News Treehugger Voices Why Has Roman Concrete Lasted So Long? By Lloyd Alter Lloyd Alter Facebook Twitter Design Editor University of Toronto Lloyd Alter is Design Editor for Treehugger and teaches Sustainable Design at Ryerson University in Toronto. Learn about our editorial process Updated October 11, 2018 CC BY 2.0. Lloyd Alter Share Twitter Pinterest Email News Environment Business & Policy Science Animals Home & Design Current Events Treehugger Voices News Archive The Pantheon looks pretty good for a 1900 year old building, considering that it is the largest unreinforced concrete dome in the world. Perhaps it's because it was not reinforced, so there was no iron to rust and expand, or perhaps because Roman concrete was different than the stuff we use today. TreeHugger has noted before that Roman concrete was a whole lot greener than today's mixes; now a new study by researchers at the Berkeley Lab shows that the concrete actually gets stronger over time. CC BY 2.0. Lloyd Alter Lloyd Alter/CC BY 2.0 Unlike modern concrete which actually shrinks, opening up tiny cracks that propagate and let moisture in, Roman concrete, made with volcanic ash instead of portland cement, is actually self-healing as a crystalline binder forms and prevents the concrete from cracking any further. According to Marie Jackson of UC Berkeley: The mortar resists microcracking through in situ crystallization of platy strätlingite, a durable calcium-alumino-silicate mineral that reinforces interfacial zones and the cementitious matrix. The dense intergrowths of the platy crystals obstruct crack propagation and preserve cohesion at the micron scale, which in turn enables the concrete to maintain its chemical resilience and structural integrity in a seismically active environment at the millennial scale. So not only would concrete made with volcanic ash have a much lower carbon footprint, It would last a lot longer. Jackson continues in a more comprehensible tone: If we can find ways to incorporate a substantial volumetric component of volcanic rock in the production of specialty concretes, we could greatly reduce the carbon emissions associated with their production also improve their durability and mechanical resistance over time. © Gates Notes The making of cement accounts for as much as 7% of the CO2 produced each year; the amount of the stuff being poured these days is extraordinary. Vaclav Smil tells Bill Gates that the statistic shown above is the most staggering in his book, Making the Modern World: Materials and Dematerialization. We use far too much of the stuff and it doesn't last nearly as long as we thought it would. Time for a change.