Product List
Reaxis C125 – Stannous Neodecanoate | Stannous Neodecanoate | Request A Sample |
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Reaxis C129 – Stannous Octoate | Stannous Octoate | Request A Sample |
Reaxis C160 – Stannous Oxalate | Stannous Oxalate | Request A Sample |
Reaxis C188 | Stannous Oxide | Request A Sample |
Reaxis C2012 M70 | Dibutyltin Blend | Request A Sample |
Reaxis C2013 | Dioctyltin Diacetyl Acetonate | Request A Sample |
Reaxis C208 | Dioctyltin bis-(2-ethylhexanoate) | Request A Sample |
Reaxis C214 | Dioctyltin bis-(isooctyl mercaptoacetate) | Request A Sample |
Reaxis C216 | Dioctyltin Dilaurate | Request A Sample |
Reaxis C218 | Dibutyltin Dilaurate | Request A Sample |
Reaxis C220 | Monobutyltin Tris-(2-ethylhexanoate) | Request A Sample |
Reaxis C221 | Dibutyltin Dineodecanoate | Request A Sample |
Reaxis C226 | Dibutyl Tin bis-(acetylacetonate) | Request A Sample |
Reaxis C227 | Dibutyltin bis-(1-thioglycerol) | Request A Sample |
Reaxis C228 | Dioctyltin Diacetate | Request A Sample |
Reaxis C233 | Dibutyltin Diacetate | Request A Sample |
Reaxis C233T | Dibutyltin Diacetate | Request A Sample |
Reaxis C248 | Dibutyltin Oxide | Request A Sample |
Reaxis C248D | Dibutyltin Oxide/ Plasticizer Blend | Request A Sample |
Reaxis C248DN | Dibutyltin Oxide/Plasticizer Blend | Request A Sample |
Reaxis C248DP | Dibutyltin Oxide/Plasticizer Blend | Request A Sample |
Reaxis C248LC | Dibutyltin Oxide | Request A Sample |
Reaxis C248T | Dibutyltin Oxide + Silane Complex | Request A Sample |
Reaxis C248VM | Dibutyltin Oxide + Silane | Request A Sample |
Reaxis C311T | Dioctyltin bis-(2-ethylhexyl maleate) | Request A Sample |
Reaxis C311X | Dibutyltin bis-(2-ethylhexyl maleate) | Request A Sample |
Reaxis C314 | Dioctyltin bis-(2-ethylhexyl maleate) | Request A Sample |
Reaxis C316 | Dimethyltin Dioleate (Dimethyl bis(oleoyloxy stannane) | Request A Sample |
Reaxis C317 – Dibutyltin bis-(2-ethylhexyl maleate) | Dibutyltin bis-(2-ethylhexyl maleate) | Request A Sample |
Reaxis C318 | Dioctyltin Dineodecanoate | Request A Sample |
Reaxis C319 | Dibutyltin Dilauryl Mercaptide | Request A Sample |
Reaxis C320 | Dioctyltin Dilauryl Mercaptide | Request A Sample |
Reaxis C3208 | Bismuth Neodecanoate | Request A Sample |
Reaxis C3209 | Bismuth Neodecanoate (Low Viscosity) | Request A Sample |
Reaxis C3210 | Bismuth Octoate (Catalyst Grade) | Request A Sample |
Reaxis C322 | Dibutyltin bis-(2-ethylhexyl mercaptoacetate) | Request A Sample |
Reaxis C325 | Dimethyltin Dineodecanoate | Request A Sample |
Reaxis C416 | Dioctyltin bis-(2-ethylhexyl mercaptoacetate) | Request A Sample |
Reaxis C417 | Dioctyltin Oxide/Silane Complex | Request A Sample |
Reaxis C417V | Dioctyltin Oxide and Silane | Request A Sample |
Reaxis C417VM | Dioctyltin Oxide/Silane Complex | Request A Sample |
Reaxis C418 | Dibutyltin bis-(isooctyl mercaptoacetate) | Request A Sample |
Reaxis C616 | Zinc Neodecanoate | Request A Sample |
Reaxis C620 | Zinc Octoate | Request A Sample |
Reaxis C708 | Zinc/Bismuth Neodecanoate Blend | Request A Sample |
Reaxis C716 | Bismuth Neodecanoate | Request A Sample |
Reaxis C716LV | Bismuth Neodecanoate (Low Viscosity) | Request A Sample |
Reaxis C717 | Zinc/Bismuth Octoate Blend | Request A Sample |
Reaxis C719 | Bismuth Methanesulfonate Solution | Request A Sample |
Reaxis C739E50 | Proprietary Water Soluble Bismuth Complex | Request A Sample |
Reaxis C739P50 | Proprietary Water Soluble Bismuth Complex | Request A Sample |
Reaxis C739W50 | Water Soluble Bismuth Complex | Request A Sample |
Reaxis E155 | Stannous Sulfate Crystal | Request A Sample |
Metal-based Catalysts and Polymerization
Metal-based catalysts play a crucial role in the polymerization process that occurs during the synthesis of these coatings, with different catalysts producing different final results in the coating created. Metal-based catalysts tend to be the preferred product for these applications, as metal-based catalysts like dibutyltin oxide, stannous octoate and dibutyltin dilaurate lead to faster curing times and more efficient overall production times than competing products.
Polyurethane Coatings
In the formulation of polyurethane coatings, metal-based catalysts are used to begin the reaction between diisocyanates and polyols, which are the central components in polyurethane coatings. Commonly used metal catalysts include tin, bismuth compounds, and zinc compounds, which help to facilitate the reaction between the two components and ensure an efficient curing process in the creation of these coatings. The specific catalyst used to create each coating depends on the desired properties of the polyurethane coating, such as its hardness, flexibility, or chemical resistance. If you’re looking for a catalyst for foams, we also offer polyurethane foam chemicals.
Silicone Coatings
Similarly, metal-based catalysts are also used in the formulation of silicone coatings. These catalysts play a critical role in the crosslinking process that occurs during the synthesis of silicone coatings. The specific metal-based catalyst used in production depends on the desired properties of the silicone coating, such as its heat resistance or flexibility, the needs of which vary by application.
Advantages of Using Metal-Based Catalysts in Coating Production
The use of metal-based catalysts in the production of polyurethane and silicone coatings allows for a controlled and efficient curing process, resulting in coatings with pre-selected properties and performance characteristics. Choosing the appropriate metal catalyst for each application is essential to create the coating that you need.
If you’re unsure which catalyst you need, contact us with your questions and we’ll help you find what you need. You can also request a sample of each chemical on their respective product page.