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Tungsten Disulfide (WS2) – Characteristics, Applications and Synthesis

Tungsten disulfide (WS2) is classified as a Transition Metal Dichalcogenides (TMDs).  TMDs are considered to be layered materials with a chemical formula of MX2 where M is a transition metal and X is a chalcogen like Sulphur, Selenium and more.

The TMDs have a general formula of X-M-X structure with a layer of M atoms sandwiched between two layers of X atoms. The bonds within the layers are strong covalent bonds and the layers are held together by weak Van der Waals forces. The adjacent layers can easily slide past each other when a shear force is applied. This gives WS2 lubricating properties.

Lubrication is required to reduce friction and wear and improve the longevity of moving parts in  a machinery. WS2 is used as a dry lubricant and allows safe and reliable operation of machinery. Tungsten disulfide (WS2) nanopowder can be used to avoid direct contact between the two surfaces in relative motion and also prevent corrosion.

WS2 occurs naturally as a rare mineral Tungstenite. WS2 can be used for solid lubrication in high temperature, high pressure, high load and high vacuum conditions. It has a very low coefficient of friction of 0.03 in static applications and 0.07 in dynamic applications.

WS2  is one of the most lubricious materials known. It is known for its properties like high load rating, long wear life, no drag and non-sticking. It can take loads up to 300,000 PSI which is higher than any other lubricant.

Characteristics of WS2

Applications

Synthesis of WS2

WS2 nanopowders can be synthesised using the Chemical Vapour Deposition method. The decomposition of Tungsten Hexacarbonyl precursor is conducted in a temperature range of 420° C – 1000° C in a reactor. 

The evaporation temperatures used are between 80° C – 110° C with flowing He gas at a rate of 2000 cc/min – 4000 cc/min. This process takes place in a bubbler and after evaporation of the precursor it is mixed with the flow of the incoming gas which is also heated to the same temperature. 

This mixture of carrier gas and the precursor vapour passes through a tube and enters a tubular reactor.. Two temperature zones are maintained here, hot and cold.The chamber to collect  the nanoparticles is placed in the upper zone. 

Pure crystalline WS2 nanoparticles form with excess of Sulphur. The powder is evaporated at a temperature of 200° C to remove the excess Sulphur. It is then condensed in the cold zone of the reactor to get WS2.

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