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Why ancient Roman concrete still stands while modern version erodes

The project conducted several drills of Roman structures, including at the Portus Cosanus pier in Orbetello.

The project conducted several drills of Roman structures, including at the Portus Cosanus pier in Orbetello. Photo: JP Oleson/ABC

Ancient Roman concrete marine structures built thousands of years ago are stronger now than when they were first built.

So how has Roman concrete outlasted the empire, while modern concrete mixtures erode within decades of being exposed to seawater?

Scientists have uncovered the chemistry behind how Roman sea walls and harbour piers resisted the elements, and what modern engineers could learn from it.

Romans built their sea walls from a mixture of lime (calcium oxide), volcanic rocks and volcanic ash, a study, published in the journal American Mineralogist, found.

Elements within the volcanic material reacted with sea water to strengthen the concrete structure and prevent cracks from growing over time.

“It’s the most durable building material in human history, and I say that as an engineer not prone to hyperbole,” Roman monument expert Phillip Brune told the Washington Post.

What is modern concrete made of?

Nowadays, we create concrete from a mixture of limestone, sandstone, ash, chalk, iron and clay.

Modern sea walls require steel reinforcements, and the concrete is designed not to change after it sets.

On the other hand, the Roman recipe was designed to reinforce itself over time.

“They spent a tremendous amount of work [on developing] this – they were very, very intelligent people,” study co-author Marie Jackson told The Guardian.

So how does it work?

Scientists previously discovered Roman concrete contained aluminous tobermorite, a rare mineral that is hard to produce.

Ancient Roman concrete drill sites

Ancient Roman concrete harbours and the project’s drill sites, as indicated by the green circles. Volcanic districts are indicated by red triangles. Photo: Marie Jackson et al/ABC

The tobermorite formed within the Roman concrete early on, as seawater reacted with the mixture to generate heat.

Now a more detailed examination of the chemistry of the concrete showed significant amounts of that rare mineral growing out of another mineral naturally found in volcanic rock called phillipsite.

The long-term exposure of the concrete to seawater caused both the tobermorite and phillipsite to crystallise throughout the concrete.

These prevented cracks from forming, therefore reinforcing the concrete over time.

The researchers said this could lead to more environmentally friendly ways of modern concrete construction, but warned it may take years before the precise Roman mixture was discovered.

“I think [the research] opens up a completely new perspective for how concrete can be made,” Dr Jackson said.

“That what we consider corrosion processes can actually produce extremely beneficial mineral cement and lead to continued resilience, in fact, enhanced perhaps resilience over time.”

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