Phillipsite and Al-tobermorite Mineral Cements Produced through Low-Temperature Water-Rock Reactions in Roman Marine Concrete

Authors

Sean R. Mulcahy, Western Washington UniversityFollow
Marie D. Jackson, University of Utah, Salt Lake City
Heng Chen, Southeast University, Nanjing
Yao Li, Xi'an Jiaotong University, Xi'an
Piergiulio Cappelletti, Università degli Studi di Napoli Federico II, Naples
Hans-Rudolf Wenk, University of California, Berkeley

Document Type

Article

Publication Date

2017

Keywords

Phillipsite, Al-tobermorite, Roman concrete, Natural pozzolan, Water-rock reaction

Abstract

Pozzolanic reaction of volcanic ash with hydrated lime is thought to dominate the cementing fabric and durability of 2000-year-old Roman harbor concrete. Pliny the Elder, however, in first century CE emphasized rock-like cementitious processes involving volcanic ash (pulvis) “that as soon as it comes into contact with the waves of the sea and is submerged becomes a single stone mass (fierem unum lapidem), impregnable to the waves and every day stronger” (Naturalis Historia 35.166). Pozzolanic crystallization of Al-tobermorite, a rare, hydrothermal, calcium-silicate-hydrate mineral with cation exchange capabilities, has been previously recognized in relict lime clasts of the concrete. Synchrotron-based X-ray microdiffraction maps of cementitious microstructures in Baianus Sinus and Portus Neronis submarine breakwaters and a Portus Cosanus subaerial pier now reveal that Al-tobermorite also occurs in the leached perimeters of feldspar fragments, zeolitized pumice vesicles, and in situ phillipsite fabrics in relict pores. Production of alkaline pore fluids through dissolution-precipitation, cation-exchange and/or carbonation reactions with Campi Flegrei ash components, similar to processes in altered trachytic and basaltic tuffs, created multiple pathways to post-pozzolanic phillipsite and Al-tobermorite crystallization at ambient seawater and surface temperatures. Long-term chemical resilience of the concrete evidently relied on water-rock interactions, as Pliny the Elder inferred. Raman spectroscopic analyses of Baianus Sinus Al-tobermorite in diverse microstructural environments indicate a cross-linked structure with Al³⁺ substitution for Si⁴⁺ in Q³ tetrahedral sites, and suggest coupled [Al³⁺ + Na⁺ ] substitution and potential for cation exchange. The mineral fabrics provide a geoarchaeological prototype for developing cementitious processes through low-temperature rock-fluid interactions, subsequent to an initial phase of reaction with lime that defines the activity of natural pozzolans. These processes have relevance to carbonation reactions in storage reservoirs for CO₂ in pyroclastic rocks, production of alkali-activated mineral cements in maritime concretes, and regenerative cementitious resilience in waste encapsulations using natural volcanic pozzolans.

Publication Title

American Mineralogist

Volume

102

First Page

1435

Last Page

1450

Required Publisher's Statement

Published by the Mineralogical Society of America

This article was published under the Gold Open Access option.

http://www.minsocam.org/msa/ammin/toc/2017/index.html?issue_number=07

DOI: http://dx.doi.org/10.2138/am-2017-5993CCBY

Recommended Citation

Mulcahy, Sean R.; Jackson, Marie D.; Chen, Heng; Li, Yao; Cappelletti, Piergiulio; and Wenk, Hans-Rudolf, "Phillipsite and Al-tobermorite Mineral Cements Produced through Low-Temperature Water-Rock Reactions in Roman Marine Concrete" (2017). Geology Faculty Publications. 67.
https://cedar.wwu.edu/geology_facpubs/67

Subjects - Topical (LCSH)

Roman cement; Pozzuolanas--Italy--Rome; Lime--Italy--Rome

Geographic Coverage

Rome

Genre/Form

articles

Type

Text

Language

English

Format

application/pdf