Synthesis and Characterization of Three New Lithium‐Scandium Hexathiohypodiphosphates: Li4–3xScxP2S6 (x = 0.358), m‐LiScP2S6, and t‐LiScP2S6

Schoop, Leslie M.; Eger, Roland; Pielnhofer, Florian; Schneider, Christian; Nuß, Jürgen; Lotsch, Bettina V.

doi:10.1002/zaac.201800363

Cited by 7 publications

(9 citation statements)

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“…The pervasive interest in main group, transition, and rare earth metal sulfide chemistry is driven by their structural diversity and unique properties. − Replacing hard Lewis base oxide ligands with soft sulfides leads to a change in the bonding between the metal center and the ligand resulting in changes in the optical, magnetic, and structural properties of the materials. − Recently, particular interest has been directed toward thiophosphate materials that exhibit conducting and catalytic properties. , For example, a family of layered thiophosphate materials with a general formula MPS x , such as MnPS 3 , NiPS 3 , and ZnPS 3 , can be readily exfoliated and exhibits antiferromagnetic transitions at temperatures below 120 K. − Layered thiophosphites have shown potential for application in hydrogen evolution reactions and other energy applications. , Lithium and sodium thiophosphates, in particular, possess outstanding diffusion properties making them a potential class of materials for ion conduction applications and, as a result, have generated significant interest to comprehensively investigate these materials. ,− …”

Section: Introductionmentioning

confidence: 99%

“…8,9 For example, a family of layered thiophosphate materials with a general formula MPS x , such as MnPS 3 , NiPS 3 , and ZnPS 3 , can be readily exfoliated and exhibits antiferromagnetic transitions at temperatures below 120 K. 10−13 Layered thiophosphites have shown potential for application in hydrogen evolution reactions and other energy applications. 14,15 Lithium and sodium thiophosphates, in particular, possess outstanding diffusion properties making them a potential class of materials for ion conduction applications and, as a result, have generated significant interest to comprehensively investigate these materials. 8,16−22 Oxyphosphate ligands have been studied extensively and are known to exhibit various oxidation states, rich structural diversity, and different structural units ranging from isolated P(V)O 4 3− groups to infinite (P(V)O 3 − ) ∞ chains.…”

Section: ■ Introductionmentioning

confidence: 99%

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Size-Driven Stability of Lanthanide Thiophosphates Grown from an Iodide Flux

et al. 2019

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To determine the influence of the lanthanide size on the structures and properties of thiophosphates, a thiophosphate series containing different lanthanides was synthesized via high temperature flux crystal growth and their structures and physical properties analyzed and compared. Layered thiohypophosphates NaLnP 2 S 6 (Ln = La, Ce, Pr) and thiopyrophosphates CsLnP 2 S 7 (Ln = Pr, Nd, Sm, Gd, Tb, Dy, Ho, Er, Yb, Y) were grown out of an iodide flux using consistent reaction conditions across both series. Under the mildly reducing iodide flux reaction conditions, a rather rare example of phosphorus reduction from the +5 to the +4 oxidation state was observed. Both resultant structure types are based on lanthanide thiophosphate sheets with the alkali cations located between them. Magnetic susceptibility measurements were conducted and revealed Curie−Weiss behavior of the samples, with a Van Vleck contribution in the CsSmP 2 S 7 sample. UV−vis data was found to be in good agreement with the literature, indicating little influence of the sulfide environment on the localized 4f orbitals.

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Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Size-Driven Stability of Lanthanide Thiophosphates Grown from an Iodide Flux

et al. 2019

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“…Compounds Li 4–3 x V x P 2 S 6 ( x = 0.5) ( 1 ), Li 4–2 x Co x P 2 S 6 ( x = 0.75) ( 4 ), and Li 4–2 x Ni x P 2 S 6 ( x = 0.8) ( 5 ) crystallize in the P 3̅1 m space group isostructural to Li 4–3 x Sc x P 2 S 6 or Li 4–2 x M x P 2 S 6 (M = Mg, Fe, and Co). ,, The asymmetric unit of the crystal structures of 1 , 4, and 5 consists of one transition metal (V, Co, or Ni) mixed-occupied with Li (Li1), one disordered phosphorus split between P1 (major component) and P1A (minor component) for 1 (no disorder in P for 4 and 5 ), one sulfur, and one lithium site (Figure a,b). In both cases, 2D layers are formed in the ab -plane by edge sharing between MS 6 octahedra themselves or between MS 6 octahedra and P 2 S 6 polyhedra and stacked along the c -axis with Li ions filling the interlayer van der Waals gap (Figure c).…”

Section: Resultsmentioning

confidence: 99%

“…Takada et al first reported the synthesis of Li 4–2 x M x P 2 S 6 (M = Mg and Fe) under anhydrous conditions in a sealed quartz tube and determined its crystal structure in the trigonal system ( P 3̅1 m ). , Accordingly, Li 2 MgP 2 S 6 displayed couple of orders higher Li-ion conductivity compared to pure Li 4 P 2 S 6 , whose room-temperature conductivity is found to be 1.6 × 10 –7 S/cm, while on the other hand, Li 2 FeP 2 S 6 is a 3 V cathode . Lotsch's group showed that partial substitution of M 3+ in Li 4 P 2 S 6 can also stabilize the trigonal Li 4–2 x Mg x P 2 S 6 structure type as in the case of Li 4–3 x Sc x P 2 S 6 ( x = 0.358) . More recently, Rodriguez's group further expanded the family of Li 2 MP 2 S 6 structure type with new compositions of Fe and Co and reported their magnetic properties .…”

Section: Introductionmentioning

confidence: 99%

Li₂MP₂S₆: Building-Block Approach to a Family of 2D Non-van der Waals-Layered Materials and Their Water, Ammonia, and Ion Intercalation Properties

Sundaramoorthy,

Gerasimchuk,

Ghosh

et al. 2024

Chem. Mater.

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A series of non-van der Waals 2D quaternary thiophosphates with nominal composition, Li 2 MP 2 S 6 (M = V, Mn, Fe, Co, Ni, and Zn), has been successfully synthesized through solid-state metathesis reactions by a building block approach as well as starting with a stoichiometric combination of elements. Li 4−nx M x n+ P 2 S 6 (M = V, Fe, Ni, Co, and Zn; x = 0.5−1, n = 2 or 3) crystallize in the P3̅ 1m space group, while Li 2 MnP 2 S 6 crystallizes in R3̅ . All the compounds form a 2D layered structure through edge sharing MS 6 octahedra and P 2 S 6 units with Li atoms occupying the interlayer spaces. X-ray diffraction and thermogravimetric analyses reveal spontaneous water intercalation tendencies of these materials, leading to two distinct hydrated phases (HY-I and HY-II) when they are exposed to air for shorter and extended times, respectively. Thermodiffractograms demonstrate the reversibility of phase transformation upon deintercalation of water molecules from the interlayer regions. The crystal structure of hydrated phase I from single-crystal and synchrotron powder X-ray diffraction indicates formation of a monolayer of water with interlayer expansion. Additionally, Li 4−nx M x n+ P 2 S 6 (M = V, Mn, Fe, and Ni) also display huge affinity toward NH 3 intercalation in the interlayer space when subjected to a liquid or gaseous ammonia environment. The magnetic measurements on Li 2 MP 2 S 6 (M = Mn and Ni) show the paramagnetic nature of the compounds down to 2 K. AC impedance spectroscopy on Li 2.56 Zn 0.72 P 2 S 6 shows a room-temperature ionic conductivity of 2.69 × 10 −3 mS/cm, which is four order higher in magnitude than Li 4 P 2 S 6 , while hydrated Li 2.56 Zn 0.72 P 2 S 6 display 7-fold higher ionic conductivity (1.85 × 10 −2 mS/cm) than its anhydrous counterpart. The study also reports electrochemical Li (de)intercalation in Li 2 FeP 2 S 6 in a Li-ion battery with a liquid electrolyte for the first time.

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“…These materials which crystallize in extremely divers crystal structure types attracted much attention for their potentially useful properties, such as magnetism, ferroelectricity, photoluminescence, nonlinear optics, thermoelectricity, electrocatalysis, ionic conductivity, or reversible redox chemistry . Among the thiohypodiphosphate materials, the quaternary compounds A + M 3+ ( P 2 S 6 ) ( A = Li, Na, K, Rb, Cs, Tl, Cu, Ag and M = Al, Sc, V, Cr, Y, In, Sb, La, Ce, Pr, Sm, Tb, Er, Yb, Lu, Bi···) − were the most intensively studied with 38 representatives in the ICSD database followed by the ternary compounds containing divalent cations M 2 2+ ( P 2 S 6 ) ( M = Mg, Ca, Ba, V, Mn, Fe, Co, Ni, Zn, Pd, Cd, Hg, Sn, Pb, Eu···) − with 19 representatives. Ternary thiohypodiphosphate were also reported for monovalent- A 4 + ( P 2 S 6 ) ( A = Li, Na, K, Rb, Cs, Tl, Cu, and Ag), − trivalent- M 4/3 3+ ( P 2 S 6 ) ( M = Al, In, Ga···), , and tetravalent-cations M 4+ ( P 2 S 6 ) ( M = Ti, Zr, Hf, Sn, Th, U···). − Many quaternary compounds of the general formula A 2 + M 2+ ( P 2 S 6 ) ( A = Li, K, Rb, Cs, Ag and M = Mg, Mn, Fe, Ni, Zn, Pd···) − were reported in the literature as well.…”

Section: Introductionmentioning

confidence: 99%

Crystal Structure and Ionic Conductivity of Na₂MnP₂S₆

Ben Yahia,

Motohashi,

Mori

et al. 2024

J. Phys. Chem. C

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Green needlelike single crystals of Na 2 MnP 2 S 6 were grown by crystallization after melting a mixture of Na 2 S, Mn, and P 2 S 5 . The crystal structure of the new compound was determined from single-crystal X-ray diffraction data. The chemical composition was confirmed by energy-dispersive X-ray spectroscopy, and the ionic conductivity was measured using electrochemical impedance spectroscopy. Na 2 MnP 2 S 6 crystallizes in the orthorhombic system, space group Pbcn (no. 60) with a = 7.3850(6) Å, b = 21.6682(13) Å, c = 6.2495(4) Å, V = 1000.04(12) Å 3 , and Z = 4. The Na and Mn atoms are octahedrally coordinated to the S atoms. They form [Na 2 MnS 6 ] 8− honeycomb-like structure within which P−P dimer units are located. Two of the three sodium atomic positions are partially occupied. The group-subgroup transformations emphasized a strong relationship with the P3̅ m1-Li 4 P 2 S 6 structure. Indeed, 4Li atoms were replaced by 2Na, Mn, and □ (□: vacancy), and half of the P−P dimer units have the same distribution within the tunnels. The new cationic ordering is at the origin of the trigonal to orthorhombic symmetry transformation (P3̅ m1 to Pbcn). The ionic conductivity of Na 2 MnP 2 S 6 is 6.2 × 10 −7 S cm −1 (Ea = 0.41 eV) at 31 °C.

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Synthesis and Characterization of Three New Lithium‐Scandium Hexathiohypodiphosphates: Li_4–3xSc_xP₂S₆ (x = 0.358), m‐LiScP₂S₆, and t‐LiScP₂S₆

Cited by 7 publications

References 72 publications

Size-Driven Stability of Lanthanide Thiophosphates Grown from an Iodide Flux

Size-Driven Stability of Lanthanide Thiophosphates Grown from an Iodide Flux

Li₂MP₂S₆: Building-Block Approach to a Family of 2D Non-van der Waals-Layered Materials and Their Water, Ammonia, and Ion Intercalation Properties

Crystal Structure and Ionic Conductivity of Na₂MnP₂S₆

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Synthesis and Characterization of Three New Lithium‐Scandium Hexathiohypodiphosphates: Li4–3xScxP2S6 (x = 0.358), m‐LiScP2S6, and t‐LiScP2S6

Cited by 7 publications

References 72 publications

Size-Driven Stability of Lanthanide Thiophosphates Grown from an Iodide Flux

Size-Driven Stability of Lanthanide Thiophosphates Grown from an Iodide Flux

Li2MP2S6: Building-Block Approach to a Family of 2D Non-van der Waals-Layered Materials and Their Water, Ammonia, and Ion Intercalation Properties

Crystal Structure and Ionic Conductivity of Na2MnP2S6

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Synthesis and Characterization of Three New Lithium‐Scandium Hexathiohypodiphosphates: Li_4–3xSc_xP₂S₆ (x = 0.358), m‐LiScP₂S₆, and t‐LiScP₂S₆

Li₂MP₂S₆: Building-Block Approach to a Family of 2D Non-van der Waals-Layered Materials and Their Water, Ammonia, and Ion Intercalation Properties

Crystal Structure and Ionic Conductivity of Na₂MnP₂S₆