Nature's Treasures: Minerals and Gems

Flett Lecture Theatre, Natural History Museum, London

Sunday, 7th December, 10.00 am.

DIRECTIONS

Directions on where to go on Sunday, 7th December were emailed/snail-mailed to all delegates on Thursday 4th December. Due to a number of bounced messages, I am posting them here now.

Entrance will be via the Earth Galleries door on Exhibition Road (nearest London Underground station: South Kensington – follow the signs for “Museums”). Do not go to the main museum entrance on Cromwell Road.

 The event will commence shortly after 10.00 am, as soon as delegates have been able to make their way through the security checks at the entrance (museum security staff will insist on checking all bags).

 On the ground floor, there is a secure cloakroom, where you can leave coats, bags etc. There is a coat-rack in the foyer immediately outside the Flett Theatre, but we cannot guarantee the safety of your belongings if you leave them there. Once inside the museum, go up to the second floor using the stairs, or if necessary the lift (ask security staff for assistance). Entrance to the Flett Theatre is to the left of the stairs (large glass doors). There will be signs to guide you.

 There are bathroom facilities between the first and second floors.

 After a brief registration process, where you will be given a name badge and a copy of the programme, the first of the speakers will commence by no later than 10.15 am.

 A sandwich lunch, followed by coffee, will be served after the talks are finished (at ~1.00 pm) and this will bring us to the exhibition which will run until 3.00 pm.

 Please contact Kevin Murphy (kevin@minersoc.org) if you have any queries. After Friday evening, please text him at +353 (0)86 736 1922, if you have any problems or questions.

This is a one-day meeting, co-organized by Gem-A (the Gemmological Association and Gem-testing Laboratory of Great Britain), the Russell Society and the Mineralogical Society. 

Its aim is to provide a day of short talks which will be of interest to an audience comprising members of all three organizations, and to others who have not previously had an association with any of the organizations mentioned above. Students from schools and universities are welcomed.

ONLINE REGISTRATION HAS NOW CLOSED (THURSDAY, 14.30 PM). If you would still like to register, please contact Kevin Murphy (kevin@minersoc.org).

An exciting line-up of talks is planned, with the following speakers already committed:

Roy Gill, formerly of University of Edinburgh: Minerals and their growth, shapes and colours (abstract)
Jack Ogden, Gem-A: Minerals to gems, and ancient uses (abstract)
Jeff Harris, Glasgow: Smashing diamonds (abstract)
Andy Rankin, Kingston: Fluid and solid inclusions in minerals and gems; guides to their origin (abstract)
Kathryn Goodenough, British Geological Survey, Edinburgh: Mapping and mineral exploration in Africa (abstract)
Karen Hudson-Edwards, Birkbeck College, London: Environmental’ Minerals: Bacteria, Fungi, Worms, Toxins and the Human Body (abstract)
Chris Stanley, Natural History Museum, London: Industrial applications of minerals (abstract)
Bob Symes, Devon: Minerals in the field: where to find them, and how to collect responsibly (abstract)
Brian Jackson, Edinburgh: Agates (abstract)
Adrian Finch, St. Andrews University: Mineral luminescence: the brilliance of imperfections (abstract)

*Provisional title

For further information, please contact Kevin Murphy (kevin@minersoc.org).

Abstracts

Smashing Diamonds
Dr Jeff Harris, Department of Geographical and Earth Sciences, University of Glasgow, Glasgow, G12 8QQ, UK

Marvelling at the beauty of a cut diamond is one thing, but to break a diamond to understand how some parts of the interior of the Earth work is something really special. This talk will show that diamond formation occurs not in isolation, but accompanied by specific mineralogies which may become encapsulated and thereafter protected from further change by a very robust and chemically inert parent. Mineral inclusions in diamonds are usually no more than 100 μm (0.1mm) in longest dimension and have morphologies which have been imposed by the diamond. The mineralogy indicates two principal upper mantle growth environments, referred to as peridotitic (olivine, orthopyroxene, pyrope garnet, diopsidic clinopyroxene and sulphides) and eclogitic (almandine garnet, omphacitic clinopyroxene and sulphides). Diamond formation takes place over a depth range of about 500kms (starting at 150km), so that some diamonds with very specific inclusions which are distinct from those mentioned above, grew in the lower mantle. From the chemistry of the majority of the inclusions and for both principal environments, formation temperatures average 1150⁰C with determined pressures (1σ) ranging from 5.3 ± 0.8 GPa (1GPa ≈ 10km of vertical depth). From radioactive elements in some silicate and sulphide inclusions the genesis ages indicate that no diamond is younger than 990Ma and some are as old as 3600 Ma, which is 80% of the age of the Earth. In this research the broken diamond is very important as it provides information not only about carbon isotopic (δ¹³C) signatures, but also about the levels and aggregation states of nitrogen, diamonds’ commonest molecular impurity. These results can be then linked to the characteristics of the mineralogy of the inclusions. Not a bad scientific return for smashing diamonds.

Fluid and Solid inclusions in Minerals and Gems; guides to their origin
Andrew Rankin, School of Geography, Geology and Environment, Kingston University, Kingston upon Thames, Surrey KT1 2EE

Perfect crystals are unknown in nature. Defects range from the atomic scale to gross imperfections such as depressions and cavities on the macroscopic scale.  Usually, these cavities are sealed over during a period of later growth trapping tiny portions of mineralising fluids (and co-precipitated solids) from the geological past . These fossil droplets provide important information on the physical and chemical conditions prevailing mineral growth from these ancient mineralising fluids.

The presentation will illustrate the splendour and beauty of fluid inclusions and illustrate their usefulness with particular reference to recent research on the origin and authenticity of “ancient” Crystal Skulls and gem rubies.

Mapping and mineral exploration in Africa
Kathryn Goodenough, British Geological Survey, West Mains Road, Edinburgh EH9 3LA

The British Geological Survey may be best known for producing geological maps of the UK, but also has an international reputation for mapping in developing countries. In these areas, geological maps underpin some of the fundamentals needed for development, such as the search for mineral and water resources. In recent years, BGS has worked in a number of countries in Africa, including Madagascar, Mozambique, Ghana, Mauritania and Morocco. Many of these countries are relatively poor, but they have a wealth of mineral resources which could provide a basis for economic development.  

BGS carries out a whole range of work in African countries, in partnership with local geological surveys and universities. Mapping almost always starts with remotely sensed information such as satellite images or aeromagnetic maps. In large-scale mapping projects, where poor exposure and difficult access often make traditional geological mapping very difficult, remotely sensed data provide excellent background information. Bedrock mapping is typically accompanied by stream sediment analysis, indicating hotspots of key minerals such as gold which can then be investigated in more detail. This talk will illustrate some of the work that BGS has been doing in Africa, showing just how ‘nature’s treasures’ can be discovered in some very remote places.

'Environmental’ Minerals: Bacteria, Fungi, Worms, Toxins and the Human Body
Karen Hudson-Edwards, Birkbeck College, University of London

'Environmental’ minerals are exciting because they are the solid expression of the dynamic interaction of water and life at the Earth’s surface. Bacteria, for example, can cause minerals to precipitate within their cell walls, or act as substrates. Fungi can deteriorate building materials, forming secondary minerals as a consequence. Earthworms ingest sediment and excrete clay minerals. Toxic elements can be removed from waters and soils by their incorporation into minerals, and these processes are often helped by organisms. Even human teeth, bones and for some, kidney stones, are examples of environmental biominerals.
 
This talk will illustrate the diversity of ways that environmental minerals form. You will never think of a worm in the same way again!

Industrial applications of Minerals
C.J. Stanley, Department of Mineralogy, Natural History Museum, London

The talk will cover those applications involving what are generally termed industrial minerals and rocks, gemstones and metals, but not fossil fuels. Minerals form the basis of life as we know it; they are integral to our history and our culture. From providing sources of essential elements and vitamins to lending shelter and protection from weather and enemies, from clay for pots to metals for weaponry used in hunting and defence, humankind has needed and utilized minerals for many thousands of years. In the industrial age, producers have had a seemingly unending capacity for creating and developing products of use to man derived from minerals and rocks. Industrial applications for minerals are constantly growing as our technological requirements expand. Everyday objects that the general public takes for granted can contain unexpected metals or mineral derivatives that have been utilized for a specific purpose depending on a specific property. To take a mobile phone as an example, roughly 50% is plastic, 15% glass and ceramics, 15% copper and 20% a cocktail of the following: C, Au, Ag, Ni, Cd, As, Pb, Hg, Mn, Li, Zn, Sb, Be, Bi, In, Nb, Ta, Sn, Co, Pt, Ir, Re, Pd, Rh, Ru, Cr.

Minerals in the field: where to find them, and how to collect responsibly
Bob Symes, formerly of the Natural History Museum, London

The mineralogical sciences have more than kept apace with the use of and application of today's sophisticated analytical techniques, thus providing further understanding of the geochemistry, structure and environments of mineral formation. However, as for the other natural sciences, it is the collection of natural mineral specimens that provides the fundamental starting blocks of study.

Responsible collecting by informed amateur and professional mineralogists continues to advance our science and the understanding of the geological environment. Most major ore-fields have an extensive literature, but smaller pockets of unusual mineralization have perhaps only a single reference or note. Using such literature, geological maps and their interpretation, and to a great extent, local knowledge, interesting and important pockets of mineralization may be discovered and provide new scientific information. Using examples from the British Isles of varied geological environments, this talk will focus on a few areas of mineralization whether they be primary or secondary in origin, which have provided, in past and recent years, a stimulus to scientific mineralogical investigations.

Agates
Brian Jackson, National Scottish Museum

Agates are probably the most common gemstones on Earth.   They have been used to create ornaments for around 7000 years.   The volcanic rocks of Scotland host agates which have been used to create traditional Scottish pebble jewellery.  The formation of agates is of scientific interest.  They are made from silicon dioxide in the form of the mineral quartz but, despite their simple chemistry, the mechanisms that bring about the variety of colours and structures is still not fully understood.

Mineral Luminescence: the Brilliance of Imperfections
Adrian Finch, University of St Andrews, Fife, Scotland

Many minerals emit light (‘luminesce’) when hit by incident energy. For example, shining ultra-violet radiation onto minerals (‘fluorescence’) is widely used by amateur mineralogists as a diagnostic tool and the results are often spectacular. However there are many forms of irradiation, including electrons, x-rays and ions.

Luminescence encodes information about how real minerals differ from idealised perceptions of chemistry and structure. No mineral is truly ‘perfect’ and by varying the irradiation, mineralogists are gaining insights into the types of defects in real minerals. This talk reviews some of the important breakthroughs that have occurred in understanding minerals from luminescence.

Minerals are – quite literally – brilliant.