Silanes

Silanes are silicon-based compounds with one or more organic groups attached to a silicon atom. They serve as crucial building blocks in organic and inorganic synthesis, especially in surface modification, adhesion promotion, and the production of coatings and sealants. Silanes are widely used in the semiconductor industry, glass treatment, and as crosslinking agents in polymer chemistry. At CymitQuimica, we offer a diverse range of silanes designed for your research and industrial applications.

ALLYLTRIMETHOXYSILANE

CAS:

• 2551-83-9

Olefin Functional Trialkoxy Silane
Silane coupling agents have the ability to form a durable bond between organic and inorganic materials to generate desired heterogeneous environments or to incorporate the bulk properties of different phases into a uniform composite structure. The general formula has two classes of functionality. The hydrolyzable group forms stable condensation products with siliceous surfaces and other oxides such as those of aluminum, zirconium, tin, titanium, and nickel. The organofunctional group alters the wetting or adhesion characteristics of the substrate, utilizes the substrate to catalyze chemical transformations at the heterogeneous interface, orders the interfacial region, or modifies its partition characteristics, and significantly effects the covalent bond between organic and inorganic materials.
Alkenylsilane Cross-Coupling Agent
The cross-coupling reaction is a highly useful methodology for the formation of carbon-carbon bonds. It involves two reagents, with one typically being a suitable organometallic reagent - the nucleophile - and the other a suitable organic substrate, normally an unsaturated halide, tosylate or similar - the electrophile.
Allyltrimethoxysilane; 1-Trimethoxysilylprop-2-ene
Adhesion promoter for vinyl-addition siliconesAllylation of ketones, aldehydes and imines with dual activation of a Lewis Acid and fluoride ionUsed in the regioselective generation of the thermodynamically more stable enol trimethoxysilyl ethers, which in turn are used in the asymmetric generation of quaternary carbon centersConverts arylselenyl bromides to arylallylselenidesAllylates aryl iodidesUsed in microparticle surface modificationComonomer for polyolefin polymerizationExtensive review of silicon based cross-coupling agents: Denmark, S. E. et al. "Organic Reactions, Volume 75" Denmark, S. E. ed., John Wiley and Sons, 233, 2011

Formula: C₆H₁₄O₃Si

Purity: 97%

Color and Shape: Straw Liquid

Molecular weight: 162.26

1,1,3,3,5,5-HEXAMETHYLTRISILOXANE

CAS:

• 1189-93-1

Siloxane-Based Silane Reducing Agent
Organosilanes are hydrocarbon-like and possess the ability to serve as both ionic and free-radical reducing agents. These reagents and their reaction by-products are safer and more easily handled and disposed than many other reducing agents. The metallic nature of silicon and its low electronegativity relative to hydrogen lead to polarization of the Si-H bond yielding a hydridic hydrogen and a milder reducing agent compared to aluminum-, boron-, and other metal-based hydrides. A summary of some key silane reductions are presented in Table 1 of the Silicon-Based Reducing Agents brochure.
1,1,3,3,5,5-hexamethyltrisiloxane; Methyl 1,5-dihydro-1,1,3,3-hexamethyltrsiloxane; M’DM’
High molecular weight silane reducing agentUndergoes hydrosilylation reactionsExtensive review of silicon based reducing agents: Larson, G.; Fry, J. L. "Ionic and Organometallic-Catalyzed Organosilane Reductions", Wipf, P., Ed.; Wiley, 2007

Formula: C₆H₂₀O₂Si₃

Purity: 97%

Color and Shape: Liquid

Molecular weight: 208.48

BIS[3-(TRIETHOXYSILYL)PROPYL]DISULFIDE, 90%

CAS:

• 56706-10-6

Bis[3-(triethoxysilyl)propyl]disulfide; bis(triethoxysilyl)-4,5-dithiooctane
Sulfur functional dipodal silaneContains sulfide and tetrasulfideDipodal coupling agent/vulcanizing agent for rubbersIntermediate for mesoporous silicas with acidic pores

Formula: C₁₈H₄₂O₆S₂Si₂

Purity: 90%

Color and Shape: Pale Yellow Amber Liquid

Molecular weight: 474.82

1,2-BIS(TRIETHOXYSILYL)ETHANE

CAS:

• 16068-37-4

Alkyl Silane - Dipodal Surface Bonding
Aliphatic, fluorinated aliphatic or substituted aromatic hydrocarbon substituents are the hydrophobic entities which enable silanes to induce surface hydrophobicity. The organic substitution of the silane must be non-polar. The hydrophobic effect of the organic substitution can be related to the free energy of transfer of hydrocarbon molecules from an aqueous phase to a homogeneous hydrocarbon phase. A successful hydrophobic coating must eliminate or mitigate hydrogen bonding and shield polar surfaces from interaction with water by creating a non-polar interphase. Although silane and silicone derived coatings are in general the most hydrophobic, they maintain a high degree of permeability to water vapor. This allows coatings to breathe and reduce deterioration at the coating interface associated with entrapped water. Since ions are not transported through non-polar silane and silicone coatings, they offer protection to composite structures ranging from pigmented coatings to rebar reinforced concrete. A selection guide for hydrophobic silanes can be found on pages 22-31 of the Hydrophobicity, Hydrophilicity and Silane Surface Modification brochure.
Non Functional Alkoxy Silane
Silane coupling agents have the ability to form a durable bond between organic and inorganic materials to generate desired heterogeneous environments or to incorporate the bulk properties of different phases into a uniform composite structure. The general formula has two classes of functionality. The hydrolyzable group forms stable condensation products with siliceous surfaces and other oxides such as those of aluminum, zirconium, tin, titanium, and nickel. The organofunctional group alters the wetting or adhesion characteristics of the substrate, utilizes the substrate to catalyze chemical transformations at the heterogeneous interface, orders the interfacial region, or modifies its partition characteristics, and significantly effects the covalent bond between organic and inorganic materials.
Dipodal Silane
Dipodal silanes are a series of adhesion promoters that have intrinsic hydrolytic stabilities up to ~10,000 times greater than conventional silanes and are used in applications such as plastic optics, multilayer printed circuit boards and as adhesive primers for ferrous and nonferrous metals. They have the ability to form up to six bonds to a substrate compared to conventional silanes with the ability to form only three bonds to a substrate. Many conventional coupling agents are frequently used in combination with 10-40% of a non-functional dipodal silane, where the conventional coupling agent provides the appropriate functionality for the application, and the non-functional dipodal silane provides increased durability. Also known as bis-silanes additives enhance hydrolytic stability, which impacts on increased product shelf life, ensures better substrate bonding and also leads to improved mechanical properties in coatings as well as composite applications.
1,2-Bis(triethoxysilyl)ethane (Hexaethoxydisilethylene, BSE)
ΔHvap: 101.5 kJ/molVapor pressure, 150°: 10mmAdditive to silane coupling agent formulations that enhance hydrolytic stabilityEmployed in corrosion resistant coating and primers for steel and aluminumComponent in evaporation-induced self-assembly of mesoporous structuresForms mesoporous molecular sieves that can be further functionalizedSolg-gels of α,ω-bis(trimethoxysilyl)alkanes reportedHydrolysis kinetics studied7Advanced silane in SIVATE™ E610Used as an adhesion promoter in Bird-deterrent Glass Coatings

Formula: C₁₄H₃₄O₆Si₂

Purity: 97%

Color and Shape: Liquid

Molecular weight: 354.59

TRIMETHYLCHLOROSILANE

CAS:

• 75-77-4

Trimethylsilyl Blocking Agent
Used as a protecting group for reactive hydrogens in alcohols, amines, thiols, and carboxylic acids. Organosilanes are hydrogen-like, can be introduced in high yield, and can be removed under selective conditions. They are stable over a wide range of reaction conditions and can be removed in the presence of other functional groups, including other protecting groups. The tolerance of silylated alcohols to chemical transformations summary is presented in Table 1 of the Silicon-Based Blocking Agents brochure.
Alkyl Silane - Conventional Surface Bonding
Aliphatic, fluorinated aliphatic or substituted aromatic hydrocarbon substituents are the hydrophobic entities which enable silanes to induce surface hydrophobicity. The organic substitution of the silane must be non-polar. The hydrophobic effect of the organic substitution can be related to the free energy of transfer of hydrocarbon molecules from an aqueous phase to a homogeneous hydrocarbon phase. A successful hydrophobic coating must eliminate or mitigate hydrogen bonding and shield polar surfaces from interaction with water by creating a non-polar interphase. Although silane and silicone derived coatings are in general the most hydrophobic, they maintain a high degree of permeability to water vapor. This allows coatings to breathe and reduce deterioration at the coating interface associated with entrapped water. Since ions are not transported through non-polar silane and silicone coatings, they offer protection to composite structures ranging from pigmented coatings to rebar reinforced concrete. A selection guide for hydrophobic silanes can be found on pages 22-31 of the Hydrophobicity, Hydrophilicity and Silane Surface Modification brochure.
Trimethylchorosilane; Chlorotrimethylsilane; Trimethylsilyl chloride; TMCS
Viscosity: 0.47 cStΔHcomb: -2,989 kJ/molΔHform: -354 kJ/molΔHvap: 27.6 kJ/molDipole moment: 2.09 debyeSurface tension: 17.8 mN/mSpecific heat: 1.76 J/g/°CCoefficient of thermal expansion: 1.2 x 10-3Vapor pressure, 20 °: 190 mmVapor pressure, 50 °C: 591 mmCritical temperature: 224.6 °CCritical pressure: 31.6 atmMost economical and broadly used silylation reagentEnhances Claisen rearrangementEnhances the deprotection of tBOC-protected amino acidsEnhances ethylene glycol ketalization reactionCatalyzes the formation of chlorohydrin esters from diolsReviewed as water scavenger in reactions of carbonyl compoundsFacilitates Michael additionsReacts in presence of HCl acceptorWill silylate strong acids with expulsion of HClHigh purity grade available, SIT8510.1Protects hindered alcohols with Mg/DMFNafion SAC-13 has been shown to be a recyclable catalyst for the trimethylsilylation of primary, secondary, and tertiary alcohols in excellent yields and short reaction timesSummary of selective deprotection conditions is provided in Table 7 through Table 20 of the Silicon-Based Blocking Agents brochure

Formula: C₃H₉ClSi

Purity: 97%

Color and Shape: Straw Liquid

Molecular weight: 108.64

DIMETHYLSILA-14-CROWN-5, 95%

CAS:

• 70851-49-9

Silacrown (250.37 g/mol)
2,2-Dimethyl-1,3,6,9,12-pentaoxa-2-silacyclotetradecaneCrown ether analogDual end protected PEGPotential Li ion electrolyte

Formula: C₁₀H₂₂O₅Si

Purity: 95%

Color and Shape: Liquid

Molecular weight: 250.37

DIALLYLDIMETHYLSILANE, 92%

CAS:

• 1113-12-8

Formula: C₈H₁₆Si

Purity: 92%

Color and Shape: Straw Liquid

Molecular weight: 140.3

PENTAFLUOROPHENYLTRIETHOXYSILANE

CAS:

• 20083-34-5

Arylsilane Cross-Coupling Agent
The cross-coupling reaction is a highly useful methodology for the formation of carbon-carbon bonds. It involves two reagents, with one typically being a suitable organometallic reagent - the nucleophile - and the other a suitable organic substrate, normally an unsaturated halide, tosylate or similar - the electrophile.
Pentafluorophenyltriethoxysilane; Triethoxysilylperfluorobenzene
Forms hydrogen-free silicone resins useful in optical coatingsUseful for the preparation of pentafluorophenyl derivativesExtensive review of silicon based cross-coupling agents: Denmark, S. E. et al. "Organic Reactions, Volume 75" Denmark, S. E. ed., John Wiley and Sons, 233, 2011

Formula: C₁₂H₁₅F₅O₃Si

Purity: 97%

Color and Shape: Straw Liquid

Molecular weight: 330.33

1,2-BIS(TRIMETHOXYSILYL)DECANE

CAS:

• 832079-33-1

Alkyl Silane - Dipodal Surface Bonding
Aliphatic, fluorinated aliphatic or substituted aromatic hydrocarbon substituents are the hydrophobic entities which enable silanes to induce surface hydrophobicity. The organic substitution of the silane must be non-polar. The hydrophobic effect of the organic substitution can be related to the free energy of transfer of hydrocarbon molecules from an aqueous phase to a homogeneous hydrocarbon phase. A successful hydrophobic coating must eliminate or mitigate hydrogen bonding and shield polar surfaces from interaction with water by creating a non-polar interphase. Although silane and silicone derived coatings are in general the most hydrophobic, they maintain a high degree of permeability to water vapor. This allows coatings to breathe and reduce deterioration at the coating interface associated with entrapped water. Since ions are not transported through non-polar silane and silicone coatings, they offer protection to composite structures ranging from pigmented coatings to rebar reinforced concrete. A selection guide for hydrophobic silanes can be found on pages 22-31 of the Hydrophobicity, Hydrophilicity and Silane Surface Modification brochure.
Non Functional Alkoxy Silane
Silane coupling agents have the ability to form a durable bond between organic and inorganic materials to generate desired heterogeneous environments or to incorporate the bulk properties of different phases into a uniform composite structure. The general formula has two classes of functionality. The hydrolyzable group forms stable condensation products with siliceous surfaces and other oxides such as those of aluminum, zirconium, tin, titanium, and nickel. The organofunctional group alters the wetting or adhesion characteristics of the substrate, utilizes the substrate to catalyze chemical transformations at the heterogeneous interface, orders the interfacial region, or modifies its partition characteristics, and significantly effects the covalent bond between organic and inorganic materials.
Dipodal Silane
Dipodal silanes are a series of adhesion promoters that have intrinsic hydrolytic stabilities up to ~10,000 times greater than conventional silanes and are used in applications such as plastic optics, multilayer printed circuit boards and as adhesive primers for ferrous and nonferrous metals. They have the ability to form up to six bonds to a substrate compared to conventional silanes with the ability to form only three bonds to a substrate. Many conventional coupling agents are frequently used in combination with 10-40% of a non-functional dipodal silane, where the conventional coupling agent provides the appropriate functionality for the application, and the non-functional dipodal silane provides increased durability. Also known as bis-silanes additives enhance hydrolytic stability, which impacts on increased product shelf life, ensures better substrate bonding and also leads to improved mechanical properties in coatings as well as composite applications.
1,2-Bis(trimethoxysilyl)decane; 3,3,6,6-Tetramethoxy-4-octyl-2,7-dioxa-3,6-disilaoctane
Pendant dipodal silaneEmployed in high pH HPLCEmployed in the fabrication of luminescent molecular thermometers

Formula: C₁₆H₃₈O₆Si₂

Purity: 97%

Color and Shape: Liquid

Molecular weight: 382.65

(3-ACRYLOXYPROPYL)METHYLDIMETHOXYSILANE, tech

CAS:

• 13732-00-8

Acrylate Functional Dialkoxysilane
Silane coupling agents have the ability to form a durable bond between organic and inorganic materials to generate desired heterogeneous environments or to incorporate the bulk properties of different phases into a uniform composite structure. The general formula has two classes of functionality. The hydrolyzable group forms stable condensation products with siliceous surfaces and other oxides such as those of aluminum, zirconium, tin, titanium, and nickel. The organofunctional group alters the wetting or adhesion characteristics of the substrate, utilizes the substrate to catalyze chemical transformations at the heterogeneous interface, orders the interfacial region, or modifies its partition characteristics, and significantly effects the covalent bond between organic and inorganic materials.
3-(acryloxypropyl)methyldimethoxysilane, dimethoxymethylsilylpropyl acrylate
Employed in fabrication of photoimageable, low shrinkage multimode waveguidesCoupling agent for UV cure systemsUsed in microparticle surface modificationComonomer for free-radical polymerizaitonInhibited with MEHQ

Formula: C₉H₁₈O₄Si

Purity: tech

Color and Shape: Straw Liquid

Molecular weight: 218.33

1,3-BIS(4-BIPHENYL)-1,1,3,3-TETRAMETHYLDISILAZANE, 95%

CAS:

• 916667-75-9

Phenyl-Containing Blocking Agent
Used as a protecting group for reactive hydrogens in alcohols, amines, thiols, and carboxylic acids. Organosilanes are hydrogen-like, can be introduced in high yield, and can be removed under selective conditions. They are stable over a wide range of reaction conditions and can be removed in the presence of other functional groups, including other protecting groups. The tolerance of silylated alcohols to chemical transformations summary is presented in Table 1 of the Silicon-Based Blocking Agents brochure.
1,3-Bis(4-biphenyl)-1,1,3,3-tetramethyldisilazane
Reactivity and stability similar to that of SID4586.0Summary of selective deprotection conditions is provided in Table 7 through Table 20 of the Silicon-Based Blocking Agents brochure

Formula: C₂₈H₃₁NSi₂

Purity: 95%

Color and Shape: White Solid

Molecular weight: 437.73

1,1,3,3-TETRAMETHYLDISILOXANE, 99%

CAS:

• 3277-26-7

Formula: C₄H₁₄OSi₂

Purity: 99%

Color and Shape: Liquid

Molecular weight: 134.33

((CHLOROMETHYL)PHENYLETHYL)TRIMETHOXYSILANE

CAS:

• 68128-25-6

Halogen Functional Trialkoxy Silane
Silane coupling agents have the ability to form a durable bond between organic and inorganic materials to generate desired heterogeneous environments or to incorporate the bulk properties of different phases into a uniform composite structure. The general formula has two classes of functionality. The hydrolyzable group forms stable condensation products with siliceous surfaces and other oxides such as those of aluminum, zirconium, tin, titanium, and nickel. The organofunctional group alters the wetting or adhesion characteristics of the substrate, utilizes the substrate to catalyze chemical transformations at the heterogeneous interface, orders the interfacial region, or modifies its partition characteristics, and significantly effects the covalent bond between organic and inorganic materials.
((Chloromethyl)phenylethyl)trimethoxysilane; [2-[3(or 4)-(Chloromethyl)phenyl]ethyl]trimethoxysilane; (Trimethoxysilylethyl)benzyl chloride
Mixed m-, p- isomersUsed in microparticle surface modificationAdhesion promoter for polyphenylenesulfide and polyimide coatingsEmployed as a high temperature coupling agentDetermined by TGA a 25% weight loss of dried hydrolysates at 495 °CReagent for surface initiated atom-transfer radical-polymerization (ATRP) of N-isopropylacrylamide-butylmethacrylate copolymers

Formula: C₁₂H₁₉ClO₃Si

Purity: 97%

Color and Shape: Straw Liquid

Molecular weight: 274.82

n-BUTYLDIMETHYLCHLOROSILANE

CAS:

• 1000-50-6

Alkyl Silane - Conventional Surface Bonding
Aliphatic, fluorinated aliphatic or substituted aromatic hydrocarbon substituents are the hydrophobic entities which enable silanes to induce surface hydrophobicity. The organic substitution of the silane must be non-polar. The hydrophobic effect of the organic substitution can be related to the free energy of transfer of hydrocarbon molecules from an aqueous phase to a homogeneous hydrocarbon phase. A successful hydrophobic coating must eliminate or mitigate hydrogen bonding and shield polar surfaces from interaction with water by creating a non-polar interphase. Although silane and silicone derived coatings are in general the most hydrophobic, they maintain a high degree of permeability to water vapor. This allows coatings to breathe and reduce deterioration at the coating interface associated with entrapped water. Since ions are not transported through non-polar silane and silicone coatings, they offer protection to composite structures ranging from pigmented coatings to rebar reinforced concrete. A selection guide for hydrophobic silanes can be found on pages 22-31 of the Hydrophobicity, Hydrophilicity and Silane Surface Modification brochure.
n-Butyldimethylchlorosilane; Butylchlorodimethylsilane; Butyldimethylsilyl chloride; Chlorodimethyl-n-butylsilane
Forms bonded phases for HPLC

Formula: C₆H₁₅ClSi

Purity: 97%

Color and Shape: Liquid

Molecular weight: 150.72

1,1,1,3,3,3-HEXAMETHYLDISILAZANE, 99%

CAS:

• 999-97-3

Alkyl Silane - Conventional Surface Bonding
Aliphatic, fluorinated aliphatic or substituted aromatic hydrocarbon substituents are the hydrophobic entities which enable silanes to induce surface hydrophobicity. The organic substitution of the silane must be non-polar. The hydrophobic effect of the organic substitution can be related to the free energy of transfer of hydrocarbon molecules from an aqueous phase to a homogeneous hydrocarbon phase. A successful hydrophobic coating must eliminate or mitigate hydrogen bonding and shield polar surfaces from interaction with water by creating a non-polar interphase. Although silane and silicone derived coatings are in general the most hydrophobic, they maintain a high degree of permeability to water vapor. This allows coatings to breathe and reduce deterioration at the coating interface associated with entrapped water. Since ions are not transported through non-polar silane and silicone coatings, they offer protection to composite structures ranging from pigmented coatings to rebar reinforced concrete. A selection guide for hydrophobic silanes can be found on pages 22-31 of the Hydrophobicity, Hydrophilicity and Silane Surface Modification brochure.
Silane Cross-Coupling Agent
The cross-coupling reaction is a highly useful methodology for the formation of carbon-carbon bonds. It involves two reagents, with one typically being a suitable organometallic reagent - the nucleophile - and the other a suitable organic substrate, normally an unsaturated halide, tosylate or similar - the electrophile.
Trimethylsilyl Blocking Agent
Used as a protecting group for reactive hydrogens in alcohols, amines, thiols, and carboxylic acids. Organosilanes are hydrogen-like, can be introduced in high yield, and can be removed under selective conditions. They are stable over a wide range of reaction conditions and can be removed in the presence of other functional groups, including other protecting groups. The tolerance of silylated alcohols to chemical transformations summary is presented in Table 1 of the Silicon-Based Blocking Agents brochure.
ALD Material
Atomic layer deposition (ALD) is a chemically self-limiting deposition technique that is based on the sequential use of a gaseous chemical process. A thin film (as fine as -0.1 Å per cycle) results from repeating the deposition sequence as many times as needed to reach a certain thickness. The major characteristic of the films is the resulting conformality and the controlled deposition manner. Precursor selection is key in ALD processes, namely finding molecules which will have enough reactivity to produce the desired films yet are stable enough to be handled and safely delivered to the reaction chamber.
1,1,1,3,3,3-Hexamethyldisilazane; HMDS; HMDZ; Bis(trimethylsilyl)amine
<5 ppm chlorideStandard grade available, SIH6110.0Viscosity: 0.90 cStΔHcomb: 25,332 kJ/molΔHvap: 34.7 kJ/molDipole moment: 0.37 debyeSurface tension: 18.2 mN/mSpecific wetting surface: 485 m2/gVapor pressure, 50 °: 50 mmpKa: 7.55Photoresist adhesion promoterDielectric constant: 1000 Hz: 2.27Ea, reaction w/SiO2 surface: 73.7 kJ/molVersatile silylation reagentCreates hydrophobic surfacesConverts acid chlorides and alcohols to amines in a three-component reactionReacts with formamide and ketones to form pyrimidinesLithium reagent reacts w/ aryl chlorides or bromides to provide primary anilinesUsed to convert ketones to α-aminophosphonates

Formula: C₆H₁₉NSi₂

Purity: 99%

Color and Shape: Colourless Liquid

Molecular weight: 161.39

VINYLPENTAMETHYLDISILOXANE

CAS:

• 1438-79-5

Formula: C₇H₁₈OSi₂

Purity: 97%

Color and Shape: Liquid

Molecular weight: 174.39

(30-35% TRIETHOXYSILYLETHYL)ETHYLENE-(35-40% 1,4-BUTADIENE)-(25-30% STYRENE) terpolymer, 50% in toluene

(30-35% Triethoxysilylethyl)ethylene-(35-40% 1,4-butadiene)-(25-30% styrene) terpolymer; (vinyltriethoxysilane)-(1,2-butadiene)-(styrene) terpolymer
Multi-functional polymeric trialkoxy silaneHydrophobic modified polybutadiene50% in tolueneViscosity: 20-30 cSt

Color and Shape: Pale Yellow Amber Liquid

Molecular weight: 4500-5500

HEXADECYLTRIETHOXYSILANE, 92%

CAS:

• 16415-13-7

Alkyl Silane - Conventional Surface Bonding
Aliphatic, fluorinated aliphatic or substituted aromatic hydrocarbon substituents are the hydrophobic entities which enable silanes to induce surface hydrophobicity. The organic substitution of the silane must be non-polar. The hydrophobic effect of the organic substitution can be related to the free energy of transfer of hydrocarbon molecules from an aqueous phase to a homogeneous hydrocarbon phase. A successful hydrophobic coating must eliminate or mitigate hydrogen bonding and shield polar surfaces from interaction with water by creating a non-polar interphase. Although silane and silicone derived coatings are in general the most hydrophobic, they maintain a high degree of permeability to water vapor. This allows coatings to breathe and reduce deterioration at the coating interface associated with entrapped water. Since ions are not transported through non-polar silane and silicone coatings, they offer protection to composite structures ranging from pigmented coatings to rebar reinforced concrete. A selection guide for hydrophobic silanes can be found on pages 22-31 of the Hydrophobicity, Hydrophilicity and Silane Surface Modification brochure.
Hexadecyltriethoxysilane; Triethoxysilylhexadecane; Cetyltriethoxysilane
Trialkoxy silane

Formula: C₂₂H₄₈O₃Si

Purity: 92%

Color and Shape: Straw Liquid

Molecular weight: 388.71

n-OCTADECYLTRICHLOROSILANE, 97%

CAS:

• 112-04-9

Alkyl Silane - Conventional Surface Bonding
Aliphatic, fluorinated aliphatic or substituted aromatic hydrocarbon substituents are the hydrophobic entities which enable silanes to induce surface hydrophobicity. The organic substitution of the silane must be non-polar. The hydrophobic effect of the organic substitution can be related to the free energy of transfer of hydrocarbon molecules from an aqueous phase to a homogeneous hydrocarbon phase. A successful hydrophobic coating must eliminate or mitigate hydrogen bonding and shield polar surfaces from interaction with water by creating a non-polar interphase. Although silane and silicone derived coatings are in general the most hydrophobic, they maintain a high degree of permeability to water vapor. This allows coatings to breathe and reduce deterioration at the coating interface associated with entrapped water. Since ions are not transported through non-polar silane and silicone coatings, they offer protection to composite structures ranging from pigmented coatings to rebar reinforced concrete. A selection guide for hydrophobic silanes can be found on pages 22-31 of the Hydrophobicity, Hydrophilicity and Silane Surface Modification brochure.
n-Octadecyltrichlorosilane; OTS; Trichlorosilyloctadecane; Trichlorooctadecylsilane
Contains <5% C18 isomersProvides lipophilic surface coatingsEmployed in patterning and printing of electroactive molecular filmsImmobilizes physiologically active cell organellesTreated substrates increase electron transport of pentacene filmsHighest concentration of terminal silane substitution

Formula: C₁₈H₃₇Cl₃Si

Purity: 97% including isomers

Color and Shape: Straw Liquid

Molecular weight: 387.93

n-OCTYLTRICHLOROSILANE

CAS:

• 5283-66-9

Alkyl Silane - Conventional Surface Bonding
Aliphatic, fluorinated aliphatic or substituted aromatic hydrocarbon substituents are the hydrophobic entities which enable silanes to induce surface hydrophobicity. The organic substitution of the silane must be non-polar. The hydrophobic effect of the organic substitution can be related to the free energy of transfer of hydrocarbon molecules from an aqueous phase to a homogeneous hydrocarbon phase. A successful hydrophobic coating must eliminate or mitigate hydrogen bonding and shield polar surfaces from interaction with water by creating a non-polar interphase. Although silane and silicone derived coatings are in general the most hydrophobic, they maintain a high degree of permeability to water vapor. This allows coatings to breathe and reduce deterioration at the coating interface associated with entrapped water. Since ions are not transported through non-polar silane and silicone coatings, they offer protection to composite structures ranging from pigmented coatings to rebar reinforced concrete. A selection guide for hydrophobic silanes can be found on pages 22-31 of the Hydrophobicity, Hydrophilicity and Silane Surface Modification brochure.
n-Octyltrichlorosilane; Trichlorosilyloctane; Trichlorooctylsilane
Vapor pressure, 125 °C: 1 mmSiO2 surface modification improves pentacene organic electronic performance

Formula: C₈H₁₇Cl₃Si

Purity: 97%

Color and Shape: Straw Liquid

Molecular weight: 247.67