Conservation and restoration of ceramic objects

For Additional information on ceramics, see Ceramic.
A museum technician applies acetone to a ceramic piece to remove a previous conservation adhesive of Duco glue. This object is from the collection of the Indiana State Museum
Kylix before and after conservation - restoration.

Conservation and restoration of ceramic objects is a process dedicated to the preservation and protection of objects of historical and personal value made from ceramic. Typically this activity of conservation-restoration is undertaken by a conservator-restorer, especially when dealing with object of cultural heritage. Ceramics are created from a production of coatings of inorganic, nonmetallic materials using heating and cooling to create a glaze. Typically the coatings are permanent and sustainable for utilitarian and decorative purposes.[1] The cleaning, handling, storage, and in general treatment of ceramics is consistent with that of glass because they are made of similar oxygen-rich components such as silicates.[2] In conservation ceramics are broken down into three groups: unfired clay, earthenware or terracotta, and stoneware and porcelain.[3]

Deterioration of ceramics

It is in the nature of all the materials used for construction to eventually degrade and deteriorate. Degradation of an object occurs as a result of the interaction between the environment or with the materials that form the object however, in the case of ceramics, environmental factors are the major cause. There are several ways in which ceramics break down physically and chemically.

Additionally the type of ceramic will affect how it will break down. Unfired clay, like mud and clay adobe, is clay that is fired under 1000 °C or 1832 °F. This type of clay is water-soluble and unstable. Earthenware is clay that has been fired between 1000-1200 °C or 1832°-2192 °F. The firing makes the clay water insoluble but does not allow the formation of an extensive glassy or vitreous within the body. Although water-insoluble, the porous body of earthenware allows water to penetrate. A glaze can be applied that will protect the vessel from water. Due to its porosity, earthenware is susceptible to moisture and creates problems including cracks, breaks and mold growth. Porcelain and stoneware is fired at the highest temperatures between 1200-1400 °C or 2192-2552 °F. Porcelain clay mixtures are fired to create a non-porous and very hard surface.[3]:p.98 However, the materials also create a very brittle surface which increases the potential for chips, cracks and breaks.

Physical degradation

Due to their fragility, damage to ceramics typically comes from mishandling and packing. However, other factors such as vandalism, frost, mold, and other similar occurrences can also inflect harm.[4]

Manufacturing defects

Also known as inherent vice, the intrinsic instability of the fabric and components of an objects can lead to its own physical degradation. This is difficult to prevent because it occurs within the fabric of the material and therefore is a natural occurrence. Deterioration of an object can happen even before the object is used. How the piece is created can instil manufacturing defects in the piece.[2]:p.61 This means that objects can be damaged even before they are used. This would include a body that contains inadequate qualities of (filler (materials)). A second typical defect is from poor design and construction. An example of this would be a ceramic piece with a handle that is too thin to support the weight of the cup. A third manufacturing defect includes careless firing. A ceramic piece that has been fired too rapidly or allowed to dry too fast will crack or break.[4]:p.20

Impact and abrasions

With its delicate nature, ceramics that have been used over a period of time will sustain cracks, nicks, and blemishes. Additionally in a museum environment, damages can occur from packing storing, and handling of objects.[4]:p.22

Frost

Damage can occur when ceramics are exposed to freezing temperatures and frost. The problem occurs when ice crystals form inside of the pores of the ceramic piece. The frost inside of the pores will exert pressure onto the fabric of the pottery and cause the material to crack and break.[4]:p.24

Mold growth

Opposite of frost is heat and humidity. When the humidity is high molds can begin to form on ceramic, particularly ones in which there is no glaze. Spores of molds are found throughout the atmosphere and will attached to any organic residues nearby, such as ceramics. Earthenware ceramics are frequently affected due to their porosity and lack of glaze.[4]:p.25

Chemical degradation

For Additional information on chemical degradation, see Chemical decomposition.

Chemical degradation of objects occurs not in the physical structure of the object but rather in at the chemical or compound level. Compounds begin to breakdown into more simpler compounds and is often an undesired reaction. The degradation of the chemical component of an object will hinder or weaken the stability of the object when exposed to environmental factors such as water, air, pollution, heat, humidity, and the like.

Water

Water can dissolve or deform ceramics that have been low fired, i.e. temperatures around 600 °C. Ceramic fired in high temperatures may also be susceptible to water if their mineral particles are soluble in water, for example Gypsum or calcite. Additionally the different compounds in water can flux and react in different ways to different ceramics. In naturally occurring water, carbon dioxide is dissolved and can create a chemical reaction with minerals in clay bodies that may form calcium bicarbonate which is very soluble. Stagnant water is less damaging because the carbon dioxide is not exhausted.[4]:p.27

Soluble salts

A common degradation issue in ceramics involves soluble salts. Soluble salts can either enter the clay body from the environment, for example from being buried underground for decades, or they are already naturally occurring due to the components of the materials or clay used. Non-archaeological objects, such as modern dishware, can acquire salts from normal use such as storing salt. Soluble salts respond to changes in humidity both high and low. In high humidity salts become soluble and in low humidity they crystallize. The changing from soluble to crystallization and back damages the surface of the ceramic because salt crystals are larger than liquid salt and therefore will shrink and expand the ceramic body. A white haze on the surface is the first indication of soluble salts, which is the salt crystallizing. Overtime the physical component of the body will crumble until it is completely destroyed.[2]:p.61

Preventive care of ceramics

Main article: Collections care

In the realm of conservation there are two distinct practices: non-interventive and active conservation. Non-interventive types of conservation are used to control the surrounding environment such as light, humidity, and temperature. Active conservation is when a conservator practices treatments to alleviate physical problems in the object such as fading, chipping, or breaks.

Display

Although ceramics are utilitarian, some pieces are made to be artwork and therefore displayed. Displaying an object improperly can cause damages either physical or chemically from the environment. One of the most common causes for damages is a ceramic piece falling over or off a shelf. To prevent this issue, many historic houses will line storage and display shelves with a thin layer of ethafoam (polyethylene foam) or bubble wrap.[2]:p.63

Storage

This ceramic ring is housed in a blue board box with an acrylic plastic lid. The ring is laid upon a layer of carved ethafoam to prevent it from shifting during handling.

Ceramics are very delicate in nature and damages can occur even when they are stored away. The most common way in which ceramics become damaged is when they are stacked one inside the other. Unless this is part of the original design, this will typically cause nicks, cracks, or breaks. Some ceramics, depending on their provenance, survive better in different temperature and humidity conditions. Pottery that has been buried, such as from an archaeological site, adheres better to storage at a constant low humidity. Low humidity will help to keep any salts from efflorescing which can mar the surface as well as remove the surface glaze.[5]

In general ceramics are typically inert and are not sensitive to elevated light levels. However, extreme changes in temperature and humidity can cause chemical and physical damage. Typically museums strive to store ceramics, as well as many other material types, in a stable temperature of 68 °F with ± 3°.[2]:p.61 Additionally relative humidity should be stabilized at 50% also with a ±5%. Storing objects near windows, heaters, fireplaces, and exterior walls can create an unstable environment with temperature and humidity fluctuation and increase potential for damages.

Some storing materials can be harmful to ceramic objects. Wool felt attracts and harbors insects including moths and silverfish which can be potentially very harmful to other collection material types. Polyurethane foam deteriorates over time which leaves a by-product that are sticky and acidic.[3]:p.102

Handling

One of the cardinal rules in object handling is to treat every object as if it is fragile and easily breakable. Museum technicians, curators, and conservators are trained to prepare a moving plan before an object is even touched that way minimal damage can occur when handling or moving an object. In the museum field is it a known fact that a vessel, or any object, should be held and handled by its strongest part, such as the base, and with both hands. Areas such as the handle or neck of a vessel tend to be the weakest points and may break if picked up by these components.[5]:p.98

Removal of previous conservation actions

Damages also occur to ceramics from previous restoration. Although the intent was to repair the object for use or display, some dated practices are now known to increase damages either physically, from rivets or staples, or chemically, from old used adhesives that off-gas.[2]:p.61

Removal of surface coating

Overpaint is a technique that is used to cover imperfection on the surface of a ceramic piece. Differences can be seen to the naked eye due to discoloration, being matched poorly, and change in texture or gloss. subtle difference can also been seen by restorers by using lighting and magnification. Overpaint and surface coatings can be removed either mechanically or with the use of solvents.

Mechanical removal of overpaint include physical techniques to remove the coating from the surface. On a glazed surface a sharp needle or scalpel can be used. If mechanical removal is not possible without damaging the surface then solvents can be used instead. The archetype solvents typically used are water, white spirit, industrial methylated spirits (denatured alcohol), acetone, and Dichloromethane which is usually found in the form of a commercial paint stripper. The appropriate solvent works by being applied to the ceramic surface by a cotton wool swab and is rolled on the surface rather than being wiped. Wiping the solvent on the surface will push the paint into the surface rather than lift it off.[4]:p.75–77

Removal of filling materials

Fill materials are used to fill in missing parts or breaks in a ceramic piece in order to stabilize the piece. A wide range of materials and techniques have been used to restore losses in ceramics. Today the most common filling materials are made from calcium-sulphate-based fillers or synthetic resins based on epoxy, acrylic, or polyester resin. These new resins are stronger and do not harm the object. Removing previous filling materials, either mechanically or chemically, and replacing them with new fillers can help keep the piece strong and stable.

Fillers can be removed physically by mechanical ways, depending on the filler material type. Cement mortar can be chiselled away with a hammer and chisel gradually. Plaster is easily removed through mechanical methods such as chiselling and chipping away with sharp implements. Saws, drills, and other mechanical methods can be used to remove the bulk of protruding materials, however scratches, chips, and breaks can occur.[4]:p.77–78

A second option to removing filler material is chemically. Typically, chemical removal is used once the bulk of filler material is left and only a small portion is left.

Unlike adhesives, fills tend to be easier to remove and dismantle from ceramics. Plaster of Paris is one example of a fill that comes apart easily with warm.[6]:p.37

Removal of adhesives

A Minoan ceramic piece from the Archaeological Museum of Herakleion that has gone under restoration

The selection for the proper solvent is based on the identification of the adhesive itself. Every adhesive has a particular solvent that work best to break down its chemical composition. Color, hardness, and other physical properties will allow for identification of the adhesive. The adhesive can be soften once exposed, either in a liquid of vapor form, of the solvent for some time. The length of time depends on the solubility of the adhesive and the thickness of the joint. Porous bodies, low-fired clays, are sometimes pre-soaked in water to prevent the adhesive from being drawn back into the body once it joins with the removal solution. If the adhesive that is being removed is part of the support for the object, then supports, such as tissue paper or propping up the object, will be used to make sure the object does not sustain damages once the adhesive is removed. Sometimes if the adhesive is not softened enough if will remove part of the surface on the ceramic if pressure is applied. The information on solvents for specific adhesives are found below, under each adhesive section.[4]:p.78–79

Cleaning

Removal of surface dirt and deposits is beneficial for the health and longevity of an object because it will prevent the dirt from becoming drawn into the body. Dust and grease may be held on the surface loosely by electrostatic forces or weak chemical bonds and are easily removed. Some deposits, such as calcium salts, can be strongly attached a ceramic surface especially if the surface is unglazed. There are two main methods in which ceramics are cleaned and treated: mechanically and chemically.

Not all ceramic pieces are dry when they need cleaning. Some ceramics, such as those that are excavated archaeologically, will be damp or wet in nature. Conservators tend to remove the surface dirt before the object is completely dry. This is done because it is easier to do before the dirt hardens and because as it dried the dirt may shrink and cause physical damage to the ceramic surface. Some ceramics are kept damp until treatment can be completed.

Mechanical methods

Mechanical methods include dusting, picking and cutting, and abrading. Mechanical cleaning is typically much easier to control than chemical treatments and there is no danger of dirt being drawn into a solution and then absorbed by the ceramic. The danger of mechanical cleaning is the potential for the surface to break or become scratched with a tool. Dusting is used when dirt is not strongly adhered to the surface of the ceramic and is carried out by either a brush or a soft cloth. Large ceramic vessels are cleaned with delicate vacuum cleaner with a soft, muslin-covered head. Picking and cutting is used when there are hardened dirt, encrustations, or old restoration materials closely adheres to the surface. Needles, sharp scalpels, other custom made tools, usually made from wood, and electric vibrotools are used. The dangers with these tools are the increase potential for scratches, gouges, cracking, and breaking of the object due to pressure.

Abrading is the process in which surface deposits are removed using abrasives. Abrasives come in both solid and cream forms. Solid forms of abrasives include glass fiber brush or a rubber burr on a dental drill. Cream forms are usually attached to paper or film. Polishing creams are commonly used to remove thin layers of insoluble surface deposits such calcium. These creams can also remove surface dirt and marks made by tools. The best creams of ceramic do not have oil, grease, or bleach as additives and are used only on glazed ceramics.[4]:p.86–87

Chemical methods

Chemical methods for cleaning ceramics involve water, solvents, acids, and alkalis. Prolonged soaking in water may be used as a conservation method. The goal is to either remove stains from the surface or to remove the soluble salts in the clay body.[6]:p.27

Repair and restoration

The repair and restoration of ceramics has occurred since ceramics were invented including fillings, adhesives, reinforcements, and even patch work. The history of ceramic repair is vast and ranges from different methods and methodologies. For example, in 16th century China, people would repair broken ceramics by using pieces from other objects to disguise the patch. A sixteenth-century manuscript describes the process of patching broken ceramics:

16th century - "Old pieces of porcelain from any famous kiln such as censers lack ears or feet or if vases have damaged mouth rims one can use old bits to patch the old; and if one adds glaze and then bakes it is just the same as the old. But the colour is weak at the patch. Yet people prefer this to the new stuff. And if one uses the method of blowing the glaze on to the patched parts there is still less of a trace".[7]

Today there are new advances in ceramic restoration including consolidation, bonding, adhesives, dowels, rivets, and fillers.

Consolidation

Consolidation is the process in which the fabric of the ceramic is strengthened by introducing a material into the fabric that will bind together. The most common ceramics that need consolidation are excavated pieces because they tend to have lost their bonding fabrics due to leeching or have absorbed soluble salts. A consolidant works in two ways: it either links to the particles in the ceramic chemically or it may form a support system mechanically without reacting with the fabric itself. Chemical consolidants that are used in modern conservation include isocyanates, silanes, siloxnes, and methyl methacrylates, however the consolidants that create a mechanical support system are used more frequently.[4]:p.106

Adhesives

For Additional information on Adhesives, see Adhesive.
Repaired ceramic bowl from the National Museum of Vietnam History

A chemical compound that adheres or bonds items together, such as pieces of ceramic. In ceramic conservation there are several different types that range from natural to man-made adhesives. Conservators characterise the best adhesive as one which can be undone.

Animal glue
For Additional information on Animal Glue, see Animal glue.

Animal glue is an adhesive that contains various animal parts such as bone, skin, or fish and is widely used. It is a soft adhesive and can appear white, but usually has a pale yellow or brown appearance. Animal glue is very soft and can easily be broken down and removed with warm water and steam.[6] Although easily reversible, the relative ease with which the glue breaks down makes it a less strong bonding method.

Shellac
For Additional information on Shellac, see Shellac.

A widely used old adhesive that is orange or very dark brown in appearance. Once dried, the adhesive is very hard and becomes increasingly more brittle over time. Shellac does not break down easily with commercially available products. Additionally, the resin has naturally-occurring dyes that can stain ceramic pink or black. The solvent that works best on this resin is Industrial methylated spirit or (IMA).[6]:p.31 Shellac is prepared by dissolving flakes of shellac in hot alcohol. The properties of shellac make it vulnerable to climatic conditions and inclined to deteriorate over time. Damage can even occur to shellac under the hot light of photography.[8]

Epoxy resin
For Additional information on epoxy Resin, see Epoxy.

This type of resin is typically used post-1930s and is an indication of modern conservation work. Generally epoxy is very hard but unlike shellac is not brittle. The color of epoxy resin can range from yellow/green to a dark yellow/brown. Yellowing of the resin is an indication of aging. Warm to hot water or acetone are known to be the solvents of this adhesive.[6]:p.31

Rubber adhesives
For Additional information on rubber adhesives, see Rubber cement.

Rubber cements are solutions of synthetic or natural rubber products in solvents, with or without resins and gums. Vulcanizers, accelerators, and stabilizers are considered problematic due to the nature of their compounds. One example is the additive of sulfur which is harmful to some types of material, including silver, because it can cause discoloration.[9]:p.99 Rubber adhesives can be confused with epoxy resins due to their similar appearance. However, unlike epoxy resins, rubber adhesives will stretch when pulled. Nitromors or Polystrippa solvent brands are used as a solvent but warm water can also loosen the bond.[6]:p.32

Vinyl acetate polymers
For Additional information on Vinyl acetate polymers, see Vinyl acetate.

Vinyl acetate polymers include polyvinyl acetate, polyvinyl alcohol and polyvinyl acetal; all come from reaction products of vinyl acetate. Some forms of acetates are known to be acidic and will do damage to an object with direct contact. Additionally, polyvinyl acetate mixtures tend to degrade in storage and release acetic acid, which in some cases can corrode lead.[9] This compound's coloring ranges from clear/white to a soft yellow. As it ages, it will change to a deeper yellow. It can have a similar appearance to rubber adhesives but the difference is that PVA turns white when comes into contact with water. Warm water and acetone are typically used as solvents.[6]:p.32

Cellulose nitrate
For Additional information on Cellulose nitrate, see Nitrocellulose.

There are early and modern forms of this adhesive. While both tend to tinge with yellow as they age, the early form tends to become more brittle than the modern version, which contains a plasticizer to make the compound more stable. As with many adhesives, acetone is generally used as a solvent, however IMS can also be used.[6]:p.32

Paraloid B-72
For Additional information on Paraloid B-72, see Paraloid B-72.

B-72 is a thermoplastic resin that was created by Rohm and Haas for use as a surface coating and as a vehicle for Flexographic ink. However B-72 is now being used more as an adhesive specifically for ceramic and glass. One of the major advantages of B-72 as a consolidate is that it is stronger and harder than polyvinyl acetate without being extremely brittle. This adhesive is more flexible than many of the other typically-used adhesives and tolerates stress and strain on a join that most others can not. One major drawback to using B-72 is the difficulty of applying the acrylic resin as an adhesive, as is difficulty in manipulating the substance as a workable agent. The most suitable solvent for B-72 is acetone.[10]

Unlike cellulose nitrate, B-72 does not need additives like plasticizers to stabilize its durability. Fumed colloidal silica is a chemical that can be added to help with the workability of the resin. Additionally research shows that the silica will better distribute stress and strain that occurs during evaporation of the solvent and during the setting of the adhesive film.[10]:p.9

Dowels and rivets

Dowels and rivets are physical ways in which ceramics can be reinforced and strengthen beneath the surface. Dowels are cylindrical rods that consist of wood, metal, or plastic. They are drilled into the ceramic piece and usually are set in the hole with an adhesive that is used to repair the ceramic piece. Removing dowels can be hard because they lie under the surface and are usually hidden. Conservators will cut through dowels with a piercing saw and soften the area with a solvent, like acetone to remove two pieces of ceramic from one another.[6]:p.40

Riveting is a process in which holes are drilled in the surface of the ceramic, but does not go completely through the piece. The rivets are angled toward the joint and provide additional structural support.[4]:p.81 There are two methods to removing rivets: the 'cut' and 'pull'. The 'cut' method consists of cutting the rivets through the middle with a file and then pulled out. The 'pull' method involves placing a thin blade under the rivet and pushing out any plaster packing. This method uses leverage to pull the rivet from the ceramic piece.[6]:p.38

Fillers

Fillers are used to replace gaps and losses from ceramic materials for either aesthetic reasons or for support. There are several different filler materials used in ceramics including plaster of Paris and other commercially available putties and fillers.

Plaster of Paris is a material that consists of calcium sulphate hemihydrate power and is produced by heating gypsum to 120 °C. The chemical formula is as follows: :CaSO4·2H2O + Heat → CaSO4·½H2O + 1½ H2O (released as steam). When mixed with water, an exothermic reaction occurs and forms a hard white filling similar to density of fired ceramics. Different grades of plasters are available and vary based on their particle size, setting time, density, expansion, and color.[4]:p.198

A thermoplastic synthetic wax resin mixture developed by John W Burke and Steve Colton in 1997 can be used to compensate losses in objects from translucent materials such as alabaster, marble, calcite, diorite, and anhydrite. The mixture consists of polyvinyl acetate (PVAC) AYAC, ethylene acrylic acid (EAA) copolymers A-C 540, and 580, antioxidants Irganox 1076 or 1035, dry pigments, marble powder, and other additives which were all melted together. This wax resin is a better substitute to wax-resins because wax collects dust and dirt and make the fill noticeable. Polyester resin and epoxies are toxic and noxious. The wax-resin is fast and easy to use, making it a possible new alternative to fill materials in the conservation field. The wax-resin works best on losses that allow for large contact with the original, primed surface and on losses that are thicker than 1/16in. Shallow losses and small gaps are more difficult due to the ease in which the fill is pulled out.[11]

See also

References

  1. Ceramic Tile and Stone Standards. Ctioa.org. Retrieved on 2012-03-28.
  2. 1 2 3 4 5 6 Little, Margaret (2000). The Winterthur Guide to Caring for Your Collection. Chapter 5: Ceramics and Glass. London: University Press of New England. pp. 57–66. ISBN 0-912724-52-8.
  3. 1 2 3 Craft, Meg (1992). "Decorative Arts" in Caring for Your Collection. New York: Harry N. Abrams, Inc. pp. 97–107. ISBN 0-8109-3174-5.
  4. 1 2 3 4 5 6 7 8 9 10 11 12 13 Buys, Susan (1993). The Conservation and Restoration of Ceramics. Oxford: Butterworth-Heinemann. p. 20. ISBN 0 7506 0957 5.
  5. 1 2 Bachmann, Konstanze (1992). Conservation Concerns: A Guide for Collectors and Curators. Washington, D.C.: Smithonsian Institution Press. ISBN 978-1-56098-174-9.
  6. 1 2 3 4 5 6 7 8 9 10 Williams, Nigel (2002). Porcelain: repair and restoration, a handbook. London: The British Museum Press. ISBN 0 7141 2757 4.
  7. Sayer, G (1951). The Potteries of China. Routledge.
  8. Koob, Stephen (1979). "The Removal of Aged Shellac Adhesive from Ceramics". Studies in Conservation. 24: 134–135. doi:10.1179/sic.1979.015.
  9. 1 2 Hatchfield, Pamela (2002). Pollutants in the Museum Environment: Practical Strategies for Problem Solving in Design, Exhibition and Storage. London: Archetype Publications Ltd. pp. 98–100. ISBN 1-873132-96-4.
  10. 1 2 Koob, Stephen (30 April 1986). "The Use of Paraloid B-72 as an adhesive. Its application for archaeological ceramics and other materials". Studies in Conservation. 31: 7–14. doi:10.1179/sic.1986.31.1.7.
  11. Gansicke, Susanne; Hirx, John (1997). "The Translucent Wax-Resin Fill Material for the Compensation of Losses in Objects". Journal of American Institute for Conservation. 36 (1): 17–29. doi:10.1179/019713697806113648.

External links

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