Amber

Amber is fossilized tree resin (not sap), which has been appreciated for its color and natural beauty since Neolithic times.[2] Amber is used as an ingredient in perfumes, as a healing agent in folk medicine, and as jewelry. There are five classes of amber, defined on the basis of their chemical constituents. Because it originates as a soft, sticky tree resin, amber sometimes contains animal and plant material as inclusions. Amber occurring in coal seams is also called resinite, and the term ambrite is applied to that found specifically within New Zealand coal seams. [3]

Contents

History and etymology

The English word amber derives from the Arabic anbar, via Medieval Latin ambar and Old French ambre. The word originally referred to a precious oil derived from the Sperm whale (now called ambergris). The sense was extended to fossil resin circa 1400, and this became the main sense as the use of ambergris waned.[4] The two substances were confused because they both were found washed up on beaches. Ambergris is less dense than water and floats; whereas amber is less dense than stone, but too dense to float.[5] The word "ambar" was brought to Europe by the Crusaders. In French "ambre gris" was then distinguished from "ambre jaune": ambre gris (gray amber) was ambergris; ambre jaune (yellow amber) was the fossil resin we now call amber.

Amber is discussed by Theophrastus, possibly the first historical mention of the material, in the 4th century BC. The Greek name for amber was ηλεκτρον (electron) and was connected to the Sun God, one of whose titles was Elector or the Awakener.[6] The modern terms "electricity" and "electron" derive from the Greek word for amber and come from William Gilbert's research showing that amber could attract other substances.[7] The word "electron" was coined in 1891 by the Irish physicist George Stoney whilst analyzing elementary charges for the first time.[8][9]

The presence of insects in amber was noticed by Pliny the Elder in his Naturalis Historia, and led him to theorize correctly that, at some point, amber had to be in a liquid state to cover the bodies of insects. Hence he gave it the expressive name of succinum or gum-stone, a name that is still in use today to describe succinic acid as well as succinite, a term given to a particular type of amber by James Dwight Dana (see below under Baltic Amber).

Heating amber will soften it and eventually it will burn, which is why in Germanic languages the word for amber is a literal translation of burn-Stone (nl. barnsteen, de. Bernstein, the latter of which the Polish word bursztyn or the Hungarian borostyán derives from). Heated above 200 °C, amber suffers decomposition, yielding an "oil of amber", and leaving a black residue which is known as "amber colophony", or "amber pitch"; when dissolved in oil of turpentine or in linseed oil this forms "amber varnish" or "amber lac".

Amber from the Baltic Sea has been extensively traded since antiquity and in the main land, from where amber was traded 2000 years ago, the natives called it glaes (referring to its see-through similarity to glass).

The Baltic Lithuanian term for amber is Gintaras and Latvian Dzintars. They and the Slavic jantar or Hungarian gyanta ('resin') are thought to originate from Phoenician jainitar (sea-resin). However, while most Slavic languages, such as Russian and Czech, retain the old Slavic word, in the Polish language, despite still being correct, jantar is used very rarely (even considered archaic) and was replaced by the word bursztyn deriving from the German analogue.

Composition and formation

Amber is heterogeneous in composition, but consists of several resinous bodies more or less soluble in alcohol, ether and chloroform, associated with an insoluble bituminous substance. Amber is a macromolecule by free radical polymerization of several precursors in the labdane family, e.g. communic acid, cummunol, and biformene.[10] These labdanes are diterpenes (C20H32) and trienes, equipping the organic skeleton with three alkene groups for polymerization. As amber matures over the years, more polymerization takes place as well as isomerization reactions, crosslinking and cyclization.

The average composition of amber leads to the general formula C10H16O.

Formation

Molecular polymerization, resulting from high pressures and temperatures produced by overlying sediment, transforms the resin first into copal. Sustained heat and pressure drives off terpenes and results in the formation of amber.[11]

Botanical origin

Fossil resins from Europe fall into two categories, the famous Baltic ambers and another that resembles the Agathis group. Fossil resins from the Americas and Africa are closely related to the modern genus Hymenaea,[12] while Baltic ambers are thought to be fossil resins from Sciadopityaceae family plants that used to live in north Europe.[13]

Inclusions

The abnormal development of resin has been called succinosis. Impurities are quite often present, especially when the resin dropped on to the ground, so that the material may be useless except for varnish-making, whence the impure amber is called firniss. Enclosures of pyrites may give a bluish color to amber. The so-called black amber is only a kind of jet. Bony amber owes its cloudy opacity to minute bubbles in the interior of the resin.

In darkly clouded and even opaque amber, inclusions can be imaged using high-energy, high-contrast, high-resolution X-rays.[14]

Extraction and processing

Distribution and mining

Amber is globally distributed, mainly in rocks of Cretaceous age or younger. Historically, the coast around Königsberg in Prussia was the world's leading source of amber. About 90% of the world's extractable amber is still located in the Kaliningrad Oblast of Russia on the Baltic Sea (which was previously Königsberg in Prussia, before World War II).[15]

Pieces of amber torn from the seafloor are cast up by the waves, and collected by hand, dredging, or diving. Elsewhere, amber is mined, both in open works and underground galleries. Then nodules of blue earth have to be removed and an opaque crust must be cleaned off, which can be done in revolving barrels containing sand and water. Erosion removes this crust from sea-worn amber.

Dominican amber, especially Dominican blue amber, is mined through bell pitting, which is dangerous due to the risk of tunnel collapse.[16]

Treatment

The Vienna amber factories, which use pale amber to manufacture pipes and other smoking tools, turn it on a lathe and polish it with whitening and water or with rotten stone and oil. The final lustre is given by friction with flannel.

When gradually heated in an oil-bath, amber becomes soft and flexible. Two pieces of amber may be united by smearing the surfaces with linseed oil, heating them, and then pressing them together while hot. Cloudy amber may be clarified in an oil-bath, as the oil fills the numerous pores to which the turbidity is due. Small fragments, formerly thrown away or used only for varnish, are now used on a large scale in the formation of "amberoid" or "pressed amber". The pieces are carefully heated with exclusion of air and then compressed into a uniform mass by intense hydraulic pressure; the softened amber being forced through holes in a metal plate. The product is extensively used for the production of cheap jewelry and articles for smoking. This pressed amber yields brilliant interference colors in polarized light. Amber has often been imitated by other resins like copal and kauri, as well as by celluloid and even glass. Baltic amber is sometimes colored artificially, but also called "true amber".

Appearance

Amber occurs in a range of different colors. As well as the usual yellow-orange-brown that is associated with the color "amber", amber itself can range from a whitish color through a pale lemon yellow, to brown and almost black. Other more uncommon colors include red amber (sometimes known as "cherry amber"), green amber, and even blue amber, which is rare and highly sought after.

Much of the most highly-prized amber is transparent, in contrast to the very common cloudy amber and opaque amber. Opaque amber contains numerous minute bubbles. This kind of amber is known as "bony amber".

Although all Dominican amber is fluorescent, the rarest Dominican amber is blue amber. It turns blue in natural sunlight and any other partially or wholly ultraviolet light source. In long-wave UV light it has a very strong reflection, almost white. Only about 100 kg is found per year, which makes it valuable and expensive.[17]

Sometimes amber retains the form of drops and stalactites, just as it exuded from the ducts and receptacles of the injured trees. It is thought that, in addition to exuding onto the surface of the tree, amber resin also originally flowed into hollow cavities or cracks within trees, thereby leading to the development of large lumps of amber of irregular form.

Classification

Amber can be classified into several forms. Most fundamentally, there are two types of plant resin with the potential for fossilization. Terpenoids, produced by conifers and angiosperms, consist of ring structures formed of isoprene (C5H8) units.[2] Phenolic resins are today only produced by angiosperms, and tend to serve functional uses. The extinct medullosans produced a third type of resin, which is often found as amber within their veins.[2] The composition of resins is highly variable; each species produces a unique blend of chemicals which can be identified by the use of pyrolysis–gas chromatography–mass spectrometry.[2] The overall chemical and structural composition is used to divide ambers into five classes.[18][19] There is also a separate classifications of amber gemstones, according to the way of production.

Class I

This class is by far the most abundant. It comprises labdatriene carboxylic acids such as communic or ozic acids.[18] It is further split into three sub-classes. Classes Ia and Ib utilise regular labdanoid diterpenes (e.g. communic acid, communol, biformenes), whilst Ic uses enantio labdanoids (ozic acid, ozol, enantio biformenes).[20]

Ia

Includes Succinite (= 'normal' Baltic amber) and Glessite.[19] Have a communic acid base. They also include much succinic acid.[18]

Baltic amber yields on dry distillation succinic acid, the proportion varying from about 3% to 8%, and being greatest in the pale opaque or bony varieties. The aromatic and irritating fumes emitted by burning amber are mainly due to this acid. Baltic amber is distinguished by its yield of succinic acid, hence the name succinite. Succinite has a hardness between 2 and 3, which is rather greater than that of many other fossil resins. Its specific gravity varies from 1.05 to 1.10.[21] It can be distinguished from other ambers via IR spectroscopy due to a specific carbonyl absorption peak. IR spectroscopy can detect the relative age of an amber sample. Succinic acid may not be an original component of amber, but rather a degradation product of abietic acid.[22]

Ib

Like class Ia ambers, these are based on communic acid; however, they lack succinic acid.[18]

Ic

This class is mainly based on enantio-labdatrienonic acids, such as ozic and zanzibaric acids.[18] Its most familiar representative is Dominican amber.[2]

Dominican amber differentiates itself from Baltic amber by being mostly transparent and often containing a higher number of fossil inclusions. This has enabled the detailed reconstruction of the ecosystem of a long-vanished tropical forest.[23] Resin from the extinct species Hymenaea protera is the source of Dominican amber and probably of most amber found in the tropics. It is not "succinite" but "retinite".[24]

Class II

These ambers are formed from resins with a sesquiterpenoid base, such as cadinene.[18]

Class III

These ambers are polystyrenes.[18]

Class IV

This class is something of a wastebasket; its ambers are not polymerized, but mainly consist of cedrane-based sesquiterpenoids.[18]

Class V

Class V resins are considered to be produced by a pine or pine relative. They comprise a mixture of diterpinoid resins and n-alkyl compounds. Their type mineral is highgate copalite.[19]

Classification of Baltic amber (succinite) gemstones by the International Amber Association

Geological record

The oldest amber recovered dates to the Upper Carboniferous period (320 million years ago).[2][25] Its chemical composition makes it difficult to match the amber to its producers – it is most similar to the resins produced by flowering plants.[26] Amber becomes abundant long afterwards, in the Early Cretaceous, 150 million years ago,[2] when it is found in association with insects. The oldest amber with arthropod inclusions comes from the Middle East from Lebanon and Jordan (Kaddumi, 2007; Azar, 2000). This amber is roughly 125–135 million years old and is considered of high scientific value. In Lebanon more than 450 outcrops of Lower Cretaceous amber have been recovered recently, among which about 20 outcrops have led to intensive biological inclusions comprising the oldest representatives of several recent families of terrestrial arthropods. Jurassic amber has been found recently in Lebanon as well. Many remarkable insects and spiders were recently discovered in the amber of Jordan (Kaddumi, 2007) including the oldest zorapterans, clerid beetles, umenocoleid roaches, and achiliid planthoppers.

Baltic amber or succinite (historically documented as Prussian amber[21]) is found as irregular nodules in marine glauconitic sand, known as blue earth, occurring in the Lower Oligocene strata of Samland in Prussia (Latin: Sambia), in historical sources also referred to as Glaesaria. After 1945 this territory around Königsberg was turned into Kaliningrad Oblast, Russia, where it is now systematically mined.[27] It appears, however, to have been partly derived from yet earlier Tertiary deposits (Eocene); and it occurs also as a derivative phase in later formations, such as glacial drift. Relics of an abundant flora occur as inclusions trapped within the amber while the resin was yet fresh, suggesting relations with the flora of Eastern Asia and the southern part of North America. Heinrich Göppert named the common amber-yielding pine of the Baltic forests Pinites succiniter, but as the wood does not seem to differ from that of the existing genus it has been also called Pinus succinifera. It is improbable, however, that the production of amber was limited to a single species; and indeed a large number of conifers belonging to different genera are represented in the amber-flora.

Paleontological significance

Amber is a unique preservational mode, preserving otherwise unfossilizable parts of organisms; as such it is helpful in the reconstruction of ecosystems and organisms.[28]

The chemical composition of the resin is of limited utility in reconstructing the phylogenetic affinity of the resin producer.[2]

Amber sometimes contains animals or plant matter that became caught in the resin as it was secreted. Insects, spiders and their webs, annelids, frogs,[29] crustaceans, bacteria and amoebae,[30] marine microfossils,[31] wood, flowers and fruit, hair, feathers and other small organisms have been recovered in ambers dating to 130 million years ago.[2]

Use

Amber has been used since antiquity in the manufacture of jewelry and ornaments, and also in folk medicine. Amber also forms the flavoring for akvavit liquor. Amber has been used as an ingredient in perfumes.

Jewelry

Amber has been used since the stone age, from 13,000 years ago.[2] Amber ornaments have been found in Mycenaean tombs and elsewhere across Europe. To this day it is used in the manufacture of smoking and glassblowing mouthpieces.[32][33] Amber's place in culture and tradition lends it a tourism value; Palanga Amber Museum is dedicated to the mineral.

Historic medicinal uses

Amber has long been used in folk medicine for its purported healing properties. Amber and extracts were used from the time of Hippocrates in ancient Greece for a wide variety of treatments through the Middle Ages and up until the early twentieth century.

Scent of amber and amber perfumery

In ancient China it was customary to burn amber during large festivities. If amber is heated under the right conditions, oil of amber is produced, and in past times this was combined carefully with nitric acid to create "artificial musk" – a resin with a peculiar musky odor.[34] Although when burned, amber does give off a characteristic "pinewood" fragrance, modern products, such as perfume, do not normally use actual amber. This is due to the fact that fossilized amber produces very little scent. In perfumery, scents referred to as “amber” are often created and patented[35][36] to emulate the opulent golden warmth of the fossil.[37] The modern name for amber is thought to come from the Arabic word, ambar, meaning ambergris.[8] Ambergris is the waxy aromatic substance created in the intestines of sperm whales and was used in making perfumes both in ancient times as well as modern. The scent of amber was originally derived from emulating the scent of ambergris and/or labdanum but due to the endangered status of the sperm whale the scent of amber is now largely derived from labdanum.[38] The term “amber” is loosely used to describe a scent that is warm, musky, rich and honey-like, and also somewhat oriental and earthy. It can be synthetically created or derived from natural resins. When derived from natural resins it is most often created out of labdanum. Benzoin is usually part of the recipe. Vanilla and cloves are sometimes used to enhance the aroma.

"Amber" perfumes may be created using combinations of labdanum, benzoin resin, copal (itself a type of tree resin used in incense manufacture), vanilla, Dammara resin and/or synthetic materials.[34]

See also

References

  1. ^ Jessamyn Reeves-Brown (November 1997). "Mastering New Materials: Commissioning an Amber Bow, no.65". Strings magazine. http://www.stringsmagazine.com/instruments/Back_Issues/ST65/AmberBow65.html. Retrieved 2007-04-09. 
  2. ^ a b c d e f g h i j Grimaldi, D. (2009). "Pushing Back Amber Production". Science 326 (5949): 51. Bibcode 2009Sci...326...51G. doi:10.1126/science.1179328. PMID 19797645. 
  3. ^ Poinar GO, Poinar R. The quest for life in amber. Basic Books, 1995, ISBN 0201489287, p. 133
  4. ^ Harper, Douglas. "amber". Online Etymology Dictionary. http://www.etymonline.com/index.php?term=amber. 
  5. ^ see: Abu Zaid al Hassan from Siraf & Sulaiman the Merchant (851), Silsilat-al-Tawarikh (travels in Asia).
  6. ^ King, Rev. C.W. (1867). The Natural History of Gems or Decorative Stones. Cambridge (UK). p. 315. http://www.farlang.com/gemstones/king-gems-decorative-stones/page_315. 
  7. ^ Heilbron, J.L. (1979). Electricity in the 17th and 18th Centuries: A Study of Early Modern Physics. University of California Press. p. 169. ISBN 9780520034785. http://books.google.com/?id=UlTLRUn1sy8C&pg=PA169. 
  8. ^ a b Susie Ward Aber. "Welcome to the World of Amber". Emporia State University. http://www.emporia.edu/earthsci/amber/amber.htm. Retrieved 2007-05-11. 
  9. ^ "Origin of word Electron". Patent-invent.com. http://www.patent-invent.com/electricity/inventions/electron.html. Retrieved 2010-07-30. 
  10. ^ Manuel Villanueva-García, Antonio Martínez-Richa, and Juvencio Robles Assignment of vibrational spectra of labdatriene derivatives and ambers: A combined experimental and density functional theoretical study Arkivoc (EJ-1567C) pp. 449–458
  11. ^ Rice, Patty C. (2006). Amber: Golden Gem of the Ages. 4th Ed.. AuthorHouse. ISBN 1-4259-3849-3. 
  12. ^ Lambert, JB; Poinar Jr, GO (2002). "Amber: the organic gemstone.". Accounts of chemical research 35 (8): 628–36. doi:10.1021/ar0001970. PMID 12186567. 
  13. ^ Wolfe, A. P.; Tappert, R., Muehlenbachs, K., Boudreau, M., McKellar, R. C., Basinger, J. F., Garrett, A. (30 June 2009). "A new proposal concerning the botanical origin of Baltic amber". Proceedings of the Royal Society B: Biological Sciences 276 (1672): 3403–3412. doi:10.1098/rspb.2009.0806. PMC 2817186. PMID 19570786. http://rspb.royalsocietypublishing.org/content/276/1672/3403.full. 
  14. ^ Amos, Jonathan (2008-04-01). "BBC News, " Secret 'dino bugs' revealed", 1 April 2008". BBC News. http://news.bbc.co.uk/2/hi/science/nature/7324564.stm. Retrieved 2010-07-30. 
  15. ^ Amber Trade and the Environment in the Kaliningrad Oblast
  16. ^ Wilfred Wichard und Wolfgang Weitschat: Im Bernsteinwald. – Gerstenberg Verlag, Hildesheim, 2004, ISBN 3-8067-2551-9
  17. ^ Manuel A. Iturralde-Vennet (2001). "Geology of the Amber-Bearing Deposits of the Greater Antilles". Caribbean Journal of Science 37 (3): 141–167. http://academic.uprm.edu/publications/cjs/Vol37b/37_141-167.pdf. 
  18. ^ a b c d e f g h Anderson, K; Winans, R; Botto, R (1992). "The nature and fate of natural resins in the geosphere—II. Identification, classification and nomenclature of resinites☆". Organic Geochemistry 18 (6): 829–841. doi:10.1016/0146-6380(92)90051-X. 
  19. ^ a b c Anderson, K; Botto, R (1993). "The nature and fate of natural resins in the geosphere—III. Re-evaluation of the structure and composition of Highgate Copalite and Glessite". Organic Geochemistry 20 (7): 1027. doi:10.1016/0146-6380(93)90111-N. 
  20. ^ Anderson, Ken B. (1996). New Evidence Concerning the Structure, Composition, and Maturation of Class I (Polylabdanoid) Resinites. 617. pp. 105–129. doi:10.1021/bk-1995-0617.ch006. 
  21. ^ a b Chisholm 1911.
  22. ^ "(Rottlaender, 1970)" (PDF). http://www.natmus.dk/cons/reports/2002/amber/amber.pdf. Retrieved 2010-07-30. 
  23. ^ George Poinar, Jr. and Roberta Poinar, 1999. The Amber Forest: A Reconstruction of a Vanished World, (Princeton University Press) ISBN 0-691-02888-5
  24. ^ Grimaldi, D. A.: Amber – Window to the Past. – American Museum of Natural History, New York 1996
  25. ^ Bray, P. S.; Anderson, K. B. (2009). "Identification of Carboniferous (320 Million Years Old) Class Ic Amber". Science 326 (5949): 132–134. Bibcode 2009Sci...326..132B. doi:10.1126/science.1177539. PMID 19797659. 
  26. ^ There are no flowering plant fossils until the Cretaceous, and they were not common until the Upper Cretaceous.
  27. ^ Langenheim, Jean (2003). Plant Resins: Chemistry, Evolution, Ecology, and Ethnobotany. Timber Press Inc.. ISBN 0-88192-574-8. 
  28. ^ BBC – Radio 4 – Amber. Db.bbc.co.uk. Retrieved on 2011-04-23.
  29. ^ "Scientist: Frog could be 25 million years old". MSNBC. 2007-02-16. http://www.msnbc.msn.com/id/17168489/. Retrieved 2010-07-30. 
  30. ^ Benjamin M. Waggoner (July 13, 1996). "Bacteria and protists from Middle Cretaceous amber of Ellsworth County, Kansas". PaleoBios 17 (1): 20–26. http://www.ucmp.berkeley.edu/museum/171online/PB171BMWPG1.html. 
  31. ^ Girard, V.; Schmidt, A.; Saint Martin, S.; Struwe, S.; Perrichot, V.; Saint Martin, J.; Grosheny, D.; Breton, G. et al. (2008). "Evidence for marine microfossils from amber". Proceedings of the National Academy of Sciences of the United States of America 105 (45): 17426–17429. Bibcode 2008PNAS..10517426G. doi:10.1073/pnas.0804980105. PMC 2582268. PMID 18981417. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2582268.  edit
  32. ^ "Interview with expert pipe maker, Baldo Baldi . Accessed 10-12-09". Pipesandtobaccos.com. 2000-02-11. http://www.pipesandtobaccos.com/pipesandtobaccos/info/insights/baldoview.htm. Retrieved 2010-07-30. 
  33. ^ "Maker of amber mouthpiece for glass blowing pipes. Accessed 10-12-09". Steinertindustries.com. 2007-05-07. http://steinertindustries.com/osc/advanced_search_result.php?search_in_description=1&keywords=amber&osCsid=d8f7cf307cfb59b1356aa7e3abfaa59e. Retrieved 2010-07-30. 
  34. ^ a b Amber as an aphrodisiac
  35. ^ Saturated indane derivatives and processes for producing same, Ernst T. Thermer, p. 1 U.S. Patent 3,703,479, U.S. Patent 3,681,464, issue date 1972
  36. ^ Perfume compositions and perfume articles containing one isomer of an octahydrotetramethyl acetonaphthone, John B. Hall, Rumson; James Milton Sanders, Eatontown U.S. Patent 3,929,677, Publication Date: 30 December 1975
  37. ^ Sorcery of Scent: Amber: A perfume myth. Sorceryofscent.blogspot.com (2008-07-30). Retrieved on 2011-04-23.
  38. ^ Gomes, Paula B, Mata, Vera G, Rodrigues, A E (2005). "Characterization of the Portuguese-Grown Cistus ladanifer Essential Oil". Journal of Essential Oil Research. http://teresacasimiro.com.sapo.pt/Bibliographic_References/21.pdf. 
Attribution
  •  This article incorporates text from a publication now in the public domainChisholm, Hugh, ed (1911). "Amber (resin)". Encyclopædia Britannica (11th ed.). Cambridge University Press. 

External links

Forms
Making
People
Processes
Tools
Materials
Precious metal alloys
Mineral gemstones
Organic gemstones
Terms