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Tungsten disulfide

April 11, 2024

"Tungsten sulfide" redirects here. Not to be confused with Tungsten trisulfide.

Tungsten disulfide is an inorganic chemical compound composed of tungsten and sulfur with the chemical formula WS2. This compound is part of the group of materials called the transition metal dichalcogenides. It occurs naturally as the rare mineral tungstenite. This material is a component of certain catalysts used for hydrodesulfurization and hydrodenitrification.

Tungsten disulfide

Left: WS2 film on sapphire. Right: dark exfoliated WS2 film floating on water
Names
IUPAC names
Tungsten sulfur
Bis(sulfanylidene)tungsten
Systematic IUPAC name
Dithioxotungsten
Other names
Tungsten(IV) sulfide
Tungstenite
Identifiers
  • 12138-09-9 Y
3D model (JSmol)
  • Interactive image
ChEBI
  • CHEBI:30521 Y
ChemSpider
  • 74837 Y
ECHA InfoCard 100.032.027
EC Number
  • 235-243-3
  • 82938
  • DTXSID2065256
  • InChI=1S/2S.W Y
    Key: ITRNXVSDJBHYNJ-UHFFFAOYSA-N Y
  • InChI=1S/2S.W
    Key: ITRNXVSDJBHYNJ-UHFFFAOYSA-N
  • S=[W]=S
Properties
WS2
Molar mass 247.98 g/mol
Appearance Blue-gray powder[1]
Density 7.5 g/cm3, solid[1]
Melting point 1,250 °C (2,280 °F; 1,520 K) decomposes[1]
Slightly soluble
Band gap ~1.35 eV (optical, indirect, bulk)[2][3]
~2.05 eV (optical, direct, monolayer)[4]
+5850·10−6 cm3/mol[5]
Structure
Molybdenite
Trigonal prismatic (WIV)
Pyramidal (S2−)
Related compounds
Other anions
 Tungsten(IV) oxide
Tungsten diselenide
Tungsten ditelluride
Other cations
 Molybdenum disulfide
Tantalum disulfide
Rhenium disulfide
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
N verify (what is YN ?)

WS2 adopts a layered structure similar, or isotypic with MoS2, instead with W atoms situated in trigonal prismatic coordination sphere (in place of Mo atoms). Owing to this layered structure, WS2 forms non-carbon nanotubes, which were discovered after heating a thin sample of WS2 in 1992.[6]

Structure and physical properties edit

 
Atomic image (top) and model (bottom) of Nb-doped WS2. Blue, red, and yellow spheres indicate W, Nb, and S atoms, respectively. Nb doping allows to reduce the WS2 bandgap.[7]

Bulk WS2 forms dark gray hexagonal crystals with a layered structure. Like the closely related MoS2, it exhibits properties of a dry lubricant.

Although it has long been thought that WS2 is relatively stable in ambient air, recent reports on the ambient air oxidation of monolayer WS2 have found this to not be the case. In the monolayer form, WS2 is converted rather rapidly (over the course of days in ambient light and atmosphere) to tungsten oxide via a photo-oxidation reaction involving visible wavelengths of light readily absorbed by monolayer WS2 (< ~660 nm; > ~1.88 eV).[8] In addition to light of suitable wavelength, the reaction likely requires both oxygen and water to proceed, with the water thought to act as a catalyst for oxidation. The products of the reaction likely include various tungsten oxide species and sulfuric acid. The oxidation of other semiconductor transition metal dichalcogenides (S-TMDs) such as MoS2, has similarly been observed to occur in ambient light and atmospheric conditions.[9]

WS2 is also attacked by a mixture of nitric and hydrofluoric acid. When heated in oxygen-containing atmosphere, WS2 converts to tungsten trioxide. When heated in absence of oxygen, WS2 does not melt but decomposes to tungsten and sulfur, but only at 1250 °C.[1]

Historically monolayer WS2 was isolated using chemical exfoliation via intercalation with lithium from n-butyl lithium (in hexane), followed by exfoliation of the Li intercalated compound by sonication in water.[10] WS2 also undergoes exfoliation by treatment with various reagents such as chlorosulfonic acid[11] and the lithium halides.[12]

Synthesis edit

WS2 is produced by a number of methods.[1][13] Many of these methods involve treating oxides with sources of sulfide or hydrosulfide, supplied as hydrogen sulfide or generated in situ.

Thin films and monolayers edit

Widely used techniques for the growth of monolayer WS2 include chemical vapor deposition (CVD), physical vapor deposition (PVD) or metal organic chemical vapor deposition (MOCVD), though most current methods produce sulfur vacancy defects in excess of 1×1013 cm−2.[14] Other routes entail thermolysis of tungsten(VI) sulfides (e.g., (R4N)2WS4) or the equivalent (e.g., WS3).[13]

Freestanding WS2 films can be produced as follows. WS2 is deposited on a hydrophilic substrate, such as sapphire, and then coated with a polymer, such as polystyrene. After dipping the sample in water for a few minutes, the hydrophobic WS2 film spontaneously peels off.[15]

Applications edit

WS2 is used, in conjunction with other materials, as catalyst for hydrotreating of crude oil.[13] In recent years it has also found applications as a saturable for passively mode locked fibre lasers resulting in femtosecond pulses being produced.

Lamellar tungsten disulphide is used as a dry lubricant for fasteners, bearings, and molds,[16] as well as having significant use in aerospace and military industries.[17][failed verification] WS2 can be applied to a metal surface without binders or curing, via high-velocity air impingement. The most recent official standard for this process is laid out in the SAE International specification AMS2530A.[18]

Research edit

Like MoS2, nanostructured WS2 is actively studied for potential applications, such as storage of hydrogen and lithium.[11] WS2 also catalyses hydrogenation of carbon dioxide:[11][19][20]

CO2 + H2 → CO + H2O

Nanotubes edit

Tungsten disulfide is the first material which was found to form non-carbon nanotubes, in 1992.[6] This ability is related to the layered structure of WS2, and macroscopic amounts of WS2 have been produced by the methods mentioned above.[13] WS2 nanotubes have been investigated as reinforcing agents to improve the mechanical properties of polymeric nanocomposites. In a study, WS2 nanotubes reinforced biodegradable polymeric nanocomposites of polypropylene fumarate (PPF) showed significant increases in the Young's modulus, compression yield strength, flexural modulus and flexural yield strength, compared to single- and multi-walled carbon nanotubes reinforced PPF nanocomposites, suggesting that WS2 nanotubes may be better reinforcing agents than carbon nanotubes.[21] The addition of WS2 nanotubes to epoxy resin improved adhesion, fracture toughness and strain energy release rate. The wear of the nanotubes-reinforced epoxy is lower than that of pure epoxy.[22] WS2 nanotubes were embedded into a poly(methyl methacrylate) (PMMA) nanofiber matrix via electrospinning. The nanotubes were well dispersed and aligned along fiber axis. The enhanced stiffness and toughness of PMMA fiber meshes by means of non-carbon nanotubes addition may have potential uses as impact-absorbing materials, e.g. for ballistic vests.[23][24]

WS2 nanotubes are hollow and can be filled with another material, to preserve or guide it to a desired location, or to generate new properties in the filler material which is confined within a nanometer-scale diameter. To this goal, non-carbon nanotube hybrids were made by filling WS2 nanotubes with molten lead, antimony or bismuth iodide salt by a capillary wetting process, resulting in PbI2@WS2, SbI3@WS2 or BiI3@WS2 core–shell nanotubes.[25]

Nanosheets edit

See also: Transition metal dichalcogenide monolayers

WS2 can also exist in the form of atomically thin sheets.[26] Such materials exhibit room-temperature photoluminescence in the monolayer limit.[27]

Transistors edit

Taiwan Semiconductor Manufacturing Company (TSMC) is investigating use of WS
2 as a channel material in field effect transistors. The approximately 6-layer thick material is created using chemical vapor deposition (CVD).[28]

References edit

 
Wikimedia Commons has media related to Tungsten disulfide.
  1. ^ a b c d e Eagleson, Mary (1994). Concise encyclopedia chemistry. Walter de Gruyter. p. 1129. ISBN 978-3-11-011451-5.
  2. ^ Kam KK, Parkinson BA (February 1982). "Detailed photocurrent spectroscopy of the semiconducting group VIB transition metal dichalcogenides". Journal of Physical Chemistry. 86 (4): 463–467. doi:10.1021/j100393a010.
  3. ^ Baglio JA, Calabrese GS, Kamieniecki E, Kershaw R, Kubiak CP, Ricco AJ, et al. (July 1982). "Characterization of n-Type Semiconducting Tungsten Disulfide Photoanodes in Aqueous and Nonaqueous Electrolyte Solutions Photo-oxidation of Halides with High Efficiency". J. Electrochem. Soc. 129 (7): 1461–1472. Bibcode:1982JElS..129.1461B. doi:10.1149/1.2124184.
  4. ^ Gutiérrez H, Perea-López N, Elías AL, Berkdemir A, Wang B, Lv R, et al. (November 2012). "Extraordinary Room-Temperature Photoluminescence in Triangular WS2 Monolayers". Nano Letters. 13 (8): 3447–3454. arXiv:1208.1325. Bibcode:2013NanoL..13.3447G. doi:10.1021/nl3026357. PMID 23194096. S2CID 207597527.
  5. ^ Haynes WM, ed. (2011). CRC Handbook of Chemistry and Physics (92nd ed.). Boca Raton, FL: CRC Press. p. 4.136. ISBN 1-4398-5511-0.
  6. ^ a b Tenne R, Margulis L, Genut M, Hodes G (1992). "Polyhedral and cylindrical structures of tungsten disulphide". Nature. 360 (6403): 444–446. Bibcode:1992Natur.360..444T. doi:10.1038/360444a0. S2CID 4309310.
  7. ^ Sasaki S, Kobayashi Y, Liu Z, Suenaga K, Maniwa Y, Miyauchi Y, et al. (2016). "Growth and optical properties of Nb-doped WS2 monolayers". Applied Physics Express. 9 (7): 071201. Bibcode:2016APExp...9g1201S. doi:10.7567/APEX.9.071201. 
  8. ^ Kotsakidis JC, Zhang Q, Vazquez de Parga AL, Currie M, Helmerson K, Gaskill DK, et al. (July 2019). "Oxidation of Monolayer WS2 in Ambient Is a Photoinduced Process". Nano Letters. 19 (8): 5205–5215. arXiv:1906.00375. Bibcode:2019NanoL..19.5205K. doi:10.1021/acs.nanolett.9b01599. PMID 31287707. S2CID 173990948.
  9. ^ Gao J, Li B, Tan J, Chow P, Lu TM, Koratker N (January 2016). "Aging of Transition Metal Dichalcogenide Monolayers". ACS Nano. 10 (2): 2628–2635. doi:10.1021/acsnano.5b07677. PMID 26808328. S2CID 18010466.
  10. ^ Joensen P, Frindt RF, Morrison SR (1986). "Single-layer MoS2". Materials Research Bulletin. 21 (4): 457–461. doi:10.1016/0025-5408(86)90011-5.
  11. ^ a b c Bhandavat R, David L, Singh G (2012). "Synthesis of Surface-Functionalized WS2 Nanosheets and Performance as Li-Ion Battery Anodes". The Journal of Physical Chemistry Letters. 3 (11): 1523–30. doi:10.1021/jz300480w. PMID 26285632.
  12. ^ Ghorai A, Midya A, Maiti R, Ray SK (2016). "Exfoliation of WS2 in the semiconducting phase using a group of lithium halides: a new method of Li intercalation". Dalton Transactions. 45 (38): 14979–14987. doi:10.1039/C6DT02823C. PMID 27560159.
  13. ^ a b c d Panigrahi, Pravas Kumar, Pathak, Amita (2008). "Microwave-assisted synthesis of WS2 nanowires through tetrathiotungstate precursors" (free download). Sci. Technol. Adv. Mater. 9 (4): 045008. Bibcode:2008STAdM...9d5008P. doi:10.1088/1468-6996/9/4/045008. PMC 5099650. PMID 27878036.
  14. ^ Hong J, Hu Z, Probert M, Li K, Lv D, Yang X, et al. (February 2015). "Eploring atomic defects in molybdenum disulphide monolayers". Nature Communications. 6: 6293. Bibcode:2015NatCo...6.6293H. doi:10.1038/ncomms7293. PMC 4346634. PMID 25695374.
  15. ^ Yu Y, Fong PW, Wang S, Surya C (2016). "Fabrication of WS2/GaN p-n Junction by Wafer-Scale WS2 Thin Film Transfer". Scientific Reports. 6: 37833. Bibcode:2016NatSR...637833Y. doi:10.1038/srep37833. PMC 5126671. PMID 27897210.
  16. ^ French LG, ed. (1967). "Dicronite". Machinery. Vol. 73. Machinery Publications Corporation. p. 101.
  17. ^ "Quality Approved Special Processes By Special Process Code". BAE Systems. 2020-07-07.
  18. ^ "AMS2530A: Tungsten Disulfide Coating, Thin Lubricating Film, Binder-Less Impingement Applied". SAE International. Retrieved 2020-07-10.
  19. ^ Lassner, Erik, Schubert, Wolf-Dieter (1999). Tungsten: properties, chemistry, technology of the element, alloys, and chemical compounds. Springer. pp. 374–. ISBN 978-0-306-45053-2.
  20. ^ Engineer making rechargeable batteries with layered nanomaterials. Science Daily (2013-01-016)
  21. ^ Lalwani G (September 2013). "Tungsten disulfide nanotubes reinforced biodegradable polymers for bone tissue engineering". Acta Biomaterialia. 9 (9): 8365–8373. doi:10.1016/j.actbio.2013.05.018. PMC 3732565. PMID 23727293.
  22. ^ Zohar, E., et al. (2011). "The Mechanical and Tribological Properties of Epoxy Nanocomposites with WS2 Nanotubes". Sensors & Transducers Journal. 12 (Special Issue): 53–65.
  23. ^ Reddy, C. S., Zak, A., Zussman, E. (2011). "WS2 nanotubes embedded in PMMA nanofibers as energy absorptive material". J. Mater. Chem. 21 (40): 16086–16093. doi:10.1039/C1JM12700D.
  24. ^ Nano-Armor: Protecting the Soldiers of Tomorrow. Physorg.com (2005-12-10). Retrieved on 2016-01-20
  25. ^ Kreizman R, Enyashin AN, Deepak FL, Albu-Yaron A, Popovitz-Biro R, Seifert G, et al. (2010). "Synthesis of Core-Shell Inorganic Nanotubes". Adv. Funct. Mater. 20 (15): 2459–2468. doi:10.1002/adfm.201000490. S2CID 136725896.
  26. ^ Coleman JN, Lotya M, O'Neill A, Bergin SD, King PJ, Khan U, et al. (2011). "Two-Dimensional Nanosheets Produced by Liquid Exfoliation of Layered Materials". Science. 331 (6017): 568–71. Bibcode:2011Sci...331..568C. doi:10.1126/science.1194975. hdl:2262/66458. PMID 21292974. S2CID 23576676.
  27. ^ Gutiérrez HR, Perea-López N, Elías AL, Berkdemir A, Wang B, Lv R, et al. (2013). "Extraordinary Room-Temperature Photoluminescence in Triangular WS2 Monolayers". Nano Letters. 13 (8): 3447–54. arXiv:1208.1325. Bibcode:2013NanoL..13.3447G. doi:10.1021/nl3026357. PMID 23194096. S2CID 207597527.
  28. ^ Cheng CC, Chung YY, Li UY, Lin CT, Li CF, Chen JH, et al. (2019). "First demonstration of 40-nm channel length top-gate WS2 pFET using channel area-selective CVD growth directly on SiOx/Si substrate". 2019 Symposium on VLSI Technology. IEEE. pp. T244–T245. doi:10.23919/VLSIT.2019.8776498. ISBN 978-4-86348-719-2. S2CID 198931613.

April 11, 2024
tungsten, disulfide, tungsten, sulfide, redirects, here, confused, with, tungsten, trisulfide, inorganic, chemical, compound, composed, tungsten, sulfur, with, chemical, formula, this, compound, part, group, materials, called, transition, metal, dichalcogenide. Tungsten sulfide redirects here Not to be confused with Tungsten trisulfide Tungsten disulfide is an inorganic chemical compound composed of tungsten and sulfur with the chemical formula WS2 This compound is part of the group of materials called the transition metal dichalcogenides It occurs naturally as the rare mineral tungstenite This material is a component of certain catalysts used for hydrodesulfurization and hydrodenitrification Tungsten disulfide Left WS2 film on sapphire Right dark exfoliated WS2 film floating on waterNamesIUPAC names Tungsten sulfurBis sulfanylidene tungstenSystematic IUPAC name DithioxotungstenOther names Tungsten IV sulfideTungsteniteIdentifiersCAS Number 12138 09 9 Y3D model JSmol Interactive imageChEBI CHEBI 30521 YChemSpider 74837 YECHA InfoCard 100 032 027EC Number 235 243 3PubChem CID 82938CompTox Dashboard EPA DTXSID2065256InChI InChI 1S 2S W YKey ITRNXVSDJBHYNJ UHFFFAOYSA N YInChI 1S 2S WKey ITRNXVSDJBHYNJ UHFFFAOYSA NSMILES S W SPropertiesChemical formula WS2Molar mass 247 98 g molAppearance Blue gray powder 1 Density 7 5 g cm3 solid 1 Melting point 1 250 C 2 280 F 1 520 K decomposes 1 Solubility in water Slightly solubleBand gap 1 35 eV optical indirect bulk 2 3 2 05 eV optical direct monolayer 4 Magnetic susceptibility x 5850 10 6 cm3 mol 5 StructureCrystal structure MolybdeniteCoordination geometry Trigonal prismatic WIV Pyramidal S2 Related compoundsOther anions Tungsten IV oxideTungsten diselenideTungsten ditellurideOther cations Molybdenum disulfideTantalum disulfideRhenium disulfideExcept where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa N verify what is Y N Infobox references WS2 adopts a layered structure similar or isotypic with MoS2 instead with W atoms situated in trigonal prismatic coordination sphere in place of Mo atoms Owing to this layered structure WS2 forms non carbon nanotubes which were discovered after heating a thin sample of WS2 in 1992 6 Contents 1 Structure and physical properties 2 Synthesis 2 1 Thin films and monolayers 3 Applications 4 Research 4 1 Nanotubes 4 2 Nanosheets 4 3 Transistors 5 ReferencesStructure and physical properties edit nbsp Atomic image top and model bottom of Nb doped WS2 Blue red and yellow spheres indicate W Nb and S atoms respectively Nb doping allows to reduce the WS2 bandgap 7 Bulk WS2 forms dark gray hexagonal crystals with a layered structure Like the closely related MoS2 it exhibits properties of a dry lubricant Although it has long been thought that WS2 is relatively stable in ambient air recent reports on the ambient air oxidation of monolayer WS2 have found this to not be the case In the monolayer form WS2 is converted rather rapidly over the course of days in ambient light and atmosphere to tungsten oxide via a photo oxidation reaction involving visible wavelengths of light readily absorbed by monolayer WS2 lt 660 nm gt 1 88 eV 8 In addition to light of suitable wavelength the reaction likely requires both oxygen and water to proceed with the water thought to act as a catalyst for oxidation The products of the reaction likely include various tungsten oxide species and sulfuric acid The oxidation of other semiconductor transition metal dichalcogenides S TMDs such as MoS2 has similarly been observed to occur in ambient light and atmospheric conditions 9 WS2 is also attacked by a mixture of nitric and hydrofluoric acid When heated in oxygen containing atmosphere WS2 converts to tungsten trioxide When heated in absence of oxygen WS2 does not melt but decomposes to tungsten and sulfur but only at 1250 C 1 Historically monolayer WS2 was isolated using chemical exfoliation via intercalation with lithium from n butyl lithium in hexane followed by exfoliation of the Li intercalated compound by sonication in water 10 WS2 also undergoes exfoliation by treatment with various reagents such as chlorosulfonic acid 11 and the lithium halides 12 Synthesis editWS2 is produced by a number of methods 1 13 Many of these methods involve treating oxides with sources of sulfide or hydrosulfide supplied as hydrogen sulfide or generated in situ Thin films and monolayers edit Widely used techniques for the growth of monolayer WS2 include chemical vapor deposition CVD physical vapor deposition PVD or metal organic chemical vapor deposition MOCVD though most current methods produce sulfur vacancy defects in excess of 1 1013 cm 2 14 Other routes entail thermolysis of tungsten VI sulfides e g R4N 2WS4 or the equivalent e g WS3 13 Freestanding WS2 films can be produced as follows WS2 is deposited on a hydrophilic substrate such as sapphire and then coated with a polymer such as polystyrene After dipping the sample in water for a few minutes the hydrophobic WS2 film spontaneously peels off 15 Applications editWS2 is used in conjunction with other materials as catalyst for hydrotreating of crude oil 13 In recent years it has also found applications as a saturable for passively mode locked fibre lasers resulting in femtosecond pulses being produced Lamellar tungsten disulphide is used as a dry lubricant for fasteners bearings and molds 16 as well as having significant use in aerospace and military industries 17 failed verification WS2 can be applied to a metal surface without binders or curing via high velocity air impingement The most recent official standard for this process is laid out in the SAE International specification AMS2530A 18 Research editLike MoS2 nanostructured WS2 is actively studied for potential applications such as storage of hydrogen and lithium 11 WS2 also catalyses hydrogenation of carbon dioxide 11 19 20 CO2 H2 CO H2ONanotubes edit Tungsten disulfide is the first material which was found to form non carbon nanotubes in 1992 6 This ability is related to the layered structure of WS2 and macroscopic amounts of WS2 have been produced by the methods mentioned above 13 WS2 nanotubes have been investigated as reinforcing agents to improve the mechanical properties of polymeric nanocomposites In a study WS2 nanotubes reinforced biodegradable polymeric nanocomposites of polypropylene fumarate PPF showed significant increases in the Young s modulus compression yield strength flexural modulus and flexural yield strength compared to single and multi walled carbon nanotubes reinforced PPF nanocomposites suggesting that WS2 nanotubes may be better reinforcing agents than carbon nanotubes 21 The addition of WS2 nanotubes to epoxy resin improved adhesion fracture toughness and strain energy release rate The wear of the nanotubes reinforced epoxy is lower than that of pure epoxy 22 WS2 nanotubes were embedded into a poly methyl methacrylate PMMA nanofiber matrix via electrospinning The nanotubes were well dispersed and aligned along fiber axis The enhanced stiffness and toughness of PMMA fiber meshes by means of non carbon nanotubes addition may have potential uses as impact absorbing materials e g for ballistic vests 23 24 WS2 nanotubes are hollow and can be filled with another material to preserve or guide it to a desired location or to generate new properties in the filler material which is confined within a nanometer scale diameter To this goal non carbon nanotube hybrids were made by filling WS2 nanotubes with molten lead antimony or bismuth iodide salt by a capillary wetting process resulting in PbI2 WS2 SbI3 WS2 or BiI3 WS2 core shell nanotubes 25 Nanosheets edit See also Transition metal dichalcogenide monolayers WS2 can also exist in the form of atomically thin sheets 26 Such materials exhibit room temperature photoluminescence in the monolayer limit 27 Transistors edit Taiwan Semiconductor Manufacturing Company TSMC is investigating use of WS2 as a channel material in field effect transistors The approximately 6 layer thick material is created using chemical vapor deposition CVD 28 References edit nbsp Wikimedia Commons has media related to Tungsten disulfide a b c d e Eagleson Mary 1994 Concise encyclopedia chemistry Walter de Gruyter p 1129 ISBN 978 3 11 011451 5 Kam KK Parkinson BA February 1982 Detailed photocurrent spectroscopy of the semiconducting group VIB transition metal dichalcogenides Journal of Physical Chemistry 86 4 463 467 doi 10 1021 j100393a010 Baglio JA Calabrese GS Kamieniecki E Kershaw R Kubiak CP Ricco AJ et al July 1982 Characterization of n Type Semiconducting Tungsten Disulfide Photoanodes in Aqueous and Nonaqueous Electrolyte Solutions Photo oxidation of Halides with High Efficiency J Electrochem Soc 129 7 1461 1472 Bibcode 1982JElS 129 1461B doi 10 1149 1 2124184 Gutierrez H Perea Lopez N Elias AL Berkdemir A Wang B Lv R et al November 2012 Extraordinary Room Temperature Photoluminescence in Triangular WS2 Monolayers Nano Letters 13 8 3447 3454 arXiv 1208 1325 Bibcode 2013NanoL 13 3447G doi 10 1021 nl3026357 PMID 23194096 S2CID 207597527 Haynes WM ed 2011 CRC Handbook of Chemistry and Physics 92nd ed Boca Raton FL CRC Press p 4 136 ISBN 1 4398 5511 0 a b Tenne R Margulis L Genut M Hodes G 1992 Polyhedral and cylindrical structures of tungsten disulphide Nature 360 6403 444 446 Bibcode 1992Natur 360 444T doi 10 1038 360444a0 S2CID 4309310 Sasaki S Kobayashi Y Liu Z Suenaga K Maniwa Y Miyauchi Y et al 2016 Growth and optical properties of Nb doped WS2 monolayers Applied Physics Express 9 7 071201 Bibcode 2016APExp 9g1201S doi 10 7567 APEX 9 071201 nbsp Kotsakidis JC Zhang Q Vazquez de Parga AL Currie M Helmerson K Gaskill DK et al July 2019 Oxidation of Monolayer WS2 in Ambient Is a Photoinduced Process Nano Letters 19 8 5205 5215 arXiv 1906 00375 Bibcode 2019NanoL 19 5205K doi 10 1021 acs nanolett 9b01599 PMID 31287707 S2CID 173990948 Gao J Li B Tan J Chow P Lu TM Koratker N January 2016 Aging of Transition Metal Dichalcogenide Monolayers ACS Nano 10 2 2628 2635 doi 10 1021 acsnano 5b07677 PMID 26808328 S2CID 18010466 Joensen P Frindt RF Morrison SR 1986 Single layer MoS2 Materials Research Bulletin 21 4 457 461 doi 10 1016 0025 5408 86 90011 5 a b c Bhandavat R David L Singh G 2012 Synthesis of Surface Functionalized WS2 Nanosheets and Performance as Li Ion Battery Anodes The Journal of Physical Chemistry Letters 3 11 1523 30 doi 10 1021 jz300480w PMID 26285632 Ghorai A Midya A Maiti R Ray SK 2016 Exfoliation of WS2 in the semiconducting phase using a group of lithium halides a new method of Li intercalation Dalton Transactions 45 38 14979 14987 doi 10 1039 C6DT02823C PMID 27560159 a b c d Panigrahi Pravas Kumar Pathak Amita 2008 Microwave assisted synthesis of WS2 nanowires through tetrathiotungstate precursors free download Sci Technol Adv Mater 9 4 045008 Bibcode 2008STAdM 9d5008P doi 10 1088 1468 6996 9 4 045008 PMC 5099650 PMID 27878036 Hong J Hu Z Probert M Li K Lv D Yang X et al February 2015 Eploring atomic defects in molybdenum disulphide monolayers Nature Communications 6 6293 Bibcode 2015NatCo 6 6293H doi 10 1038 ncomms7293 PMC 4346634 PMID 25695374 Yu Y Fong PW Wang S Surya C 2016 Fabrication of WS2 GaN p n Junction by Wafer Scale WS2 Thin Film Transfer Scientific Reports 6 37833 Bibcode 2016NatSR 637833Y doi 10 1038 srep37833 PMC 5126671 PMID 27897210 French LG ed 1967 Dicronite Machinery Vol 73 Machinery Publications Corporation p 101 Quality Approved Special Processes By Special Process Code BAE Systems 2020 07 07 AMS2530A Tungsten Disulfide Coating Thin Lubricating Film Binder Less Impingement Applied SAE International Retrieved 2020 07 10 Lassner Erik Schubert Wolf Dieter 1999 Tungsten properties chemistry technology of the element alloys and chemical compounds Springer pp 374 ISBN 978 0 306 45053 2 Engineer making rechargeable batteries with layered nanomaterials Science Daily 2013 01 016 Lalwani G September 2013 Tungsten disulfide nanotubes reinforced biodegradable polymers for bone tissue engineering Acta Biomaterialia 9 9 8365 8373 doi 10 1016 j actbio 2013 05 018 PMC 3732565 PMID 23727293 Zohar E et al 2011 The Mechanical and Tribological Properties of Epoxy Nanocomposites with WS2 Nanotubes Sensors amp Transducers Journal 12 Special Issue 53 65 Reddy C S Zak A Zussman E 2011 WS2 nanotubes embedded in PMMA nanofibers as energy absorptive material J Mater Chem 21 40 16086 16093 doi 10 1039 C1JM12700D Nano Armor Protecting the Soldiers of Tomorrow Physorg com 2005 12 10 Retrieved on 2016 01 20 Kreizman R Enyashin AN Deepak FL Albu Yaron A Popovitz Biro R Seifert G et al 2010 Synthesis of Core Shell Inorganic Nanotubes Adv Funct Mater 20 15 2459 2468 doi 10 1002 adfm 201000490 S2CID 136725896 Coleman JN Lotya M O Neill A Bergin SD King PJ Khan U et al 2011 Two Dimensional Nanosheets Produced by Liquid Exfoliation of Layered Materials Science 331 6017 568 71 Bibcode 2011Sci 331 568C doi 10 1126 science 1194975 hdl 2262 66458 PMID 21292974 S2CID 23576676 Gutierrez HR Perea Lopez N Elias AL Berkdemir A Wang B Lv R et al 2013 Extraordinary Room Temperature Photoluminescence in Triangular WS2 Monolayers Nano Letters 13 8 3447 54 arXiv 1208 1325 Bibcode 2013NanoL 13 3447G doi 10 1021 nl3026357 PMID 23194096 S2CID 207597527 Cheng CC Chung YY Li UY Lin CT Li CF Chen JH et al 2019 First demonstration of 40 nm channel length top gate WS2 pFET using channel area selective CVD growth directly on SiOx Si substrate 2019 Symposium on VLSI Technology IEEE pp T244 T245 doi 10 23919 VLSIT 2019 8776498 ISBN 978 4 86348 719 2 S2CID 198931613 Retrieved from https en wikipedia org w index php title Tungsten disulfide amp oldid 1211210621, wikipedia, wiki, book, books, library,

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