Silicone elastomers cure by one of three fundamentally different chemistries, and the catalyst is what makes the chemistry happen. Condensation cure (RTV-1 sealants, RTV-2 mould rubber, dental impression) crosslinks silanol-terminated PDMS with tetra-functional silanes by releasing acetic acid, oxime, alcohol or amine — and it requires a tin or titanate catalyst to hit usable cure rates at room temperature. Addition cure (LSR injection, RTV-2 medical, optical encapsulation) joins vinyl-functional PDMS to Si-H crosslinkers via hydrosilylation — and it requires a platinum complex, with no byproduct released. Peroxide cure (HTV high-consistency rubber, extruded profiles, cable jackets) generates free radicals at 120–170°C that abstract methyl protons and crosslink chains — DCBP for the lowest-temperature cure window, DCP and DBPH for higher exotherm tolerance.
Mismatching the catalyst to the chemistry produces silent process failures: a tin catalyst added to an addition-cure formulation will not cure (the platinum complex is also poisoned by the tin), and a platinum catalyst in a condensation-cure system does nothing useful. Worse, silicone formulators routinely encounter poisoning issues — sulphur, amines, organotin compounds and certain phosphorus species are catastrophic for platinum systems even at ppm levels. Catalyst selection is therefore not just a chemistry decision but a contamination-control decision affecting the entire production line.
Organotin compounds are the dominant catalyst class for condensation-cure RTV silicones, polyurethane elastomers, and ester transesterification. SEMITECH stocks three core grades: DBTDL (dibutyltin dilaurate, CAS 77-58-7) — the highest-activity, most widely specified tin catalyst, used at 0.05–0.5% in alkoxy- and oxime-cure RTV-1 sealants, RTV-2 condensation moulding compounds, and as a urethane gel-time controller; DOTL (dibutyltin diacetate, CAS 1067-33-0) — slightly lower activity than DBTDL, preferred when a longer pot-life is needed or when acetate byproducts are tolerable; and T-9 stannous octoate (tin(II) 2-ethylhexanoate, CAS 301-10-0) — a divalent tin compound used in flexible polyurethane foam, certain neutral-cure silicones, and condensation-cure dental and prosthetic silicones where reduced toxicity (relative to DBTDL) is specified. All three deliver tack-free times of 30–120 minutes at 23°C and 50% RH in standard formulations.
All three tin catalysts hydrolyse on prolonged exposure to atmospheric moisture, forming inactive tin oxide hydrates. Storage in sealed steel drums under nitrogen blanket is recommended for shelf life beyond 12 months; opened drums should be consumed within 60 days for consistent activity.
Addition-cure silicone systems — liquid silicone rubber (LSR) injection moulding, RTV-2 medical and optical, food-contact and skin-contact silicones — rely on platinum complexes to catalyse the hydrosilylation of vinyl-PDMS with Si-H functional crosslinker. Karstedt’s catalyst (platinum-divinyltetramethyldisiloxane complex, typically supplied as 2–5% Pt in xylene or in vinyl-PDMS solvent) is the modern industry standard — far more active and selective than the original chloroplatinic acid system, with no chloride residue to colour the cured part. SEMITECH supplies Karstedt at three Pt loadings — 2%, 3%, and 5% by weight — in vinyl-functional siloxane solvent, allowing direct dosing into either the A-side or B-side of two-part LSR systems. Typical use level is 5–20 ppm Pt on the total silicone, giving cure times of 10–30 seconds at 150°C in injection moulding or 5–30 minutes at 80–120°C in RTV-2 cast moulding.
Speier’s catalyst (chloroplatinic acid hexahydrate, H₂PtCl₆·6H₂O, CAS 18497-13-7) is the historical and lower-cost alternative. SEMITECH supplies it as a 0.1–10% solution in isopropanol for legacy formulations and for hydrosilylation chemistry research where the chloride byproduct is acceptable. Speier is more sensitive to inhibition by alkynes, sulphur, and amines than Karstedt and produces some chloride-related cure colour, but remains specified in many industrial RTV-2 and silane synthesis applications because of its lower cost per Pt mole.
DCBP (bis(2,4-dichlorobenzoyl) peroxide, CAS 133-14-2) is the lowest-decomposition-temperature peroxide widely used in HTV silicone rubber, with a 1-minute half-life at 124°C. SEMITECH supplies it as a 50% paste in silicone fluid — the standard form for safe handling and uniform dispersion in HCR mill-mix processes. DCBP is preferred for thin-section extruded profiles (cable jackets, gaskets, tubing) where short cure cycles in continuous hot-air vulcanisation tunnels demand fast onset. Higher-temperature peroxides — DCP (dicumyl peroxide) and DBPH (2,5-dimethyl-2,5-di(tert-butylperoxy)hexane) — are used in injection moulding of HCR where higher exotherm and longer scorch safety are required, and SEMITECH stocks both as inventory items in addition to the headline DCBP grade.
TBT (tetra-n-butyl titanate, CAS 5593-70-4) and TET (titanium acetylacetonate / Tyzor AA-equivalent chelated titanate) function as condensation-cure catalysts in dealcoholisation-cure RTV silicones — the neutral, non-acetic-acid-evolving systems specified for sensitive substrates (mirror-grade glass, copper electronics, marble). Titanate-cured RTVs cure more slowly than tin-cured but produce no corrosive byproducts. TBT is also used as a transesterification catalyst for PET polymerisation (the volume application that drives global TBT demand) and as a crosslinker in coil coatings and printing inks. TET adds chelation stability — useful in waterborne coatings and one-component formulations where bare TBT would hydrolyse prematurely.
Catalyst quality is the single largest source of silent batch-to-batch variation in silicone production. SEMITECH issues a CoA on every shipment with the active-component assay (Pt content for Karstedt by ICP-MS, Sn content for tin grades by XRF or titration, peroxide active oxygen content for DCBP by iodometric titration), water content (Karl Fischer for moisture-sensitive grades) and appearance/colour. MOQ is 25 kg for the tin and titanate grades, 1 kg for Karstedt 5% solutions, and 200 kg for DCBP paste. Standard packing is HDPE jerrycans (5 / 25 kg) for liquids and HDPE pails (25 kg) for pastes. Lead time ex-China is 2–4 weeks to Southeast Asia, 4–6 weeks to Europe and North America. Air freight available for Karstedt small-volume samples and laboratory quantities of Speier.
Storage discipline matters more for catalysts than for almost any other silicone consumable: tin catalysts hydrolyse with moisture, platinum is poisoned by sulphur and amine vapours, peroxides decompose with elevated storage temperature. Recommended storage is sealed, original packaging, below 25°C, away from incompatible chemicals. Detailed material safety datasheets covering REACH, GHS, and DOT/IMDG transport classifications are issued with every shipment.
All eight grades are stocked items in SEMITECH inventory; CoA issued per batch. Equivalent industry trade names noted for buyer cross-reference.
| Grade | Chemistry / CAS | Cure Type | Active Content | Typical Loading | Primary Application |
|---|---|---|---|---|---|
| DBTDL | Dibutyltin dilaurate / 77-58-7 | Condensation | ≥97% (Sn 18.0–18.5%) | 0.05–0.5% | RTV-1/RTV-2 silicone, PU |
| DOTL | Dibutyltin diacetate / 1067-33-0 | Condensation | ≥98% | 0.1–0.8% | Long-pot-life RTV sealants |
| T-9 | Stannous octoate / 301-10-0 | Condensation / PU | ≥95% (Sn 28%) | 0.05–0.3% | PU foam, dental silicone |
| Karstedt 5% | Pt-divinyl-tetramethyldisiloxane complex | Addition | 5.0% Pt in vinyl-siloxane | 5–20 ppm Pt | LSR, RTV-2, optical encapsulation |
| Speier (H₂PtCl₆) | Chloroplatinic acid·6H₂O / 18497-13-7 | Addition / hydrosilylation | ≥99% (in IPA solution) | 10–50 ppm Pt | Industrial RTV-2, silane synthesis |
| DCBP 50% paste | Bis(2,4-dichlorobenzoyl) peroxide / 133-14-2 | Peroxide (free radical) | 50% in silicone fluid | 0.5–1.5 phr | HTV silicone, hot-air vulcanisation |
| TBT | Tetra-n-butyl titanate / 5593-70-4 | Condensation (titanate) | ≥98% (TiO₂ 14.0–14.3%) | 0.5–2.0% | Dealcoholisation-cure RTV, PET catalyst |
| TET (Ti AcAc) | Titanium acetylacetonate (Tyzor AA-eq.) | Condensation (chelated) | 75% in IPA | 0.5–2.0% | Waterborne coatings, 1K RTV |