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| title | chunk | source | category | tags | date_saved | instance |
|---|---|---|---|---|---|---|
| Conservation science (cultural property) | 3/4 | https://en.wikipedia.org/wiki/Conservation_science_(cultural_property) | reference | science, encyclopedia | 2026-05-05T06:36:57.638346+00:00 | kb-cron |
=== Water === Water primarily causes physical changes such as warping, stains, discoloration, and other weakening to both inorganic and organic materials. Water can come from natural sources such as flooding, mechanical/technological failures, or human error. Water damage to organic material may lead to the growth of other pests such as mold. In addition to the physical effects of water directly on an object or artwork, moisture in the air directly affects relative humidity which can in turn exacerbate deterioration and damage.
=== Light === Light causes cumulative and irreversible damage to light-sensitive objects. The energy from light interacts with objects at the molecular level and can lead to both physical and chemical damage such as fading, darkening, yellowing, embrittlement, and stiffening. Ultraviolet radiation and Infrared radiation, in addition to visible light, can be emitted from light sources and can also be damaging to material culture. Cultural institutions are tasked with finding the balance between needing light for patrons and guests and exposure to the collection. Any amount of light can be damaging to a variety of objects and artworks and the effects are cumulative and irreversible. Conservation science has helped establish 50 Lux as the benchmark level of light intensity that allows the human eye to operate within the full range the visible light spectrum. While this is a baseline for many museums, adjustments are often needed for based on specific situations. Conservation science has informed the industry on the levels of light sensitivity of common materials used in material culture and the length of time permissible before deterioration is likely to occur. Control strategies must be considered on an item by item basis. Light, ultraviolet, and thermometers for infrared radiation are some of the tools used to detect when levels fall outside of an acceptable range.
=== Lightning === Lightning strikes are the primary natural cause of damage to architectural heritage because ancient buildings generally use timber with high oil content, such as pine. Lightning strikes can cause the timber in the building to catch fire by the heat of the lightning arc. Lightning can also split wood and cause damage to the building structure. The lightning current will generate heat after passing through the timber and generate gas inside, and the impact force formed by the instantaneous expansion of the gas will knock the wood out of damage pits or cracks. Stone decorations on ancient buildings may also suffer physical damage from lightning.
=== Incorrect relative humidity === Relative humidity (RH) is the measure of the humidity, or the water vapor content, in relation to the atmosphere and ranges from damp to dry. Material properties determine the effect that different levels of RH can have on any particular item. Organic materials like wood, paper, and leather, as well as some inorganic material like metals are susceptible to damage from incorrect RH. Damage ranges from physical changes like cracking and warping of organic materials to chemical reactions like corrosion of metals. Temperature has a direct effect on relative humidity: as warm air cools, relative humidity increases and as cool air warms up, relative humidity falls. Dampness can cause the growth of mold which has its own damaging properties. Research in the field has determined the various ranges and fluctuations of incorrect humidity, the sensitivity of various objects to each one, and has helped establish guidelines for proper environmental conditions specific to the objects in question.
=== Incorrect temperature === Material properties directly determine the appropriate temperature needed to preserve that item. Incorrect temperatures, whether too high, too low, or fluctuating between the two, can cause varying levels of deterioration for objects. Temperatures that are too high can lead to chemical and physical damage such as embrittlement, cracking, fading, and disintegration. Too high temperatures can also promote biological reactions like mold growth. Temperatures that are too low can also result in physical damages such as embrittlement and cracking. Temperature fluctuations can cause materials to expand and contract rapidly which causes stress to build up within the material and eventual deterioration over time.
=== Pests === Pests include microorganisms, insects, and rodents and are able to disfigure, damage, and destroy material culture. Both organic material and inorganic material are highly susceptible. Damage can occur from pests consuming, burrowing into, and excreting on material. The presence of pests can be the result of other deterioration mechanisms such as incorrect temperature, incorrect relative humidity, and the presence of water. Fumigation and pesticides may also be damaging to certain materials and requires careful consideration. Conservation science has aided in the development of thermal control methods to eradicate pests.
=== Pollutants === Pollutants consist of a wide range of compounds that can have detrimental chemical reactions with objects. Pollutants can be gases, aerosols, liquids, or solids and are able to reach objects from transference from other objects, dissipation in the air, or intrinsically as part of the object's makeup. They all have the potential to cause adverse reactions with material culture. Conservation science aids in identifying both material and pollutant properties and the types of reactions that will occur. Reactions range from discoloration and stains, to acidification and structural weakening. Dust is one of the most common airborne pollutants and its presence can attract pests as well as alter the object's surface. Research in the field informs conservators on how to properly manage damage that occurs as well as means to monitor and control pollutant levels.