Conservation and monitoring of historical architecture: new
Transcription
Conservation and monitoring of historical architecture: new
13/04/2016 Conservation and monitoring of historical architecture: new materials and technologies Prof. Lucia Toniolo Laboratory «Materials and Methods for Cultural Heritage» Department of Chemistry, Materials and Chemical Engineering “Giulio Natta” lucia.toniolo@polimi.it Cultural Heritage threatening: a complex problem The issue of conservation of the architectural heritage is strongly related to air pollution. Information on both the air quality and microclimate are needed to effectively evaluate cultural heritage conservation methods ! Lucia Toniolo – Politecnico di Milano 1 13/04/2016 Heritage Conservation? What does it mean? In Europe 60 YEARS 3 Lucia Toniolo – Politecnico di Milano Heritage Conservation? What does it mean? In Asia 1995 2006 Angkor Wat, Cambodia Lucia Toniolo – Politecnico di Milano 2 13/04/2016 Visual rate of stone decay (da E.M. Winkler “Stone in Architeture” 1994) 5 Lucia Toniolo – Politecnico di Milano Degradation of outdoor exposed stone materials 6 The process of degradation is the adaptation of stone materials to the prevailing environmental condition The process of degradation occurs at the very surface of the building, that is the interface material/environment During XXth cent. the kinetic of the process has been dramatically increased thanks to atmospheric pollution Lucia Toniolo – Politecnico di Milano 3 13/04/2016 7/65 Interaction Material / Environment Architectural Heritage durability material Chemical properties Physical properties environment Mechanical properities Climate Microclimate Air quality & pollution Petrographical properties Lucia Toniolo – Politecnico di Milano Architectural Heritage: Not only ceramics, not only concrete! 8 Metals Iron alloys, steel Copper alloys, bronzes Aluminum Titanium Ceramics Natural Stones, Rocks Lime, Gypsum, Cement Mortars & Concrete Bricks & Terracotta Masonries Organic Materials Wood and Timber Leather Synthetic Polymers Polymeric materials, Plastics Vernishes & Paintings Fibers Composites Lucia Toniolo – Politecnico di Milano 4 13/04/2016 High value Architectural Heritage 1. Milan, the Cathedral 9 2000 m2 10,500 of marble 12 spires 500 sculptures 25 large low-relieves 1961 Lucia Toniolo – Politecnico di Milano The scaffold 2003 10 2005 The scaffold has been built at the end of 2002 The conservation work has been finished at the end of 2009 Lucia Toniolo – Politecnico di Milano 5 13/04/2016 High historical-artistic value Cultural Heritage 2. Certosa di Pavia 11 Lucia Toniolo – Politecnico di Milano High historical-artistic value Cultural Heritage 3. La Collegiata di Castiglione Olona (Varese) 12 1425 Lucia Toniolo – Politecnico di Milano 6 13/04/2016 Fresco painting by Masolino da Panicale 13 1434 Lucia Toniolo – Politecnico di Milano Fresco painting by Masolino da Panicale 14 Lucia Toniolo – Politecnico di Milano 7 13/04/2016 High historical-artistic value Cultural Heritage 4. Torre Velasca, Milan 1958 Architect Studio BBPR 15 Lucia Toniolo – Politecnico di Milano How to face this very difficult situations? 16 4 dramatically important keywords 1. Multi-disciplinarity 2. Knowledge 3. Compatibility 4. Reversibility/Retraetability Project guidelines Lucia Toniolo – Politecnico di Milano 8 13/04/2016 Three Reference Books S. Sigesmund, R. Snethlage Stone in Architecture: Properties, Durability Springer-Verlag 2011 E. Doehne, C.A. Price Stone Conservation: An Overview of Current Research (Readings in Conservation) Getty Conservation Institute, Los Angeles 2010 S. Macdonald and G. Ostergren Conserving Twentieth-Century Built Heritage: A Bibliography Getty Conservation Institute, Los Angeles 2013 17 Lucia Toniolo – Politecnico di Milano Multidisciplinarity for the Conservation project Scientific publication on “conservation treatments” (in english) and case studies presenting the evaluation of treatment performances are only a few !! Book Article, Journal Article, Patent - "Conservation Treatment" as subject - in Architecture and Archaeological conservation - in the period 2000-2014 From AATA online, Getty Conservation Institute, http://aata.getty.edu/Search 18 Lucia Toniolo – Politecnico di Milano 9 13/04/2016 Knowledge & Compatibility Restoration and maintenance for natural stone 1.Cleaning Phases of 2.Surface Consolidation the conservation 3.Adhesion, Sealing work 4.Surface Protection ... what kind of treatment? “There is hardly a polymer which has not been suggested and used for a conservation application” C.V. Horie 1990 Lucia Toniolo – Politecnico di Milano 19 Polymeric materials Polymer Class Vinyl resins Substituted Vinyl resins Acrylic Resins Polyurethanes Epoxy Resins Years Types Apllication 1950 LDPE, PE, PP Stone, Mural Painting, Painting, Paper 1950-60 1930 1970 1970 1950 1975 Silicon Resin Perfluoro polyethers 1980 Fluorurated acrylic resins 1995 20 synthetic gums PVC, PVAC, PS, PEG Lucite 44/45 Paraloid, Elvacite, Plexigum PMMA, PBMA DRI FILM 104, Rhodorsil, Silirain,TEOS, MTMOS, Fomblyn, Akeogard Stone, Paper, Textile, Painting, Wood vernishes Stone, Mural piantings, Paintings, Wood Wood, Stone Stone, Mural paintings, Metals Stone, Bricks, Plaster, Paper, Antigraffiti Stone, Plasters, Antigraffiti Stone Lucia Toniolo – Politecnico di Milano 10 13/04/2016 Ideal surface consolidation treatment 21 requirements Good adhesion to the stone substrate Negligible color alteration Adds no gloss or sheen Improvement of mechanical and microstructural properties Do not produce any harmful by product (salts, VOCs, organic compounds, etc.) Lucia Toniolo – Politecnico di Milano MATERIALS FOR SURFACE CONSOLIDATION Inorganic compounds - Low molecular weight •Lime (Ca (OH)2) and nanolime •Barium hydroxide (Ba(OH)2) •Ammonium oxalate Organic esters of silicic acid •Tetraethyl orthosilicate (TEOS) •Tetramethyl orthosilicate (MTMOS) Organic synthetic polymers •Siloxanes •Acrylic polymers •Fluorinated polymers •Epoxy resins TEOS Lucia Toniolo – Politecnico di Milano 11 13/04/2016 Ideal protection/water-repellent treatment Requirements: Negligible color alteration Adds no gloss or sheen Applies as a waterborne system Water repellent Water vapor permeable Stable under a variety of environmental conditions, including temperature cycling and UV exposure Reversible or retreatable Lucia Toniolo – Politecnico di Milano MATERIALS FOR SURFACE PROTECTION 24 Polymeric materials •Acrylic resins, partially fluorunated acrylic resins •Silicon resins, polysiloxanes •Perfluoropolyethers •Fluorinated elastomers They play the role of water-repellent coating for stones The effectiveness depends on: •Chemical nature •Molecular weight •Glass transition temperature •Filming properties Lucia Toniolo – Politecnico di Milano 12 13/04/2016 Conservation project and intervention 3D Survey-Mapping and sampling preliminary in field inspection Material characterization In field diagnostic investigations Environment characterization In Lab diagnostic analyses Guidelines for conservation Conservation project In field testing of materials and methods executive Conservation and maintenance project Lucia Toniolo – Politecnico di Milano Some experiences in surface consolidation & protection Pavia – S. Michele - 1962 S. Maria delle inorganico Grazie – 1985 consolidamento a basso p.m. consolidamento e protezione con fluosilicati Milano – Duomo facciata – 1972 con materiali organici polimerici Consolidamento e integrazione con materiali organici Milano – Cortile richiniano della Ca’ Granda 1993 polimerici Consolidamento con materiale organico polimerico 26 Lucia Toniolo – Politecnico di Milano 13 13/04/2016 The faҫade of the Milan Cathedral – Conservation work 2002-2009 Lucia Toniolo – Politecnico di Milano Comparison between two well known marbles 28 Certosa di Pavia Carrara marble Candoglia marble Lucia Toniolo – Politecnico di Milano 14 13/04/2016 Cathedral façade, Milan Situation of the marble sculptures in 2003 San Giacomo Minore, Elia Vincenzo Buzzi 1812 Restored in 1972 29 Lucia Toniolo – Politecnico di Milano Surface consolidation carried out in 1972 Cathedral of Milan 30 Lucia Toniolo – Politecnico di Milano 15 13/04/2016 Polished cross-section observed by optical microscopy 31 White vernish layer Titanium dioxide Surface consolidation layer, epoxy resin Marble substrate Polished cross section of a marble fragment Microphoto Lucia Toniolo – Politecnico di Milano Sample observed by Scanning Electron Microscopy White film, Titanium rich 32 Epoxy resin Area interested by microorganisms colonization Lucia Toniolo – Politecnico di Milano 16 13/04/2016 Surface protection carried out in 1972 Presence of yellowish surface film 33 Lucia Toniolo – Politecnico di Milano in sezione trasversale 34 Lucia Toniolo – Politecnico di Milano 17 13/04/2016 in superficie Lucia Toniolo – Politecnico di Milano 35 Nanotechnology in building materials Innovative strategy for surface consolidation and protection Cement and concrete: Nano-SiO2 to increase mechanical properties and durability nano-TiO2 to reduce carbon monoxide and NOx emissions Carbon nanotubes to enhance the strength, to effectively hinder crack propagation Glass: nano-TiO2 to avoid pollutant deposition nano-TiO2 super-hydrophilic Coatings: Addition of nanoparticles (Ag, ZnO,TiO2 ) antimicrobial and self-cleaning surfaces 36 Lucia Toniolo – Politecnico di Milano 18 13/04/2016 TiO2-based materials for the conservation of Architectural Heritage Self-cleaning property De-polluting property Biocidal property • Degradation of gaseous pollutants that can be washed away by rain • Preventive strategy towards stone degradation and biocolonization • Reduction of time and costs for maintenance 37 Lucia Toniolo – Politecnico di Milano TiO2 nanoparticles used in the research Non hydrolytic sol-gel synthesis from TiCl4 and benzyl alcohol at T= 40 °C [1,2] Pure phase anatase Nanoparticles size: 30±10 nm ( in water) Benzyl groups anchored on the titania surface : photo-active not only under UV-light but also under solar light irradiation Highly stable dispersions of NA_TiO2 in aqueous systems, as they do not aggregate and precipitate Commercial P25 nanoparticles 38 [1] Niederberger, M. et al. Chemistry of Materials. 2002, 14 , 4364-4370 [2] Colombo, A., et al. RSC Adv., 2012,2, 6628-6636 Lucia Toniolo – Politecnico di Milano 19 13/04/2016 Set-up of formulations of protective treatments for stone and paint materials of Cultural Heritage, modified by appropriate photocatalytic TiO2 nanoparticles 1. Assessment of the efficacy and durability of the nanocomposite based on poly(2-ethyl-2-oxazoline) as consolidant and protective film for matte painting surface 2. Characterization of nano-TiO2 dispersions and study of their application on natural stones 3. Set-up and study of different hydrophilic SiO2-nano TiO2 treatments for the application on natural stones 4. Set-up and study of different water repellent nanocomposites for the application on natural stones 5. Assessment of the best formulations for the protection of the façade of Monza cathedral 39 Lucia Toniolo – Politecnico di Milano Set-up of SiO2–NA_TiO2 treatments for stone conservation TiO2 TiO2 SiO2 NA_TiO2 Hydrophilic SiO2-NA_TiO2 treatment Application of the consolidant Tetraethyl orthosilicate-TEOS as grafting agent Two commercial TEOS have been selected: - TEOS (A): Estel 1000, 75 wt% in white spirit D40 solvent - TEOS (B): Silres BS OH, about 100 wt%, without solvent 40 Lucia Toniolo – Politecnico di Milano 20 13/04/2016 Materials: Application of NA_TiO2 water dispersions (3%) by brush on Noto stone and thermally aged Carrara marble: Wet stone surface (“wet on wet” technique) 41 After the complete hydrolysis and gelation of the consolidant (four weeks) (“wet on dry” technique) Lucia Toniolo – Politecnico di Milano Evaluation of the aesthetic compatibility: Colorimetry • Every treatment shows high aesthetic compatibility with both lithotypes 42 Lucia Toniolo – Politecnico di Milano 21 13/04/2016 Chemical interactions between TEOS and nano-TiO2: diamond cell micro-FTIR spectroscopy TEOS after 4 weeks of curing SiO2 – nano TiO2 treatment on wet surface (AWet) SiO2 – nano TiO2 treatment on dried surface (ADry) νa Si-O-Si Absorbance ν Si-OH νs Si-O-Si 950 δ O-H 940 δa C-H 1800 1600 1400 νa Si-O-Ti 910 1200 ‐1 1000 800 Wavenumber (cm ) • Formation of the silica gel • Incorporation of TiO2 into the silica network • Modification of silica network in SiO2 – NA_TiO2 treatment on dried surface (ADry) 43 Lucia Toniolo – Politecnico di Milano Evaluation of the morphology of SiO2–NA_TiO2 treatments applied on Carrara marble section treated with Awet: SEM-EDX Ca Si Ti Si and Ti signals in the same regions • Combined SiO2–NA_TiO2 layer where nanoparticles are inserted in the silica network in the “wet on wet” treatments 44 Lucia Toniolo – Politecnico di Milano 22 13/04/2016 Evaluation of the photocatalytic activity Noto stone +85% • Higher values for specimens treated with “wet on wet” SiO2-NA_TiO2 treatments for both lithotypes, compared to those treated only with NA_TiO2 dispersions Carrara marble +200% +165% 45 Lucia Toniolo – Politecnico di Milano Set-up of water repellent TiO2-based nanocomposites for stone conservation Materials Development of water-repellent nanocomposites based on commercial coatings for stone protection: 1. Water dispersion of functionalized perfluoropolyethers (10%), Fluoline PE, CTS srl 2. Water dispersion of organosiloxanes(10%), Silo 112, CTS srl 3. A solution of SiO2 functionalized by silicon alcoxides in isopropyl alcohol (20 % by weight), SIOX-5 S, Siltea srl 46 Lucia Toniolo – Politecnico di Milano 23 13/04/2016 Materials Preparation of the nanocomposites: 1. Blend: Fluoropolymer: 16wt% (F16mix) Polysiloxane: 16, 28 and 44 wt% (S16mix, S28mix, S44mix) Functionalised SiO2 : 16wt% (SO16mix) 2. Layered nanocomposites: a) Application of NA_TiO2 water dispersions (3%) on wet surface a) Application of NA_TiO2 water dispersions (3%) on dry surface TiO2 Polymer 47 Lucia Toniolo – Politecnico di Milano Evaluation of the aesthetic compatibility : Colorimetry Fluoropolyethers Polysiloxanes Functionalised SiO2 ΔΕ* <4 after the application of the treatments Lower ΔΕ* of nanocomposites compared to pristine polymers 48 Lucia Toniolo – Politecnico di Milano 24 13/04/2016 Evaluation of the morphology of the treatments: SEM-EDX Polysiloxanes+ NA_TiO2 blend Polysiloxanes S Ref S44mix Si Ca Si Homogeneous distribution of treatments on the surface of both the pristine polymer (S ref) and the blends (S16mix, S28mix and S44mix) 49 Ti Ca Lucia Toniolo – Politecnico di Milano Evaluation of the morphology of the treatments: AFM Untreated Polysiloxanes Pristine polymer S REF Blend nano TiO2 / polymer (16 wt% pol.) S16mix Blend nano TiO2 / polymer (28 wt% pol.) S28mix Blend nano TiO2 / polymer (44 wt% pol) S44mix 50 Lucia Toniolo – Politecnico di Milano 25 13/04/2016 Evaluation of the morphology of the treatments: AFM Polysiloxanes Fluoropolyethers Functionalised SiO2 Increase of the roughness in nanocomposites (F16mix, S16mix, S28mix and S44mix) compared to pristine polymers (F REF and S REF) Comparable roughness for SO16mix and SO REF 51 Lucia Toniolo – Politecnico di Milano Evaluation of the wettability properties: Static contact angle +28% +50% Higher contact angles by increasing the NPs concentration Functionalised SiO2 For samples treated with functionalised SiO2, the introduction of NPs dcreases the contact angles -43% Polysiloxanes Fluoropolyethers NT S REF 52 F REF S44 mix F16mix SO REF SO16mix Lucia Toniolo – Politecnico di Milano 26 13/04/2016 Evaluation of the photocatalytic activity Polysiloxanes Fluoropolyethers Functionalised SiO2 53 • Polysiloxane-based blends show the highest photoactivity • Increase of the photocathalytic activity with the increase of the NPs concentration Lucia Toniolo – Politecnico di Milano Working areas Selected pilot areas: Exposition • Architectural elements • period of time North South • High relief Nascita di Eva High relief Davide e G Lucia Toniolo – Politecnico di Milano 27 13/04/2016 Monitoring of the Cathedral of Milan Site 5: Upper balcony. H = 32.00 m - colour changes, characterization of the deposit Site 4: Rear Façade (lateral nave roof). H = 30.00 m. Evaluation of protective treatment Site 3: Main balcony. H = 19.70 m - colour changes, characterization of the deposit Site 2: Southern Portal. H = 9.00 m - colour changes, characterization of the deposit Site 1: Road level - colour changes, characterization of the deposit Lucia Toniolo – Politecnico di Milano Site 4: exposition conditions REFERENCE SPECIMENS PROTECTED SPECIMENS South exposition Lucia Toniolo – Politecnico di Milano 28 13/04/2016 Specimen sheltered by rain: particulate matter accumulation 85 SITE 3: Variation of Luminosity L* 82 79 L* 76 9 73 Before exposition 8 6 5 4 3 64 T‐ zero BEFORE EXPOSITION 67 7 b* 70 Variation of b* T‐ zero T1 ‐ 6m expo T2 ‐ 1m expo T1 ‐ 6m expo T2 ‐ 1m expo Lucia Toniolo – Politecnico di Milano Exposed specimen: effects of rain washing out µm 1,2 pre expo set I ‐ 6 mesi 1,0 0,8 Ra 0,6 0,4 0,2 mm 0,0 85 86 UNTREATED 94 95 WITH SILOXANE COATING Lucia Toniolo – Politecnico di Milano 29 13/04/2016 Treatment effectiveness: water repellency pre expo contact angle θ 130 post 6m expo 110 90 70 25 misure/campione 50 94 95 96 BEFORE-EXPOSITION AFTER-EXPOSITION Lucia Toniolo – Politecnico di Milano BEFORE EXPOSITION untreated SEM observations 500x untreated AFTER EXPOSITION treated treated Lucia Toniolo – Politecnico di Milano 30 13/04/2016 BEFORE EXPOSITION untreated SEM observations 1500x untreated AFTER EXPOSITION treated treated Lucia Toniolo – Politecnico di Milano What about reversibility? 62 ….some final remarks Most of the treatments and chemicals used in the conservation yards aren’t reversible, that is they cannot be removed from surfaces after years. Polymeric materials are not very durable, as it is well known for industrial products and coatings. Studies to assess durability of treatments are rare and often carried out on in laboratory not in real cases. Conservation scientists don’t have the magic wand but are aware of limits and advantages of using different materials during intervention Conservation projects of Heritage buildings should benefit from interdisciplinary work. Lucia Toniolo – Politecnico di Milano 31 13/04/2016 MIDAR Materials and Imaging in Arts & Architecture http://midar.chem.polimi.it/ PLEASE VISIT OUR WEBSITE!! 63 Lucia Toniolo – Politecnico di Milano Thank you for your kind attention! Lucia Toniolo – Politecnico di Milano 32