R G Catalyst Site
It's the only way to survive.
The δ-phase was terrifyingly efficient. It could crack anything—including the steel walls of the reactor. In 2102, at the giant Port Arthur Gemini Refinery in Texas, an RG-47δ runaway event occurred. The catalyst, starved of sulfur after cleaning the feedstock too well, began extracting iron and chromium atoms from the reactor vessel's Inconel lining. It was eating the refinery from the inside . Operators only noticed when a pressure drop revealed that a 10cm-thick alloy wall had been transformed into a honeycomb of rust and volatile nickel carbonyl. The disaster wasn't an explosion. It was a corrosion cascade . Three refineries in two years suffered catastrophic reactor failures. The final straw was the "Rotterdam Whisper"—a tank of RG-99 that spontaneously depolymerized its storage vessel's polymer lining, releasing a cloud of atomized catalyst into the facility's ventilation system. Twenty-three workers developed a mysterious, incurable lung condition where their own mucous membranes began catalyzing the breakdown of oxygen into ozone. r g catalyst
The "R.G." in its name quickly took on a new, unofficial meaning among engineers: The Golden Age and the Creep From 2092 to 2101, R.G. Catalyst ushered in a "Second Petrochemical Renaissance." Refineries using RG-47 and its successors (RG-61, RG-99) ran for 18 months without a single regeneration shutdown. They could digest the vilest feedstocks: tar sands bitumen, pyrolyzed plastic waste, even ancient landfill organic slurry. The catalyst didn't just crack heavy oils into gasoline; it reassembled them, producing precise yields of propylene, butadiene, and benzene on demand. Carbon emissions from refining dropped 40% globally. It's the only way to survive
It wasn't a person. It wasn't even a single compound. R.G. Catalyst was an idea—an accident—that rewrote the rules of molecular transformation. The story begins not in a gleaming lab, but in the forgotten sub-basement of the now-defunct Rostock-Greifswald Institute of Applied Rheology (the "R.G." of its namesake). In 2089, a desperate team led by Dr. Aris Thorne was trying to solve "The Coking Crisis." Traditional zeolite catalysts, the workhorses of fluid catalytic cracking (FCC), were poisoning themselves. Carbonaceous coke built up on their intricate honeycomb pores within hours, not days, forcing refineries to shut down for costly "regeneration burns." In 2102, at the giant Port Arthur Gemini
Thorne’s team was experimenting with a new class of "dynamic lattice" catalysts—crystalline structures that could flex and breathe. Their 47th formulation, designated , was a bizarre hybrid: a core of modified ZSM-5 zeolite, infused with a rare-earth organometallic framework of lanthanum and a then-unstable allotrope of graphene they called "tensile carbon."