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Environmental microscopy in stone conservation
The natural weathering of stone is accelerated by the combined effects of acid rain, salt crystallization, and the freeze‐thaw cycles of water. Since weathering will take place until the system reaches chemical equilibrium, we can mitigate the loss to historic stone monuments and structures by treat...
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| Published in: | Scanning 1996-10, Vol.18 (7), p.508-514 |
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| Main Authors: | , , |
| Format: | Article |
| Language: | English |
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| cited_by | cdi_FETCH-LOGICAL-c3407-d45f1c8c0eccf0a423361bc7cbb4df0ebf8a89f123c9396c1b0cdf6105c7fbc03 |
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| cites | cdi_FETCH-LOGICAL-c3407-d45f1c8c0eccf0a423361bc7cbb4df0ebf8a89f123c9396c1b0cdf6105c7fbc03 |
| container_end_page | 514 |
| container_issue | 7 |
| container_start_page | 508 |
| container_title | Scanning |
| container_volume | 18 |
| creator | Rao, Sudeep M. Brinker, C. Jeffrey Ross, Timothy. J. |
| description | The natural weathering of stone is accelerated by the combined effects of acid rain, salt crystallization, and the freeze‐thaw cycles of water. Since weathering will take place until the system reaches chemical equilibrium, we can mitigate the loss to historic stone monuments and structures by treatments of the stone that retard hydrolysis and impart mechanical strength. While macroscopic studies of stone weathering have been performed addressing the causes, the reactions, and the kinetics involved, the mechanisms of weathering, and the chemical remediation of stone need to be better understood at a microscopic level. Our approach uses environmental scanning electron microscopy where samples can be imaged in their wet, natural state, thus facilitating the in situ study of the weathering processes. The environment in the microscope is set up to simulate the conditions of degradation by introducing corrosive liquids and gases and varying the temperature, pressure, and water content in the environmental chamber of the microscope. In this study, we observed specimens of limestone, treated calcite, and sandstone. We have characterized the morphology, structure, and chemical constituents of the samples for comparison at a later stage when protective coatings will be applied. In situ leaching tests were performed on limestone samples to study the mechanisms of degradation. Granular disintegration due to leaching of the binding material between the grains was seen. We have also observed, in situ, the changes in the structure of sodium sulfate, used in salt crystallization tests, during hydration and dehydration cycles; it changed from that of dense grains to hydrated mesoporous granules with the generation of new surface area. |
| doi_str_mv | 10.1002/sca.1996.4950180707 |
| format | article |
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The environment in the microscope is set up to simulate the conditions of degradation by introducing corrosive liquids and gases and varying the temperature, pressure, and water content in the environmental chamber of the microscope. In this study, we observed specimens of limestone, treated calcite, and sandstone. We have characterized the morphology, structure, and chemical constituents of the samples for comparison at a later stage when protective coatings will be applied. In situ leaching tests were performed on limestone samples to study the mechanisms of degradation. Granular disintegration due to leaching of the binding material between the grains was seen. 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Our approach uses environmental scanning electron microscopy where samples can be imaged in their wet, natural state, thus facilitating the in situ study of the weathering processes. The environment in the microscope is set up to simulate the conditions of degradation by introducing corrosive liquids and gases and varying the temperature, pressure, and water content in the environmental chamber of the microscope. In this study, we observed specimens of limestone, treated calcite, and sandstone. We have characterized the morphology, structure, and chemical constituents of the samples for comparison at a later stage when protective coatings will be applied. In situ leaching tests were performed on limestone samples to study the mechanisms of degradation. Granular disintegration due to leaching of the binding material between the grains was seen. 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We have characterized the morphology, structure, and chemical constituents of the samples for comparison at a later stage when protective coatings will be applied. In situ leaching tests were performed on limestone samples to study the mechanisms of degradation. Granular disintegration due to leaching of the binding material between the grains was seen. We have also observed, in situ, the changes in the structure of sodium sulfate, used in salt crystallization tests, during hydration and dehydration cycles; it changed from that of dense grains to hydrated mesoporous granules with the generation of new surface area.</abstract><cop>New Jersey</cop><pub>Wiley Periodicals, Inc</pub><doi>10.1002/sca.1996.4950180707</doi><tpages>7</tpages></addata></record> |
| fulltext | fulltext |
| identifier | ISSN: 0161-0457 |
| ispartof | Scanning, 1996-10, Vol.18 (7), p.508-514 |
| issn | 0161-0457 1932-8745 |
| language | eng |
| recordid | cdi_crossref_primary_10_1002_sca_1996_4950180707 |
| source | Alma/SFX Local Collection |
| subjects | environmental microscopy stone preservation weathering protection |
| title | Environmental microscopy in stone conservation |
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