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Title: Mechanical resilience and cementitious processes in Imperial Roman architectural mortar

Journal Article · · Proceedings of the National Academy of Sciences of the United States of America
ORCiD logo [1];  [2];  [3];  [4];  [5];  [6];  [7];  [1];  [1];  [8]
  1. Univ. of California, Berkeley, CA (United States)
  2. Univ. of Maine, Orono, ME (United States)
  3. DuPont Engineering Research and Technology, Wilmington, DE (United States)
  4. Ufficio Fori Imperiali, Rome (Italy)
  5. Univ. of California, Berkeley, CA (United States); Southeast Univ., Nanjing (China)
  6. Univ. of California, Berkeley, CA (United States); Southeast Univ. Nanjing (China)
  7. Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States)
  8. Cornell Univ., Ithaca, NY (United States)
+ Show Author Affiliations

The pyroclastic aggregate concrete of Trajan’s Markets (110 CE), now Museo Fori Imperiali in Rome, has absorbed energy from seismic ground shaking and long-term foundation settlement for nearly two millenia while remaining largely intact at the structural scale. The scientific basis of this exceptional service record is explored through computed tomography of fracture surfaces and synchroton X-ray microdiffraction analyses of a reproduction of the standardized hydrated lime–volcanic ash mortar that binds decimeter-sized tuff and brick aggregate in the conglomeratic concrete. The mortar reproduction gains fracture toughness over 180 d through progressive coalescence of calcium–aluminum-silicate–hydrate (C-A-S-H) cementing binder with Ca/(Si+Al) ≈ 0.8–0.9 and crystallization of strätlingite and siliceous hydrogarnet (katoite) at ≥90 d, after pozzolanic consumption of hydrated lime was complete. Platey strätlingite crystals toughen interfacial zones along scoria perimeters and impede macroscale propagation of crack segments. In the 1,900 year old mortar, C-A-S-H has low Ca/(Si+Al) ≈ 0.45–0.75. Dense clusters of 2- to 30-µm strätlingite plates further reinforce interfacial zones, the weakest link of modern cement-based concrete, and the cementitious matrix. These crystals formed during long-term autogeneous reaction of dissolved calcite from lime and the alkali-rich scoriae groundmass, clay mineral (halloysite), and zeolite (phillipsite and chabazite) surface textures from the Pozzolane Rosse pyroclastic flow, erupted from the nearby Alban Hills volcano. The clast-supported conglomeratic fabric of the concrete presents further resistance to fracture propagation at the structural scale.

Research Organization:
Lawrence Berkeley National Laboratory (LBNL), Berkeley, CA (United States)
Sponsoring Organization:
USDOE
Grant/Contract Number:
AC02-05CH11231
OSTI ID:
1221827
Journal Information:
Proceedings of the National Academy of Sciences of the United States of America, Vol. 111, Issue 52; ISSN 0027-8424
Publisher:
National Academy of Sciences, Washington, DC (United States)Copyright Statement
Country of Publication:
United States
Language:
English
Citation Metrics:
Cited by: 70 works
Citation information provided by
Web of Science

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Cited By (9)

Physical and Mechanical Properties of Composites Made with Aluminous Cement and Basalt Fibers Developed for High Temperature Application journal January 2015
Time resolved alkali silicate decondensation by sodium hydroxide solution journal January 2020
A study on the effects of an explosion in the Pantheon of Rome journal June 2018
Large-scale micron-order 3D surface correlative chemical imaging of ancient Roman concrete journal February 2019
Stability of strätlingite in the CASH system journal January 2016
Continuous Synthesis of Nanominerals in Supercritical Water journal January 2019
Environmental Impacts of Sand Exploitation. Analysis of Sand Market journal June 2017
Advances in understanding alkali-activated materials journal December 2015
Towards sustainable concrete journal June 2017

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36 MATERIALS SCIENCE
Roman concrete
volcanic ash mortar
fracture toughness
interfacial zone
strätlingite