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Direct process

December 20, 2023

The direct process, also called the direct synthesis, Rochow process, and Müller-Rochow process is the most common technology for preparing organosilicon compounds on an industrial scale. It was first reported independently by Eugene G. Rochow and Richard Müller in the 1940s.[1]

The process involves copper-catalyzed reactions of alkyl halides with elemental silicon, which take place in a fluidized bed reactor. Although theoretically possible with any alkyl halide, the best results in terms of selectivity and yield occur with chloromethane (CH3Cl). Typical conditions are 300 °C and 2–5 bar. These conditions allow for 90–98% conversion for silicon and 30–90% for chloromethane. Approximately 1.4 Mton of dimethyldichlorosilane (Me2SiCl2) is produced annually using this process.[2]

Few companies actually carry out the Rochow process, because of the complex technology and has high capital requirements. Since the silicon is crushed prior to reaction in a fluidized bed, the companies practicing this technology are referred to as silicon crushers.[3]

Reaction and mechanism edit

The relevant reactions are (Me = CH3):

x MeCl + Si → Me3SiCl, Me2SiCl2, MeSiCl3, Me4Si2Cl2, …

Dimethyldichlorosilane (Me2SiCl2) is of particular value (precursor to silicones), but trimethylsilyl chloride (Me3SiCl) and methyltrichlorosilane (MeSiCl3) are also valuable.[4]: 371 

The mechanism of the direct process is still not well understood, despite much research. Copper plays an important role. The copper and silicon form intermetallics with the approximate composition Cu3Si. This intermediate facilitates the formation of the Si-Cl and Si-Me bonds. It is proposed that close proximity of the Si-Cl to a copper-chloromethane "adduct" allows for formation of the Me-SiCl units. Transfer of a second chloromethane allows for the release of the Me2SiCl2. Thus, copper is oxidized from the zero oxidation state and then reduced to regenerate the catalyst.[1]

The chain reaction can be terminated in many ways. These termination processes give rise to the other products that are seen in the reaction. For example, combining two Si-Cl groups gives the SiCl2 group, which undergoes Cu-catalyzed reaction with MeCl to give MeSiCl3.[1]

In addition to copper, the catalyst optimally contains promoter metals that facilitate the reaction. Among the many promoter metals, zinc, tin, antimony, magnesium, calcium, bismuth, arsenic, and cadmium have been mentioned.[1][2]

Product distribution and isolation edit

The major product for the direct process should be dichlorodimethylsilane, Me2SiCl2. However, many other products are formed. Unlike most reactions, this distribution is actually desirable because the product isolation is very efficient.[1] Each methylchlorosilane has specific and often substantial applications. Me2SiCl2 is the most useful. It is the precursor for the majority of silicon products produced on an industrial scale. The other products are used in the preparation of siloxane polymers as well as specialized applications.[1]

Dichlorodimethylsilane is the major product of the reaction, as is expected, being obtained in about 70–90% yield. The next most abundant product is methyltrichlorosilane (MeSiCl3), at 5–15% of the total. Other products include Me3SiCl (2–4%), MeHSiCl2 (1–4%), and Me2HSiCl (0.1–0.5%).[1]

The Me2SiCl2 is purified by fractional distillation. Although the boiling points of the various chloromethylsilanes are similar (Me2SiCl2: 70 °C, MeSiCl3: 66 °C, Me3SiCl: 57 °C, MeHSiCl2: 41 °C, Me2HSiCl: 35 °C), the distillation utilizes columns with high separating capacities, connected in series. The purity of the products crucially affects the production of siloxane polymers, otherwise chain branching arises.[1]

References edit

  1. ^ a b c d e f g h Rösch, L.; John, P.; Reitmeier, R. (2003). "Organic Silicon Compounds". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a24_021..
  2. ^ a b Elschenbroich, Christoph Organometallics VCH, Weinheim, Germany: 1992. ISBN 978-3-527-29390-2.
  3. ^ (PDF). Archived from the original (PDF) on 2011-05-16. Retrieved 2010-01-26.
  4. ^ Shriver & Atkins' inorganic chemistry. P. W. Atkins (5 ed.). Oxford: Oxford University Press. 2010. ISBN 978-0-19-923617-6. OCLC 430678988.{{cite book}}: CS1 maint: others (link)

December 20, 2023
direct, process, direct, process, also, called, direct, synthesis, rochow, process, müller, rochow, process, most, common, technology, preparing, organosilicon, compounds, industrial, scale, first, reported, independently, eugene, rochow, richard, müller, 1940. The direct process also called the direct synthesis Rochow process and Muller Rochow process is the most common technology for preparing organosilicon compounds on an industrial scale It was first reported independently by Eugene G Rochow and Richard Muller in the 1940s 1 The process involves copper catalyzed reactions of alkyl halides with elemental silicon which take place in a fluidized bed reactor Although theoretically possible with any alkyl halide the best results in terms of selectivity and yield occur with chloromethane CH3Cl Typical conditions are 300 C and 2 5 bar These conditions allow for 90 98 conversion for silicon and 30 90 for chloromethane Approximately 1 4 Mton of dimethyldichlorosilane Me2SiCl2 is produced annually using this process 2 Few companies actually carry out the Rochow process because of the complex technology and has high capital requirements Since the silicon is crushed prior to reaction in a fluidized bed the companies practicing this technology are referred to as silicon crushers 3 Reaction and mechanism editThe relevant reactions are Me CH3 x MeCl Si Me3SiCl Me2SiCl2 MeSiCl3 Me4Si2Cl2 Dimethyldichlorosilane Me2SiCl2 is of particular value precursor to silicones but trimethylsilyl chloride Me3SiCl and methyltrichlorosilane MeSiCl3 are also valuable 4 371 The mechanism of the direct process is still not well understood despite much research Copper plays an important role The copper and silicon form intermetallics with the approximate composition Cu3Si This intermediate facilitates the formation of the Si Cl and Si Me bonds It is proposed that close proximity of the Si Cl to a copper chloromethane adduct allows for formation of the Me SiCl units Transfer of a second chloromethane allows for the release of the Me2SiCl2 Thus copper is oxidized from the zero oxidation state and then reduced to regenerate the catalyst 1 The chain reaction can be terminated in many ways These termination processes give rise to the other products that are seen in the reaction For example combining two Si Cl groups gives the SiCl2 group which undergoes Cu catalyzed reaction with MeCl to give MeSiCl3 1 In addition to copper the catalyst optimally contains promoter metals that facilitate the reaction Among the many promoter metals zinc tin antimony magnesium calcium bismuth arsenic and cadmium have been mentioned 1 2 Product distribution and isolation editThe major product for the direct process should be dichlorodimethylsilane Me2SiCl2 However many other products are formed Unlike most reactions this distribution is actually desirable because the product isolation is very efficient 1 Each methylchlorosilane has specific and often substantial applications Me2SiCl2 is the most useful It is the precursor for the majority of silicon products produced on an industrial scale The other products are used in the preparation of siloxane polymers as well as specialized applications 1 Dichlorodimethylsilane is the major product of the reaction as is expected being obtained in about 70 90 yield The next most abundant product is methyltrichlorosilane MeSiCl3 at 5 15 of the total Other products include Me3SiCl 2 4 MeHSiCl2 1 4 and Me2HSiCl 0 1 0 5 1 The Me2SiCl2 is purified by fractional distillation Although the boiling points of the various chloromethylsilanes are similar Me2SiCl2 70 C MeSiCl3 66 C Me3SiCl 57 C MeHSiCl2 41 C Me2HSiCl 35 C the distillation utilizes columns with high separating capacities connected in series The purity of the products crucially affects the production of siloxane polymers otherwise chain branching arises 1 References edit a b c d e f g h Rosch L John P Reitmeier R 2003 Organic Silicon Compounds Ullmann s Encyclopedia of Industrial Chemistry Weinheim Wiley VCH doi 10 1002 14356007 a24 021 a b Elschenbroich Christoph Organometallics VCH Weinheim Germany 1992 ISBN 978 3 527 29390 2 Basic Silicone Chemistry A Review PDF Archived from the original PDF on 2011 05 16 Retrieved 2010 01 26 Shriver amp Atkins inorganic chemistry P W Atkins 5 ed Oxford Oxford University Press 2010 ISBN 978 0 19 923617 6 OCLC 430678988 a href Template Cite book html title Template Cite book cite book a CS1 maint others link Retrieved from https en wikipedia org w index php title Direct process amp oldid 1129676670, wikipedia, wiki, book, books, library,

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