Biological colonization and biodeterioration of architectural ceramic materials: An overview
暂无分享,去创建一个
Maria Filomena Macedo | Ana Z. Miller | M. F. Macedo | M. L. Coutinho | M. Coutinho | A. Miller | Ana Z. Miller | Maria F. Macedo
[1] C. B. Nielsen,et al. Decay of bricks due to salt , 1990 .
[3] Daniela Pinna,et al. Progetto di conservazione programmata di ceramiche del novecento esposte all'aperto nel centro storico di Faenza , 2004 .
[4] S. E. Favero-Longo,et al. Lichens on asbestos-cement roofs: bioweathering and biocovering effects. , 2009, Journal of hazardous materials.
[5] E. Hoffland,et al. Feldspar Tunneling by Fungi along Natural Productivity Gradients , 2003, Ecosystems.
[6] M. Johari,et al. A Review: Durability of Fired Clay Brick Masonry Wall due to Salt Attack , 2009 .
[7] José Dinis Silvestre,et al. Ceramic tiling in building façades: Inspection and pathological characterization using an expert system , 2011 .
[8] J. Ettenauer,et al. Microbes on building materials--evaluation of DNA extraction protocols as common basis for molecular analysis. , 2012, The Science of the total environment.
[9] B. Uher,et al. Epilithic and chasmoendolithic phycoflora of monuments and buildings in South-Eastern Spain , 2005 .
[10] S. Lo,et al. Weathering effects on external wall tiling systems , 2007 .
[11] N. Kleczewski,et al. Fungal Planet description sheets: 128–153 , 2012, Persoonia.
[12] John Warren,et al. Conservation of brick , 1998 .
[13] C. A. Crispim,et al. Cyanobacteria and Biodeterioration of Cultural Heritage: A Review , 2003, Microbial Ecology.
[14] R. Mitchell,et al. Microbial deterioration of historic stone , 2005 .
[15] José Dinis Silvestre,et al. Ceramic tiling inspection system , 2009 .
[16] A. Giakoumaki,et al. Capillary rise kinetics of some building materials. , 2005, Journal of colloid and interface science.
[17] A. Singh,et al. Observations on Lichens Growing on Artifacts in the Indian Subcontinent , 2004 .
[18] Marco Realini,et al. Colour changes of Notos calcareous sandstone as related to its colonisation by microorganisms , 1998 .
[19] D. Rhodes. Clay and Glazes for the Potter , 1957 .
[20] A. Sjöberg,et al. Chemical resistance and cleanability of glazed surfaces , 2005 .
[21] V. Ducman,et al. Low-vacuum SEM analyses of ceramic tiles with emphasis on glaze defects characterisation , 2007 .
[22] M. Figueiredo,et al. Ancient glazed ceramic tiles : a long-term, study from the remediation of environmental impacts to the non-destructive characterization of materials , 2009 .
[23] Cesáreo Sáiz-Jiménez,et al. Factors affecting the weathering and colonization of monuments by phototrophic microorganisms , 1995 .
[24] M. Guiry,et al. THE MARINE AND TERRESTRIAL PRASIOLALES (CHLOROPHYTA) OF GALWAY CITY, IRELAND: A MORPHOLOGICAL AND ECOLOGICAL STUDY , 1999 .
[25] Nuno P. Lopes,et al. Pathology, diagnosis and repair of pitched roofs with ceramic tiles: Statistical characterisation and lessons learned from inspections , 2012 .
[26] Javier García-Guinea,et al. Weathering traces in ancient bricks from historic buildings , 2005 .
[27] M. Olsson,et al. Rock-eating fungi , 1997, Nature.
[28] P. Frey-Klett,et al. Mineral weathering by bacteria: ecology, actors and mechanisms. , 2009, Trends in microbiology.
[29] L. K. Herrera,et al. The importance of atmospheric effects on biodeterioration of cultural heritage constructional materials , 2004 .
[30] A. S. Silva,et al. Decay of historic azulejos in Portugal: an assessment of research needs , 2009 .
[31] M. F. Macedo,et al. Fungal biodeterioration of stained-glass windows , 2014 .
[32] J. Ranogajec,et al. Photocatalytic effects of TiO2 mesoporous coating immobilized on clay roofing tiles , 2014 .
[33] M. A. Rogerio-Candelera,et al. Laboratory-Induced Endolithic Growth in Calcarenites: Biodeteriorating Potential Assessment , 2010, Microbial Ecology.
[34] J. Ranogajec,et al. Evaluation of the effect of lichens on ceramic roofing tiles by scanning electron microscopy and energy-dispersive spectroscopy analyses. , 2006, Scanning.
[35] Katja Sterflinger,et al. Fungi: Their role in deterioration of cultural heritage , 2010 .
[36] Gerard Lynch. The History of Gauged Brickwork , 2010 .
[37] Jie Chen,et al. Weathering of rocks induced by lichen colonization — a review , 2000 .
[38] N. Tennent,et al. The technical examination and conservation of blackened Delftware from anaerobic sites , 1996 .
[39] A. Gorbushina,et al. The role of microorganisms and biofilms in the breakdown and dissolution of quartz and glass , 2005 .
[40] J. Ševc,et al. Airborne and soil microfungi as contaminants of stone in a hypogean cemetery , 2004 .
[41] Christine C. Gaylarde,et al. Biodeterioration of external architectural paint films – A review , 2011 .
[42] Javier R. Viguri,et al. Physico-chemical characterisation of bricks all through the manufacture process in relation to efflorescence salts , 2009 .
[43] B. M. Veeregowda,et al. Biofilms: A survival strategy of bacteria , 2003 .
[44] F. Garcia-Pichel,et al. Phylogenetic and Morphological Diversity of Cyanobacteria in Soil Desert Crusts from the Colorado Plateau , 2001, Applied and Environmental Microbiology.
[45] H. Akbari,et al. Weathering of Roofing Materials-An Overview , 2008 .
[46] Thomas Warscheid,et al. Integrated Concepts for the Protection of Cultural Artifacts Against Biodeterioration , 2000 .
[47] Cesáreo Sáiz-Jiménez,et al. Occurrence of halotolerant/halophilic bacterial communities in deteriorated monuments , 2000 .
[48] R. Kitagawa,et al. Elemental behaviour during the process of corrosion of sekishu glazed roof-tiles affected by Lecidea s.lat. sp. (crustose lichen) , 2006, Clay Minerals.
[49] A. Z. Miller,et al. Biodiversity of cyanobacteria and green algae on monuments in the Mediterranean Basin: an overview. , 2009, Microbiology.
[50] L. Tomaselli,et al. Phototrophic biodeteriogens on lithoid surfaces: An ecological study , 1995, Microbial Ecology.
[51] C. Saiz-Jimenez,et al. Deposition of anthropogenic compounds on monuments and their effect on airborne microorganisms , 1995 .
[52] J. Ranogajec,et al. Microbial Deterioration Of Clay Roofing Tiles , 2007 .
[53] S. B. Surman,et al. CONSIDERATION OF SOME IMPLICATIONS OF THE RESISTANCE OF BIOFILMS TO BIOCIDES , 1998 .
[54] L. Selbmann,et al. Biodeterioration agents dwelling in or on the wall paintings of the Holy Saviour’s cave (Vallerano, Italy) , 2012 .
[55] J. Braams,et al. Biodeterioration of stone: a review , 2000 .
[56] B. Gutarowska,et al. Clone-based comparative sequence analysis of 16S rRNA genes retrieved from biodeteriorating brick buildings of the former Auschwitz II-Birkenau concentration and extermination camp. , 2015, Systematic and applied microbiology.
[57] J. Fierro,et al. Manganese micro-nodules on ancient brick walls. , 2003, The Science of the total environment.
[58] T. Friedl,et al. Molecular diversity of phototrophic biofilms on building stone. , 2013, FEMS microbiology ecology.
[59] A. Z. Miller,et al. Bioreceptivity of building stones: a review. , 2012, The Science of the total environment.
[60] G. Gadd. Metals, minerals and microbes: geomicrobiology and bioremediation. , 2010, Microbiology.
[61] J. Mertz,et al. Algal colonization kinetics on roofing and façade tiles: Influence of physical parameters , 2013 .
[62] Influence of lichen biocorrosion on the quality of ceramic roofing tiles , 2007 .
[63] D. M. Ward,et al. 16S rRNA sequences reveal numerous uncultured microorganisms in a natural community , 1990, Nature.
[64] B. Gutarowska,et al. Application of molecular techniques for the assessment of microorganism diversity on cultural heritage objects. , 2014, Acta biochimica Polonica.
[65] Giovanna Cecchi,et al. Fluorescence lidar technique for the remote sensing of stone monuments , 2000 .
[66] C. Zartman,et al. Bryophytes in a changing landscape: The hierarchical effects of habitat fragmentation on ecological and evolutionary processes , 2007 .
[67] B. Gutarowska,et al. Diversity of an aerial phototrophic coating of historic buildings in the former Auschwitz II-Birkenau concentration camp. , 2014, Science of the Total Environment.
[68] H. Viles,et al. Lichen hotspots: raised rock temperatures beneath Verrucaria nigrescens on limestone , 2004 .
[69] Ronald G. Knapp. China's Old Dwellings , 2001 .
[70] H. Alakomi,et al. Characterization of aerobic bacterial and fungal microbiota on surfaces of historic Scottish monuments. , 2007, Systematic and applied microbiology.
[71] R. A. Kühnel. Cause and consequence: volume changes behind building material deterioration , 2004 .
[72] R. Nys,et al. Attachment point theory revisited: the fouling response to a microtextured matrix , 2008, Biofouling.
[74] C. Saiz-Jimenez,et al. Metabolically active microbial communities of yellow and grey colonizations on the walls of Altamira Cave, Spain , 2008, Journal of applied microbiology.
[75] J. Ranogajec,et al. Chemical corrosion phenomena of roofing tiles , 1997 .
[76] Cesáreo Sáiz-Jiménez,et al. Biodeterioration of building materials by cyanobacteria and algae , 1991 .
[77] Victoria Oakley,et al. Conservation and Restoration of Ceramics , 1993 .
[78] Sune Svanberg,et al. The fluorescence lidar technique for the remote sensing of photoautotrophic biodeteriogens in the outdoor cultural heritage: A decade of in situ experiments , 2009 .
[79] M. Figueiredo,et al. Diagnosis of pathologies in ancient (seventeenth-eighteenth centuries) decorative blue-and-white ceramic tiles: Green stains in the glazes of a panel depicting Lisbon prior to the 1755 earthquake , 2014 .
[80] A. Stinca,et al. Analysis of the biodeteriogenic vascular flora at the Royal Palace of Portici in southern Italy , 2011 .
[81] J. A. Larbi,et al. Microscopy applied to the diagnosis of the deterioration of brick masonry , 2004 .
[82] M. F. Gazulla,et al. Relationship between certain ceramic roofing tile characteristics and biodeterioration , 2011 .
[83] Sergio Pérez-Ortega,et al. Nd-YAG laser irradiation damages to Verrucaria nigrescens , 2013 .
[84] J. Mirão,et al. Hispano-Moresque ceramic tiles from the Monastery of Santa Clara-a-Velha (Coimbra, Portugal) , 2014 .
[85] M. F. Gazulla,et al. A procedure to evaluate the resistance to biological colonization as a characteristic for product quality of ceramic roofing tiles , 2011 .
[86] Geoffrey M Gadd,et al. Geomycology: biogeochemical transformations of rocks, minerals, metals and radionuclides by fungi, bioweathering and bioremediation. , 2007, Mycological research.
[87] W. Lubitz,et al. Monitoring the colonization of monuments by bacteria: cultivation versus molecular methods. , 2003, Environmental microbiology.
[88] F. P. Marín,et al. Influence of freezing test methods, composition and microstructure on frost durability assessment of clay roofing tiles , 2011 .
[89] K. Sterflinger,et al. Microbial deterioration of cultural heritage and works of art — tilting at windmills? , 2013, Applied Microbiology and Biotechnology.
[90] R. Schumann,et al. Influence of material properties and photocatalysis on phototrophic growth in multi-year roof weathering , 2011 .
[91] M. Khanafer,et al. Bias problems in culture-independent analysis of environmental bacterial communities: a representative study on hydrocarbonoclastic bacteria , 2013, SpringerPlus.
[92] Cesáreo Sáiz-Jiménez,et al. Isolation and characterization of epilithic chlorophytes and cyanobacteria from two Spanish cathedrals (Salamanca and Toledo) , 1993 .
[93] C. B. Carter,et al. Ceramic Materials: Science and Engineering , 2013 .
[94] Pier Luigi Nimis,et al. The lichens of Italy: An annotated catalogue , 1993 .
[95] Sikha Mandal,et al. Algal colonization and its ecophysiology on the fine sculptures of terracotta monuments of Bishnupur, West Bengal, India , 2013 .
[96] W. Lubitz,et al. Analysis of fungal communities on historical church window glass by denaturing gradient gel electrophoresis and phylogenetic 18S rDNA sequence analysis. , 2001, Journal of microbiological methods.
[97] D. Bass,et al. Three reasons to re-evaluate fungal diversity 'on Earth and in the ocean' , 2011 .
[98] L. K. Herrera,et al. Understanding microbial inhibition of corrosion. A comprehensive overview , 2009 .
[99] M. Sieracki,et al. The others: our biased perspective of eukaryotic genomes , 2014, Trends in ecology & evolution.
[100] P. Albertano,et al. Polysaccharides as a key step in stone bio-erosion , 2000 .
[101] M. V. van Loosdrecht,et al. On the reproducibility of microcosm experiments - different community composition in parallel phototrophic biofilm microcosms. , 2006, FEMS microbiology ecology.
[102] Wolfgang Sand,et al. Microbial mechanisms of deterioration of inorganic substrates—A general mechanistic overview , 1997 .
[103] Jiří Konta,et al. Clay and man: clay raw materials in the service of man , 1995 .
[104] M. Villegas,et al. Biodeterioration of historic stained glasses from the Cartuja de Miraflores (Spain) , 2006 .
[105] M. Raimondo,et al. Durability of clay roofing tiles: the influence of microstructural and compositional variables , 2009 .
[106] U. Karsten,et al. Fungal and algal biomass in biofilms on artificial surfaces quantified by ergosterol and chlorophyll a as biomarkers , 2007 .
[107] L. Giacomucci,et al. Microbial Deterioration of Artistic Tiles from the Façade of the Grande Albergo Ausonia & Hungaria (Venice, Italy) , 2011, Microbial Ecology.
[108] M. Costa,et al. The mineralogy and chemistry of the German and Portuguese tiles used to face a historic building in the Amazon region and their natural susceptibility to tropical weathering , 2013 .
[109] G. Gadd,et al. Oxalate production by fungi: significance in geomycology, biodeterioration and bioremediation , 2014 .
[110] Michela Monte,et al. Lichens and higher plants on stone: a review , 2003 .
[111] R. Kitagawa,et al. Nanoscale pseudobrookite layer in the surface glaze of a Japanese sekishu roof tile , 2009, Clay Minerals.
[112] K. K. Jain,et al. Essentials in the Care and Conservation of Historical Ceramic Objects , 2007 .
[113] A. Sola,et al. Microstructural and mechanical changes by chemical ageing of glazed ceramic surfaces , 2009 .
[114] Siti Norlizaiha Harun,et al. Preservation of Malay Singgora Roof , 2013 .
[115] M. Figueiredo,et al. Ascertaining the degradation state of ceramic tiles: A preliminary non-destructive step in view of conservation treatments , 2011 .
[116] Masahiro Kato,et al. Abscisic acid-induced rearrangement of intracellular structures associated with freezing and desiccation stress tolerance in the liverwort Marchantia polymorpha. , 2014, Journal of plant physiology.
[117] W. Vyverman,et al. Tolerance of benthic diatoms from temperate aquatic and terrestrial habitats to experimental desiccation and temperature stress , 2010 .
[118] M. Cheng,et al. Chemical and microbial effects of atmospheric particles on the performance of steep-slope roofing materials , 2011 .
[119] C. Dulamsuren,et al. Lichen diversity on steppe slopes in the northern Mongolian mountain taiga and its dependence on microclimate , 2007 .
[120] J. Lorenzo,et al. Microbial communities and alteration processes in monuments at Alcala de Henares, Spain , 1995 .
[121] Piero Tiano,et al. Biodiversity of photosynthetic micro-organisms dwelling on stone monuments , 2000 .
[122] J. Wimpenny,et al. Heterogeneity in biofilms. , 2000, FEMS microbiology reviews.
[123] M. C. Jiménez de Haro,et al. Effect of pollution on polychromed ceramic statues , 1998 .
[124] M. Raimondo,et al. Clays and bodies for ceramic tiles: Reappraisal and technological classification , 2014 .
[125] A. Silva,et al. Multi-analytical identification of pigments and pigment mixtures used in 17th century Portuguese azulejos , 2012 .
[126] S. P. Adhikary,et al. Diversity of Micro-algae and Cyanobacteria on Building Facades and Monuments in India , 2008 .
[127] M. Vendrell-Saz,et al. Decorated ceramic tiles used in Catalan Modernist Architecture (c.1870 to c.1925): Composition, decay and conservation , 2014 .
[128] Marco D’Orazio,et al. Effects of water absorption and surface roughness on the bioreceptivity of ETICS compared to clay bricks , 2014 .
[129] C. Saiz-Jimenez,et al. Lichens and bryophytes as agents of deterioration of building materials in Spanish cathedrals , 1991 .
[130] Vanderley Moacyr John,et al. Fungal and phototroph growth on fiber cement roofs and its influence on solar reflectance in a tropical climate , 2014 .
[131] F. Villani,et al. Heterotrophic microorganisms in deteriorated medieval wall paintings in southern Italian churches. , 2010, Microbiological research.
[132] M. F. Macedo,et al. Microbial communities on deteriorated artistic tiles from Pena National Palace (Sintra, Portugal) , 2013 .
[133] X. Sheng,et al. Characterization of bacterial community inhabiting the surfaces of weathered bricks of Nanjing Ming city walls. , 2011, The Science of the total environment.
[134] A. Gorbushina. Life on the rocks. , 2007, Environmental microbiology.
[135] J. Costerton,et al. Introduction to biofilm. , 1999, International journal of antimicrobial agents.
[136] R. Dreesen,et al. Laboratory chamber studies and petrographical analysis as bioreceptivity assessment tools of building materials , 1995 .
[137] Lesley Durbin,et al. Architectural tiles : conservation and restoration : from the medieval period to the twentieth century , 2005 .
[138] O. Guillitte,et al. Bioreceptivity : a new concept for building ecology studies , 1995 .