# Study on repair materials and technologies for addressing crack-related damage in the Earthen City Wall of Kaifeng

**Authors:** Tingting Yue, Xizhi Zhang, Jianwei Yue, Wenhao Li, Xiang Zhu, Jingwen Yue, Gobinath Ravindran, Jason Morgan, Hailing Ma, Hailing Ma

PMC · DOI: 10.1371/journal.pone.0334834 · 2025-10-27

## TL;DR

This study develops and tests repair materials to fix cracks in the ancient Kaifeng city wall, focusing on improving durability and waterproofing.

## Contribution

A novel high-fluidity crack repair material combining urea urease, quicklime, and sodium methylsilicate is proposed and experimentally validated.

## Key findings

- A repair material with 7.5% quicklime and 7% sodium methylsilicate achieved a total efficacy coefficient of 96.25.
- Waterborne polyurethane showed the best waterproofing performance among tested agents.
- The repair material maintained structural integrity after 30 freeze-thaw cycles.

## Abstract

Rain and snow seepage into the cracks of the soil wall is the leading cause of its surface weathering, and the key to crack repair lies in developing reasonable repair materials. Based on the carbonation principle and mineralization mechanism of quicklime, this study focuses on the cracks in the city wall of Kaifeng as the research subject. Urea urease solution, quicklime, sodium methylsilicate, styrene-acrylic emulsion, waterborne polyurethane, and soil were selected to prepare 27 groups of high-fluidity repair materials with varying proportions. The surface strength, water absorption, surface strength after water absorption, consistency and freeze-thaw cycle tests of crack repair samples were carried out to explore the repair effects of different proportions of repair materials on crack diseases. The results demonstrated that the urease urea solution, along with its mineralization reaction with quicklime and sodium methylsilicate, significantly accelerated the chemical interaction between quicklime and sodium methylsilicate, thereby enhancing the mechanical and waterproofing properties of the repair materials. The group composed of 7.5% quicklime and 7% sodium methylsilicate exhibited a total efficacy coefficient of 96.25, indicating superior mechanical strength and waterproofing performance. Among the tested waterproofing agents—sodium methylsilicate, styrene-acrylic emulsion, and waterborne polyurethane—the effectiveness was ranked as follows: waterborne polyurethane > sodium methylsilicate > styrene-acrylic emulsion. Notably, the group containing 5% sodium methylsilicate combined with 7.5% quicklime achieved the lowest water absorption rate of 3.9%. Thirty cycles of crack-filling experiments revealed that the crack resistance of the filling material surpassed that of the original sample, while maintaining excellent integrity with the earthen structure even after freeze-thaw cycles (Fig 1).

## Linked entities

- **Chemicals:** quicklime (PubChem CID 14778), sodium methylsilicate (PubChem CID 101645476)

## Full-text entities

- **Diseases:** crack (MESH:D003387)
- **Chemicals:** acrylic (-), styrene (MESH:D020058), urea (MESH:D014508), water (MESH:D014867), quicklime (MESH:C016538), polyurethane (MESH:D011140)

## Figures

45 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12558513/full.md

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Source: https://tomesphere.com/paper/PMC12558513