (7) It was found that if the Br content increases (higher x), the lattice parameter decreases for the slow cooling method and increases for the fast cooling method. The lattice parameter as a function of the Br distributed across the Wyckoff 4a site was investigated. For the slow-cooling method, it was found that increasing the Br content does not affect the Br occupancy at the 4a site significantly. Hence the decrease in lattice parameter with increasing Br content maybe due to the increase in Li+ vacancies and/or differences in Li+ distribution. In the quenched sample, a clear trend was shown between the lattice param- eter and Br occupancy in the 4a site. As the Br content increases, Br occupancy in the 4a site also increases, resulting in a larger lattice parameter. The Br occupancy on the 4d site can be tuned in a single composition by adjusting the synthesis method. As the Br content (x) is increased, Br is distributed across the Wyckoff 4a and 4d sites in the crystal structure. The percentage of Br in 4d site obtained by the two dif- ferent cooling methods as a function of total Br content was investigated. The slow-cooled sample was chosen as the lowest occupancies of Br in 4d site, determined by Rietveld refine- ments against neutron diffraction pattern. As the total Br content increases, the Br in 4d site also increases, starting from 12% at x = 0.0 and reaching 63% at x = 0.5 for the slow-cooled method. The quenched method has an even higher Br in 4d site, starting from 39% at x = 0.0 to 72% at x = 0.5, as fast cooling "freezes in" the higher Br in 4d site that is achieved at higher temperatures. The Lithium substructure: As mentioned above, in the lithium argyrodite structure, the anion framework creates six different types of tetrahedral interstices, of which five of these may accommodate lithium. These tetrahedra are classified based on the number of shared cor- ners, edges, or faces with adjacent PS₄3− units, and are referred to as types 1 through 5 (T1−T5). The Li+ is found to occupy type 5 and type 2 (T5, T2, and T5a) positions, such as in Li₆PS₅Hal (Hal = Cl, Br, and I), forming cage-like structures around central anion (Wyckoff 4d). Also Li+ can partially occupy the T4 site (Wyckoff 16e), such as in Li_6.15Al_0.15Si_1.35S_5.4O_0.6 and related Li₂S-SnS₂-SiS₂-P₂S₅ sulfides. The room-temperature high-symmetry ^4^{^}3m struc- ture of Li₆PS₅Br was used as a starting model. The occupancy of various Li sites in the argy- rodite series by quenching and slow cooling method varies as a function of bromide content. Rietveld refinement revealed four Li+ sites that are occupied to different extents, which may vary in different compositions of Li_6−xPS_5−xBr_1+x: T5, T2, T5a, and T4. The overall Li+ content was found to be constrained to obtain a charge balance with the refined Br content. For compositions x = 0.0−0.5 (quenching and slow cooling), the refined thermal displacement pa- rameters of the T2 sites were relatively large compared to other Li+ sites in the structure (B_iso values of ∼9 Å2 for the T2 site) indicating a delocalization of the local motion of Li+ around the T2 site. The refined thermal displacement parameters of the T4 site were negative for slow- cooled x = 0.0 compositions, Additionally, an FDM showed no visible evidence of Li occupa- tion on the T4 site. When the Br content increases in slow-cooled compositions up to x ≥ 0.3, additional T4 lithium sites were found. These sites were refined stably and excluding them from the model resulted in a worse fit. For example, when T4 sites were excluded in x = 0.3, it led to an increase in R_wp from 6.4 to 7.0%. It was found that the T2, T5, and T4 polyhedral volumes are barely affected by change in Br content. BVSE landscapes of Li_6−xPS_5−xBr_1+x revealed that cage-to-cage Li+ diffusion pathways are more connected with higher Br content The T2−T2 and T5−T4−T5 distance as a function of bromide content using both slow-cooling and quenching methods was investi- gated. The slow-cooled Li₆PS₅Br composition only allows for lithium-ion diffusion through T2−T2 pathways, no occupancy of T4 site is observed. As the bromine content increases, the T2−T2 distance remains constant for the slow-cooled method and decreases for the quenching method. The T5−T4−T5 distances decrease with increasing bromide content in both synthesis methods. With increasing bromide content in the slow-cooled method, the T5−T4−T5 distance decreases from 3.76 (10) Å at x = 0.3 (composition) to 3.6 (9) Å at x = 0.5. In the quenched method, the T5−T4−T5 distance decreases from 3.64 (12) Å at x = 0.0 to 3.49 (8) Å at x = 0.5. Summarizing, as bromide content increases the T5−T4−T5 inter-cage distance decreases for both slow and quenched colling and the T2−T2 inter-cage distance reduces only for the quenched cooling, potentially promoting the long-range diffusion, especially for the quenched cooled materials. The average charge on the Wyckoff 4a and 4d sites may vary based on their occupancy, due to the different charges of Br− and S2− . To quantify how Br− impacts the arrangement of calculating the average distance between the 4d site (central anion, S2−) and Li+ located at different sites (T2, T5, and T5a), weighed by the occupancy of each site within a single cage, as previously introduced. Along a series of changing total Br content and Br occupancy on 4d site, significant deviations of R_mean are observed. This result is supported by room temperature 6Li NMR spectra of Li_6−xPS_5−xBr_1+x. The spectrum for Li₆PS₅Br with a lower Br occupancy on 4d site displays an intense resonance at 1.615 ppm assigned to Li+ atom occupying the T2, T5, and T5a sites. Inventors observed that with increasing Br− content, the 6Li resonance shifts towards a higher field and smaller ppm values. This shift to lower ppm values indicates that Li-atoms are experiencing a more electron-rich environment. As the amount of Br− on the 4d site increases, either through increase of the Br content, the average negative charge on the 4d site decreases as the divalent sulfide is replaced by monovalent Br. To examine the effect of varying total Br content and Br 4d occupancy on the ionic conductivity of Li_6−xPS_5−xBr_1+x, temperature-dependent impedance spectroscopy was performed to measure ionic conductivity and activation energy. The impedance data at lower temperatures (-40 to 25°C) were fitted with a resistor and constant phase element (CPE) in parallel. The CPE in parallel exhibited a capacitance of around 1 to 8 X 10-10 F cm-2 and an α value of 0.89−0.97, indicating bulk transport, respectively. The ionic conductivities at room temperature vary as a function of Br content. The ionic conductivity increases with Br content for both cooling methods. As shown, higher site disorder (in this case Br occupancy on 4d site) leads to an improvement in ionic conductivity. The conductivity of slow-cooled Li₆PS₅Br sample (12% Br occupancy on 4d site ) was 0.78 mS cm-1. The conductivity of the slow-cooled samples increased from 0.78 mS cm- 1 to 6.2 mS cm-1 with increasing Br content, while the conductivity of quenched samples in- creased from 3.21 mS cm-1 to 8.55 mS cm-1 with increasing Br content. Structure−Property Relationship: Increasing the Br occupancies in 4d site by changing the synthesis method can significantly improve the ionic conductivity in lithium argyrodites. In- ventors were able to tune the Br occupancies in 4d site and lithium substructure in each com- position. Certain observations are: ^ As the total Br content increases, the Br occupancies in 4d site also increases, starting from 12% to 63% for the slow-cooled method. The Br occupancies in 4d site is higher at higher temperatures and quenching can kinetically "freeze in" the higher Br occupancies in 4d site. The quenched method is found to have an even higher Br occupancies in 4d site, ranging from 39% to 72%. Overall, this work highlights the importance of synthesis methods as a tool control Br occupancies in 4d site in the lithium argyrodites. ^ In the lithium substructure, a non-zero T4 occupation was found. ^ As the Br occupancies in 4d site increases in both cooling methods (see in above section), the average negative charge on the 4d site decreases as the divalent sulfide is replaced by monovalent bromide ion. This results in a higher overall conductivity. ^ For the slow-cooled samples, inventors found an increase in the ionic conductivity from 0.78 to 6.20 mS cm-1. For quenched samples, an increase in ionic conductivity from 3.21 to 8.55 mS cm-1 was found. Higher halide concentrations Synthesis of small grain size glass ceramic Li₅PS₄Cl_2, Li₅PS₄Br_2, and Li₅PS₄I₂ were prepared according to the present method and shows ionic conductivities of 1.0 mS/cm, 2.75 mS/cm, and 8.23 mS/cm, respectively. List of possible anodes and cathodes where this could be applied: Anodes: ^ Alloy anodes (such as Aluminium (Al), Tin (Sn), Magnesium (Mg), Silver (Ag), Anti- mony (Sb), and their alloys). ^ Conversion-type anode materials include transition-metal sulphides, oxides, phosphides, nitrides, fluorides, and selenides. ^ Silicon-based compounds ^ Carbon based compounds ^ Li/Na metal anode Cathode: ^ LiFePO₄ ^ LiFe_xMn_1-xPO₄ ^ LiMn₂O₄ spinel ^ LiNi_0.5Mn_1.5O₄ spinel ^ LiNi_xCo_yMn_1−x−yO₂ layered oxides ^ Li-rich layered oxides For experimental results reference is also made to an article submitted for publication, titled “Exploring the Relationship Between Halide Substitution, Structural disorder, and Lith- ium Distribution in Lithium Argyrodites Li_6-xPS_5-xBr_1+x”, which article and its content is in- corporated by reference.

Claims

CLAIMS 1. An electrolyte for a solid-state battery comprising at least one solid single crystalline electrolyte wherein the solid single crystalline elec- trolyte is selected from at least one of A_6-xZE_5-xHal_1+x and A_6+xZ_1-xM_1-xE_5-xHal_1+x, wherein A is selected from Li, Na, and first combinations thereof, wherein Z is selected from P, As, Sb, and second combinations thereof, wherein M is selected from Si, As, Ge, Sn, and Sb, and third combinations thereof, wherein E is selected from O, S, Se, Te, and fourth combinations thereof, wherein Hal is selected from Cl, Br, I, and fifth combinations thereof, and wherein x is from <-1;1.0], in particular from <-1;0.75], in particular wherein x is not from -0.99 - -1.

2. The solid electrolyte according to claim 1, wherein the solid electrolyte is in the form of single crystalline particles, wherein the particles have a size distribution with an average size of 200-5000 nm, in particular 300-1000 nm, and wherein a standard deviation of the size dis- tribution is 2-20% relative to the average size, in particular 5-12% relative to the average size, as measured with a Shimadzu SALD-7500nano.

3. The solid electrolyte according to any of claims 1-2, wherein the solid electrolyte is a mixed crystal.

4. The solid electrolyte according to claim 3, wherein at least one of first combinations, sec- ond combinations, third combinations, fourth combinations, and fifth combination is present, in particular wherein two or three of said combinations are present.

5. The solid electrolyte according to any of claims 1-4, wherein a unit cell of the solid elec- trolyte comprises a plurality of crystallographic Hal-sites, respectively, wherein a first of said crystallographic Hal-site is partly occupied by E and Hal, in particular a Wyckoff 4a Hal-site and a Wyckoff 4d Hal-site, in particular having a crystal site Hal distribution, in par- ticular Hal distribution wherein a first site is occupied for up to 95%, in particular up to 88%, more in particular up to 60%, even more in particular up to 37%, wherein a second site is oc- cupied for more than 5%, in particular for 12-80%, more in particular for 40-75%.

6. The solid electrolyte according to any of claims 1-5, wherein the solid single crystalline electrolyte has at least one site disorder of 1-75%, in particular at least one site disorder of 15-70%, more in particular at least one site disorder of 25-65%, such as 30-55%, in particu- lar two or three site disorders.

7. The solid electrolyte according to any of claims 1-6, wherein the solid single crystalline electrolyte has an ion conductivity of > 1 mScm-1, in particular of > 8 mScm-1, such as of 10- 50 mScm-1.

8. The solid electrolyte according to any of claims 1-7, wherein the solid single crystalline electrolyte has a crystallinity of >95%, in particular > 98%, such as > 99%, and/or wherein the unit cell of the solid single crystalline electrolyte has a plurality of A-crystal sites, in particular a Wyckoff T2-site, a Wyckoff T4-site, a Wyckoff T5a site, and a Wyckoff T5 site, wherein at least two of the plurality of A-crystal sites are partly or fully occupied by A, in particular three or four A-crystal sites, and having a crystal site A distribution, in par- ticular an A distribution wherein a first site is occupied for more than 55%, wherein a second site is occupied for 1-25%, in particular for 10-20%, wherein a third site is occupied for less than 26%, in particular 0-10%, and wherein a fourth site is occupied for a remainder of the A-occupation, as determined with neutron diffraction data, in particular from Rietveld re- finement thereof, and/or wherein solid single crystalline electrolyte has a capacitances of 0.1 to 20 x 10-10 F cm-2, in particular of 1 to 10 x 10-10 F cm-2, and/or wherein solid single crystalline electrolyte has a bulk transport representing α value of 0.89−0.97.

9. A solid state battery comprising at least one first electrode, at least one second electrode, in between the first and second electrode and in contact with the first and second electrode at least one solid state single crystalline electrolyte according to any of claims 1-8.

10. The solid state battery according to claim 9, wherein the material of the cathode is se- lected from Fe comprising cathodes, from Mn comprising cathodes, from Li or Na compris- ing cathodes, from Co comprising cathodes, from transition metal alloys, from Ni compris- ing cathodes, in particular from nickel comprising alloys, more in particular from nickel al- loys with >75% Ni, such as > 80 atom% Ni, and/or wherein the anode comprises a material selected from alloys, in particular from Al-alloys, from Sn-alloys, from Mg-alloys, from Ag-alloys, from Sb alloys, from In alloys, and from silicon alloys (a-Si_yA_x:Q_z), wherein element A is selected from B, C, N, Ge, O, and combi- nations thereof, wherein element Q is selected from H, F, and combinations thereof, and from silicon, wherein the silicon alloy or silicon is porous for accommodating electrolyte ions, such as Li ions, wherein the silicon alloy or silicon has a porosity from 1-50%, wherein the silicon alloy or silicon is amorphous, and wherein the silicon or silicon alloy is prefera- bly hydrogenated, from conversion-type anode materials, in particular from metal sulphides, metal oxides, metal phosphides, metal nitrides, metal fluorides, and metal selenides, more in particular wherein the metal thereof is a transition metal, from carbon based compounds, such as graphite, and graphene, and from a Li- or Na- metal anode.

11. The solid state battery according to any of claims 9-10, wherein the at least one first elec- trode and/or the at least one second electrode comprise a nano-crystalline material.

12. The solid state battery according to any of claims 9-11, wherein the battery further com- prises at least one separator, wherein the at least one separator is provided in between the at least one solid state crystalline electrolyte and the first or second electrode, respectively.

13. The solid state battery according to any of claims 9-12, wherein the at least one first elec- trode has a thickness of 50-500 µm, in particular 100-300 µm, such as 150-250 µm, and/or wherein the at least one second electrode has a thickness of 20-300 µm, in particular 40-200 µm, such as 50-100 µm, and/or wherein the at least one solid state crystalline electrolyte has a thickness of 100-1000 µm, in particular 200-800 µm, such as 300-500 µm.

14. Method of producing a solid crystalline electrolyte, wherein the to be produced solid electrolyte comprises at least one of A_6-xZE_5-xHal_1+x and A_6+xZ_1-xM_1-xE_5-xHal_1+x, wherein A is selected from Li, Na, and first combinations thereof, wherein Z is selected from P, As, Sb, and second combinations thereof, wherein M is selected from Si, Ge, As, Sn, and Sb, and third combinations thereof, wherein E is selected from O, S, Se, Te, and fourth combinations thereof, wherein Hal is selected from Cl, Br, I, and fifth combinations thereof, and wherein x is from <-1;1.0], in particular from <-1;0.75], in particular wherein x is not from -0.99 to -1, providing precursors in substantially molar amounts and forming a mixture thereof, wherein precursors are selected from A, M, Z, E, combinations of ZE, and from AHal, in particular wherein E is provided in an excess amount of 1.01-1.2 times the molar amount, milling the mixture during a milling time therewith obtaining a milled mixture, heating the milled mixture at an elevated temperature during a heating time therewith form- ing electrolyte, and cooling the heated mixture therewith obtaining solid crystalline electrolyte.

15. The method according to claim 14, wherein the milling time is from 10-60 minutes, in particular 20-30 minutes, and/or wherein milling is performed at a rpm of 500-600 rpm, in particular 505-520 rpm, and/or optionally forming pellets under a pressure, in particular a pressure from 49-500 MPa, in particular 100-200 MPa, during a pressure time of 10-60 seconds, such as 20-40 seconds, wherein the milled mixture is heated to a heating temperature of 400-550 °C, and/or during a heating time of 5-120 minutes, and/or wherein cooling is from the heating temperature to a temperature of 15-30 °C, during a cool- ing time of 1-30 seconds,

16. The method according to any of claims 14-15, wherein the heating temperature is from 300-750 °C, in particular 400-550 °C, and/or the heating time is from 1- 10 minutes, in par- ticular wherein a pre-heated oven at the heating temperature is used,.

17. The method according to any of claims 14-16, wherein the precursors are selected ac- cording to A is selected from Li, Na, and first combinations thereof, Z is selected from P, As, Sb, and second combinations thereof, M is selected from Si, Ge, Sn, and Sb, and third combinations thereof, E is selected from S, Se, Te, and fourth combinations thereof, Hal is selected from Cl, Br, I, and fifth combinations thereof, in particular wherein precursors are selected from Li, P, S, Si, Cl, Br, and I, and combina- tions of A, Z, M, E, and Hal, in particular AHal, and ZE, Such as LiHal, and P₄S₁₀, and with the proviso that Li₂S is not selected.

18. A product obtained by the method of any of claims 14-17, wherein the product is crystal- line, in particular single crystalline.

19. A system for power supply comprising at least one solid-state battery according to any of claims 9-13 and/or at least one product according to claim 18.