Introduction 

Amber has a strange fascination for nearly all people who come into contact with it. The process by which it is formed is remarkable. Its geological history and its influence on human history are considerable. 

The earliest known worked pieces of amber were discovered in Southern England near the Cheddar/Creswell crags. The age of these worked beads is between 13,000 and 11,000 years.  

Today amber can still be found washed up on certain beaches or dug from mines and pits. And the jewellery that is made from the raw material is still highly prized and coveted. 

From this it can be seen that the association between humans and amber is both ancient and complex. The two are intertwined to such an extent that they have become inseparable.  

Formation of Amber 

Millions of years ago there were huge forests that covered vast tracks of the earth. Some trees within the forests exuded a resin from their trunks and branches; these were the ancient amber trees. A number of theories have been proposed about why the trees secreted so much resin, amongst them are: 

1. As a defence mechanism against fungal or insect attack.  
The following web site address contains some interesting information relating to this issue: 

http://lib.stat.cmu.edu/DASL/Stories/ResinsRidTermitesfromTrees.html 

3. As an aid to reproduction and the attraction of insect pollinators. 

4. As a reaction to storm or weather damage. 

5. *A process linked to growth. 

*Recent studies conducted in Russia have indicated that the resin may have been discharged more heavily during particular periods of the year and so the resin could well be a bi-product of seasonal growth. (This is true of the Kauri, a species of tree found in New Zealand and which produces enormous amounts of resin which is known as Kauri Gum).

Whatever the purpose the resin would collect in layers on the surface of the trees or fall into pools of hardening resin at the foot of the trees. 

In this particular example of Baltic amber there are more than 42 separate layers of resin present. 

This was only the first stage in the transformation of resin into amber. The process by which amber changes into resin is complex and not fully understood but a number of basic factors are recognised. The fresh resin would need to quickly become buried in the soil or an anaerobic environment (little to no oxygen present) to prevent its oxidisation. Over the many millions of years that followed a slow chemical change would take place that saw the slow evaporation of volatile turpenes present in the matrix of the resin. You can smell the turpenes in fresh resin.  

There was also the polymerisation of the resin molecules, i.e. the joining together of the individual molecules into long stable strands. It is only when this process is complete that the resin can be termed amber. 

In addition to these processes heat and temperature may also be a major contributing factor to the transformational process, but exactly what part they play has yet to be precisely determined. 

Amber can be found which has retained the original shape in which it was formed. One of these forms are stalactites. In these cases fresh resin has dripped from a tree branch and gradually set in a stalactite formation. 

Here is an example of Colombian copal that has formed into a 45cm long rod by dripping down from a branch or tree trunk.  

Amber is most frequently found as rough lumps in mines or pits. There are businesses in many countries where amber is found which extract and work the fossil resin into craft goods, jewellery and resin bi-products such as varnish or shellac. This is particularly true of Russia where the extraction and processing has reached industrial proportions using heavy equipment and machinery. Thousands of tonnes are refined and processed in this way. In the Dominican Republic the digging and extraction is done on a much smaller scale and the processes is predominantly done by hand. The quantities however are still significant. 

In the Baltic region where large quantities of amber are found it is often washed up on the Baltic shore line. In these instances it is usually in the form of rounded pebbles or 'cobbles' and can range in size from tiny grains up to larger pieces 40 cm across at their broadest part. 
 
 

Inclusions in Amber 

When the resin was first formed occasionally animals or plants were trapped or enveloped by the falling resin. The trapped inclusions where preserved with remarkable level of detail. When viewed under a magnifying glass the inclusion appears as though it was trapped only yesterday. The level of preservation extends down to internal organs and in some instances individual cells. 
 

By studying these inclusions it is possible to learn about ecology and environment that existed at the time the resin was laid down. There are many different types of inclusions that can be found in amber these have include: Flies, Spiders, Pseudo Scorpions, Cockroaches, Termites, Leaf-Hoppers, Beetles, Ants, Wasps, Bees - The list goes on and most species are represented in amber collections around the world. 
  The inclusions are typically small (less than 0.5cm) as large insects were able to pull them selves free of the sticky trap, though there are remarkable exceptions.  

Traces of mammals that lived in these ancient woodlands and not very frequent but hair, feathers and even teeth have been found. Very occasionally a lizard will be tapped in amber and when these are discovered they command high prices when brought to the market. 

Andrew Ross of the Natural History Museum in London has published a book that helps the developing amber entomologist identify insect inclusions. The details of this publication are listed in the bibliography section. 
 

Some Major Locations 

Lebanon 

Lebanon has the oldest known source of amber which contains insect 
inclusions. The source of the material is in the Jezzine district and dates 
back more than 120 million years, early Cretaceous, Hauterivian Stage. This 
material has been known to exist for more than 100 hundred years but it is 
only in recent years that systematic and controlled analysis of the material 
has begun. Following spectrographic analysis of this ancient resin indicates 
the tree source as araucarian and this has been substantiated by plant 
remains in the resin which indicate that they may have been Agathis in type.

A remarkable amber dating back to Cretaceous period has been discovered in and around Sayreville, New Jersey, USA. These deposits have produced some remarkably well preserved inclusions that date back to the time of the Dinosaurs. From these deposits fascinating insights are being developed which tell us about the climate and ecosystem which were present at that time. 

One of the oldest known termites trapped in amber has been recovered from these deposits and doubtless other even more remarkable discoveries will be made in due course from this site.

The Baltic amber deposits are the largest in the world. The key deposits are located on or around the Baltic peninsula and can be found in Poland, Germany, Lithuania, Latvia, Estonia, Denmark, Sweden, Holland, the United Kingdom and Belorussia. Hundreds of thousands of tonnes have been extracted over the centuries from these areas. Much of it was processed into lacquer and varnish but a vast amount was turned into jewels and priceless artefacts. Here is a beautiful chess set made from Baltic amber it is on display at the Amber Museum in Southwold, England. Baltic amber is between 25 and 40 million years old.

The island of the Dominican Republic has a remarkable deposit of ancient amber. It is notable for its many inclusions that can be found in the resin. The island has a large-scale low industrial mining industry. Locale people using hand tools and manual labour will dig horizontal pits into the side of amber bearing hills and prominences and dig raw amber for subsequent processing in the villages and towns where a thriving tourists industry thrives for amber jewellery. 

The Dominican Republic deposits have been the centre of much research by such eminent scientists as Dr George Poinar and Dr David Grimaldi both of whom have books currently in print. The details of these publications can be found at the foot of this page. Dominican Republic amber dates back to between. 

Copal is a transitory stage of resin, perhaps half way between resin and amber. South America, Columbia, Santander Province has one of the largest deposits of Copal in the world. Some claim that this resin is more than 10 million years old but at least 8 independent analysis of this source indicate that this particular fossil resin is less than 1000 years old. Substantive evidence to the contrary has yet to emerge. 

• Angola  
• Argentina - Patagonica Formation 
• Australia - South Coast / Victoria 
• Austria - Vienna 
• Brazil - Bahia / Parana 
• Canada - British Columbia / East Coast / Manitoba-Cedar Lake 
• Colombia 
• Congo 
• Dominican Republic 
• France
• Germany - Bitterfield
• Greenland - Hare island
• Hungary
• Israel - Tel-Aviv
• Japan - Kuji / Choshi / Mizunami
• Java
• Kazakhstan - Chimkent
• Kenya
• Lebanon
• Madagascar
• Mexico - Chiapas
• Mozambique 
• New Zealand - Auckland Province / North Island 
• Nigeria 
• Philippines - Luzon 
• Poland - Baltic 
• Romania - Colti - Carpathian Mountains 
• Russia - Baltic / Sakhalin Island / Taimyr 
• Sarawak 
• Sicily 
• Sierra Leone 
• Spain - Alava - Rubielos de Mora - Oviedo 
• Sumatra 
• Sweden - Baltic 
• Switzerland 
• Tanzania  
• UK - Isle of Wight / Hastings / Northumberland / East Anglia / London Clay Formation 
• USA - Arkansas / Alaska / Arizona / Atlantic Coastal Plain / California-Baja/ Carolina / Delaware-St George's / Kansas / Maryland /Massachusetts-Martha's Vineyard / Montana / Nebraska / New Jersey / New York-Kreischerville / South Dakota / Tennessee-Hardin County / Texas / Tennessee / Upper Mississippi Valley / Washington. 
• Zanzibar 

Published books currently available on amber. 

Anderson, K.B. & Crelling, J.C. (Ed.) 1994.- Amber, Resinite, and Fossil Resins. American Chemical Society, ISBN: 0-8412-3336-5.  

Beck, C. & Shennan, S. 1991.- Amber in Prehistoric Britain. Oxbow Books, ISBN: 0-946897-30-1  

Borkent, A. 1995.- Biting Midges in Cretaceous Amber of North America. Backhuys Publishers, ISBN: 90-73348-40-4.  

Fraquet, H. 1987.- Amber. Butterworths, ISBN: 0-0408-03080-1  

Grimaldi, D.A. 1996.- Amber, Window to the Past. Harry N. Abrams, ISBN: 0-8109-1966-6.  

Larsson, S.G. 1978.- Baltic Amber - A Palaeobiological Study. Entomonograph Vol. 1 Klampenborg, Denmark, ISBN: 87-87491-16-8  

Poinar, G.O. Jr. 1992.- Life in Amber. Stanford University Press, ISBN: 0-8047-2001-0  

Poinar, G.O. Jr., 1996.- Discovering the Mysteries of Amber, GEOFIN s,r,l, - Italy, ISBN:  

Poinar, G.O. Jr., 1999.- The Amber Forest - A Reconstruction of a Vanished World; Princeton Univ Press, ISBN: 0-691-02888-5  

Poinar, G.O. Jr. & Poinar, R. 1994.- The Quest for Life in Amber. Addison-Wesley Publishing Company S; ISBN: 0-201-62660-8  

Ross, A. 1998.- Amber - The natural time capsule. Natural History Museum, London. ISBN: 0-565-09131-X.  
 

Interesting Amber Web Links 

• Amber Home: http://www.gplatt.demon.co.uk 
• 3 Dot Studio Amber Project Mark R. Meyer: http://www.3dotstudio.com/amberhome.html 
• AmberWorld: http://www.amberworld.com/amberworld-engl.htm 
• Amber Homepage: http://www.emporia.edu/S/www/earthsci/amber/amber.htm 
• Amber outline, V.Arnold homepage: http://home.t-online.de/home/Arnold-Heide/ebrnstrt.htm#kreide 
• Amber, Insects and Fossils: http://www.kadets.d20.co.edu/~lundberg/amber.html 
• Dead Bug In Amber Club: http://members.tripod.com/~Snakefly/