Water is a critical factor in evaluating and assessing microbial colonization and destruction of Angkor sandstone monuments

Sandstone monuments/temples of the Angkor Empire in the Southeast Asia are important UNESCO World Cultural Heritage of the Khmer Civilization and recorded history for the people today. Majority of these monuments suffer severe deterioration from weathering caused by a combination of physical, chemic...

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Published inInternational biodeterioration & biodegradation Vol. 133; pp. 9 - 16
Main Authors Liu, Xiaobo, Meng, Han, Wang, Yali, Katayama, Yoko, Gu, Ji-Dong
Format Journal Article
LanguageEnglish
Published Barking Elsevier Ltd 01.09.2018
Elsevier BV
Subjects
Angkor temples
Anthropogenic factors
Architecture
Biofilms
Capillary action
Chemical attack
Colonization
Crystallization
Cultural heritage
Cultural resources
Defoliation
Destabilization
Destruction
Deterioration
Drying
Environmental conditions
Evaporation
Human influences
Memorials & monuments
Microorganisms
Mobility
Mosques & temples
Organic chemistry
Plant growth
Salting
Salts
Sandstone
Secondary mineralization
Solutes
Stagnation
Structural integrity
Surface layers
Temples
Water supply
Weathering
Capillary action
Secondary mineralization
Biofilms
Defoliation
Cultural heritage
Sandstone
Angkor temples
Salting
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Abstract Sandstone monuments/temples of the Angkor Empire in the Southeast Asia are important UNESCO World Cultural Heritage of the Khmer Civilization and recorded history for the people today. Majority of these monuments suffer severe deterioration from weathering caused by a combination of physical, chemical and biological forces, including natural and anthropogenic influences. Current knowledge on deterioration of sandstone is not only scattered, but also isolated and restricted by the specialized disciplines/fields of the investigators, resulting in a lack of comprehensive understanding or integrated information on the causes and mechanisms to the damage of these temples/monuments. It is clear that water is the most critical factor, if not the utmost important one over time, affecting the integrity of the sandstone constituents of the overall architecture and also the carvings of bas-relief at many of these temples. Water is important to life and promotes the mobility of solutes, and both microbial and plant growth accelerates the destabilization of the stone structural integrity. Colonization by plants and microbes alters the local environmental conditions allowing dissolution of sandstone and mobility of solutes from and out of the sandstone. When water is not drained effectively from these temples/monuments for an extended period of time, stagnation of water forms a small pool, providing moist and water into sandstone nearby and below for an extended longer period of time. Under evaporation condition, the accumulated solutes in water can be concentrated and also transported into sandstone through initiation of capillary phenomenon to lead to salting effect and attack of the sandstone. Soluble salts in sandstone can be crystallized under further drying conditions to result in defoliation of the outer surface layer from the sandstone structure. With the supply of water, microorganisms can also contribute in a number of ways to the physical and chemical destruction processes involved. Therefore, a holistic approach with water considered must be formulated in investigation of the mechanisms involved and protection measures of Angkor sandstone temples and architecture. •Water availability is a key factor affecting the integrity of sandstone temples in Southeast Asia.•Microbial colonization on surfaces has different effects for protection and destruction at different stage of development.•Solutes and electrolytes are transported into sandstone resulting in defoliation of surface layers.•Both sulfur and ammonia oxidizing microorganisms are active agents contributing to the acid attack of the sandstone.
AbstractList Sandstone monuments/temples of the Angkor Empire in the Southeast Asia are important UNESCO World Cultural Heritage of the Khmer Civilization and recorded history for the people today. Majority of these monuments suffer severe deterioration from weathering caused by a combination of physical, chemical and biological forces, including natural and anthropogenic influences. Current knowledge on deterioration of sandstone is not only scattered, but also isolated and restricted by the specialized disciplines/fields of the investigators, resulting in a lack of comprehensive understanding or integrated information on the causes and mechanisms to the damage of these temples/monuments. It is clear that water is the most critical factor, if not the utmost important one over time, affecting the integrity of the sandstone constituents of the overall architecture and also the carvings of bas-relief at many of these temples. Water is important to life and promotes the mobility of solutes, and both microbial and plant growth accelerates the destabilization of the stone structural integrity. Colonization by plants and microbes alters the local environmental conditions allowing dissolution of sandstone and mobility of solutes from and out of the sandstone. When water is not drained effectively from these temples/monuments for an extended period of time, stagnation of water forms a small pool, providing moist and water into sandstone nearby and below for an extended longer period of time. Under evaporation condition, the accumulated solutes in water can be concentrated and also transported into sandstone through initiation of capillary phenomenon to lead to salting effect and attack of the sandstone. Soluble salts in sandstone can be crystallized under further drying conditions to result in defoliation of the outer surface layer from the sandstone structure. With the supply of water, microorganisms can also contribute in a number of ways to the physical and chemical destruction processes involved. Therefore, a holistic approach with water considered must be formulated in investigation of the mechanisms involved and protection measures of Angkor sandstone temples and architecture. •Water availability is a key factor affecting the integrity of sandstone temples in Southeast Asia.•Microbial colonization on surfaces has different effects for protection and destruction at different stage of development.•Solutes and electrolytes are transported into sandstone resulting in defoliation of surface layers.•Both sulfur and ammonia oxidizing microorganisms are active agents contributing to the acid attack of the sandstone.
Sandstone monuments/temples of the Angkor Empire in the Southeast Asia are important UNESCO World Cultural Heritage of the Khmer Civilization and recorded history for the people today. Majority of these monuments suffer severe deterioration from weathering caused by a combination of physical, chemical and biological forces, including natural and anthropogenic influences. Current knowledge on deterioration of sandstone is not only scattered, but also isolated and restricted by the specialized disciplines/fields of the investigators, resulting in a lack of comprehensive understanding or integrated information on the causes and mechanisms to the damage of these temples/monuments. It is clear that water is the most critical factor, if not the utmost important one over time, affecting the integrity of the sandstone constituents of the overall architecture and also the carvings of bas-relief at many of these temples. Water is important to life and promotes the mobility of solutes, and both microbial and plant growth accelerates the destabilization of the stone structural integrity. Colonization by plants and microbes alters the local environmental conditions allowing dissolution of sandstone and mobility of solutes from and out of the sandstone. When water is not drained effectively from these temples/monuments for an extended period of time, stagnation of water forms a small pool, providing moist and water into sandstone nearby and below for an extended longer period of time. Under evaporation condition, the accumulated solutes in water can be concentrated and also transported into sandstone through initiation of capillary phenomenon to lead to salting effect and attack of the sandstone. Soluble salts in sandstone can be crystallized under further drying conditions to result in defoliation of the outer surface layer from the sandstone structure. With the supply of water, microorganisms can also contribute in a number of ways to the physical and chemical destruction processes involved. Therefore, a holistic approach with water considered must be formulated in investigation of the mechanisms involved and protection measures of Angkor sandstone temples and architecture.
Author Meng, Han
Gu, Ji-Dong
Wang, Yali
Katayama, Yoko
Liu, Xiaobo
Author_xml – sequence: 1
  givenname: Xiaobo
  orcidid: 0000-0002-1865-4403
  surname: Liu
  fullname: Liu, Xiaobo
  organization: School of Biological Sciences, The University of Hong Kong, Pokfulam Road, Hong Kong SAR, PR China
– sequence: 2
  givenname: Han
  surname: Meng
  fullname: Meng, Han
  organization: School of Environment, Nanjing Normal University, No. 1 Wenyuan Road, Nanjing, 210023, PR China
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  givenname: Yali
  surname: Wang
  fullname: Wang, Yali
  organization: Conservation Center, Guangdong museum, 2 Zhujiang East Road, Tianhe District, Guangzhou, PR China
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  givenname: Yoko
  surname: Katayama
  fullname: Katayama, Yoko
  organization: Laboratory of Environmental Microbiology, Tokyo University of Agriculture and Technology, 3-5-8 Saiwai-cho, Fuchu-shi, Tokyo, 183-8509, Japan
– sequence: 5
  givenname: Ji-Dong
  orcidid: 0000-0002-7082-9784
  surname: Gu
  fullname: Gu, Ji-Dong
  email: jdgu@hku.hk, jdgu.ibb@gmail.com
  organization: School of Biological Sciences, The University of Hong Kong, Pokfulam Road, Hong Kong SAR, PR China
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Keywords Capillary action
Secondary mineralization
Biofilms
Defoliation
Cultural heritage
Sandstone
Angkor temples
Salting
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Snippet Sandstone monuments/temples of the Angkor Empire in the Southeast Asia are important UNESCO World Cultural Heritage of the Khmer Civilization and recorded...
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SubjectTerms Angkor temples
Anthropogenic factors
Architecture
Biofilms
Capillary action
Chemical attack
Colonization
Crystallization
Cultural heritage
Cultural resources
Defoliation
Destabilization
Destruction
Deterioration
Drying
Environmental conditions
Evaporation
Human influences
Memorials & monuments
Microorganisms
Mobility
Mosques & temples
Organic chemistry
Plant growth
Salting
Salts
Sandstone
Secondary mineralization
Solutes
Stagnation
Structural integrity
Surface layers
Temples
Water supply
Weathering
Title Water is a critical factor in evaluating and assessing microbial colonization and destruction of Angkor sandstone monuments
URI https://dx.doi.org/10.1016/j.ibiod.2018.05.011
https://www.proquest.com/docview/2124459616
Volume 133
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