geology

Geology and the Autumn Statement

Flo Bullough December 5, 2014

So George Osborne donned the ceremonial red briefcase on wednesday and took to the helm in the House of Commons (rather inconsiderately while I was in Brussels and couldn’t follow the news…) to deliver the Autumn Statement, one of the two statements that the HM Treasury makes each year to Parliament upon publication of economic forecasts (the other being the Budget which is normally announced in March-time).

George Osborne and Danny Alexande make their way to the House of Commons for the Autumn Statement Announcement. Source - Getty UK

George Osborne and Danny Alexander make their way to the House of Commons for the Autumn Statement Announcement. Source – Getty UK

Statements in the run up to wednesday suggested that Science and Engineering were likely to be singled out as the Chancellor’s ‘personal priority. In amongst all this were some announcements which relate directly to geology and in particular, Energy.

1 – North Sea Oil and Gas

The government announced plans to help maximise the economic benefits of the oil and gas resources in the UK Continental Shelf (UKCS). They estimate there is between 11-31 billion barrels still to be exploited and argue that it can provide considerable eonomic benefits to the UK through much sought energy security, high-value jobs and other things. These plans include setting out major reforms to the oil and gas fiscal regime which include a 2% reduction in the rate of the Supplementary Charge from 32-30%.

See 1.124 and 1.125 in the ‘Green Book‘ for more details.

2 – Investment fund for Shale Gas

The UK government has long championed shale gas development as a tool to increase the UK’s energy security, create new jobs and create tax revenue. As part of the government’s ongoing progress in shale gas development, the Autumn Statement detailed a new ‘£5 million fund to provide independent evidence directly to the public about the robustness of the existing regulatory regime’. The reasoning for this is that it will ensure the public is better engaged in the regulatory process.

See section 1.121 in the ‘Green Book‘ for more details.

3 – Funding for sub-surface testing facilities

An interesting inclusion is a £31 million fund for investment into creating so-called ‘sub-surface research test centres’ through the Natural Environment Research Council (NERC). These will be designed to develop world leading knowledge of energy technologies such as shale gas and carbon capture and storage.

See section 1.122 in the ‘Green Book‘ for more details.

4 – Move towards developing the Swansea Bay Tidal Lagoon

As part of the governments commitments to decarbonisation targets they have announced plans for ‘closer discussions’ with the company managing the project at Swansea Bay, Tidal Lagoon Power Ltd to establish whether a tidal lagoon project is affordable and value-for-money for consumers. If this project were to progress it could become the first tidal lagoon project in the world.

For more information on the proposed tidal lagoon project see this story on the BBC News Website and see 1.129 in the ‘Green Book‘.

Swansea Bay where the new Tidal Lagoon would be located. Source – Kakoui, Wikimedia Commons.

5 – Postgraduate Funding

And lastly there was a pretty important note about Postgraduate Taught Masters funding. The geological community has been dismayed at the lack of funding for postgraduate taught masters for sometime in particular becuase many of the Taught Masters Programs (such as Petroleums Geophysics and Hydrogeology) are seen as essential for careers in these areas. The lack of any funding framework for such courses, and the reduction in Industrial funding and scholarships has put real pressure on students wanting to pursue careers in this highly technical area. The government announced in the Autumn Statement that it will introduce a postgraduate loans system offering £10,000 to students under 30 (bit mean!) from 2016-2017. A consultation to inform the design of the scheme is set to follow early next year.

For more information on this announcement see this piece in the Times Higher Education webpage.

What’s geology got to do with it? 4 – Tennis!

Flo Bullough May 30, 2014

As part of the ‘What’s geology got to do with it?’ series, Flo takes us on a tour of the links between geology and tennis! Warning: You may not want to read this if you have no interest in Geology OR tennis….

Now the disclaimer’s out of the way, I thought it was about time I married two of my greatest loves in life, Geology and Tennis. These two interests may seem completely at odds in terms of relevance, but as is the beauty with geology, it relates to just about everything!

So, summer in the northern hemisphere and therefore the two biggest Grand Slams in tennis are upon us! The French Open, the king of the clay-court season is currently underway and Wimbledon, the jewel (and one of the few remaning…) grass court tennis tournaments is just around the corner.

But for a sport containing so few tangible objects: a court, a racket, a person and a tennis ball, how does it relate to Geology? Well….

Tennis Courts

Court Philippe Chatrier Court at the French Open, the only Grand Slam played on red clay. Source – Wikimedia Commons

Professional tennis is played on 3 types of court surface, each with its own season during the tennis calendar. You have the hard court season, which dominates most of the year between July and February, beloved by Djokovic, then you have the European and North and South American clay court season from February to May, favourite of clay-court extroadinaire Rafa Nadal and then the shortest season of all, the grass court season, occupying all of 4 weeks in the summer, from June-July, once dominated by Federer and recently by Murray! The most obvious link to geology here is the clay courts, so how do you go about building a clay court and what materials do you need?

Red Clay Courts

Well first of all, very few clay courts are actually made of natural clay. This is because they can take a very long time to dry out (which you’ll know if you’ve ever done any pottery….). For this reason, the red clay courts as seen at the French Open and numerous other clay court tournaments are actually made from crushed brick or shale. Bricks are used because they absorb water less easily than natural clay and are produced from a mix made from Alumina (clay), sand, lime and iron oxide before being fired until dry.

Guga Kuerten being awarded a cross-section of the court in his last match at the French Open in 2008. Source – Tennis Served Fresh Blog

So if you want to build a clay court like the famous red-clay courts of the French Open, first of all you need to lay a base layer, this is covered with a layer of crushed stones, this is then overlain by a layer of clinker. This is then followed by a layer of crushed limestone and finally, the crushed brick forms the thinnest layer at the top. A cross section of the layering under the court surface formed the trophy that former French Open champion Guga Kuerten received when he played his last match at the tournament in 2008!

800px-Drying_mud_with_120_degree_cracks,_Sicily

You wouldn’t want the Philippe Chatrier court looking like this after a few hours of sunshine! Source – Wikimedia Commons.

Maintenance of the court after completion is a bit tricky as the clay needs to be constantly smoothed and watered in order to prevent dewatering cracks, a feature that many geologists are very familiar with!

Green Clay Courts

800px-Maria_Sharapova,_2008_Family_Circle_Cup

Maria Sharapova playing on the ‘green clay’ at the Family Circle Cup. Source – Wikimedia Commons

Not all tournaments use red clay, so called ‘green’ clay’ or ‘Har-Tru’ has become very popular in the United States. Har-Tru courts are similar in construction but are made from crushed basalt rather than brick meaning they are slightly harder and faster. According to their website, Har-Tru courts are made from ‘billion-year old Pre-Cambrian metabasalt found in the Blue Ridge Mountains of Virginia‘. This rock has two important properties, which is that it is hard and angular which allows it to ‘lock together to form a stable playing surface’ and the hardness provides ‘exceptional durability’.

Tennis rackets

A modern tennis racket with a carbon fiber-reinforced polymer frame. Source – Wikipedia Commons

As with many manufactured items, the raw materials required to make them eventually leads us back to our natural resources in the ground. Earlier tennis rackets were always made from wood, with strings made from gut, but these days, advancements in materials technology means that the majority of professional frames are made from ‘high modulus graphite and/or carbon fibre while titanium and tungsten are often added to give the frame more stiffness and the strings are made from nylon (although Federer and Sampras are famous for using natural gut strings).

Supplies of pure titanium are rare although titanium ores such as ilmenite and rutile are much more common. Titanium is largely mined in the titanium-rich sands of Florida and Virginia as well as Russia, Japan, Kazakhstan and other nations. Much more rare is Tungsten, which has seen a rapid rise in price in recent years as supplies dwindle. Tungsten has recently emerged as a ‘critical’ metal with the majority of the world’s tungsten supply located in China. However Hemerdon mine in Devon which has been closed since 1944, is thought to host one of the largest tungsten and tin deposits in the world, and is set to reopen under control of an Australian firm in the near future with permit plans progressing this year.

For more on how a tennis racket is made: http://www.madehow.com/Volume-3/Tennis-Racket.html

Tennis Balls

Tennis ball advertisment, 19th century. Source – Wikimedia Commons

According to an article in the guardian published in 2013, manufacture of Slazenger tennis balls now has a 50,000 mile production journey before they end up in Centre Court at Wimbledon. Part of this journey includes the transport of various mineral resources. These include the transport of clay from the United States, Petroleum Napthalene (derived from coal tar) from China, Sulphur from South Korea, Magnesium Carbonate from Japan, Silica from Greece and Zinc Oxide from Thailand. This exemplifies not just the truly global nature of the manufacturing markets but also the complex importing and exporting of many natural resources for something as simple as a tennis ball.

For more on how tennis balls are made, see the ITF website: http://www.itftennis.com/technical/balls/other/manufacture.aspx

Tennis Net

Anatomy of a tennis net. Source – Do it tennis website.

The majority of the different parts of a tennis net are made up from either polyester or polyethylene, both formed synthetically. However, the raw materials required to synthesise both materials started off as extracted hydrocarbons. Polyester synthesis requires the polymerisation of ethylene which is derived from petroleum.

60 million tonnes of polyethylene is manufactured each year and is the world’s most important plastic. It is made by several methods by addition polymerisation of ethene, which is principally produced by the cracking of ethane and propane, naptha and gas oil, all hydrocarbon fractions. In Brazil, a plant is being constructed to make polyethylene from sugar cane via bioethanol.

And that’s how geology underpins everything we know and love about tennis!

For more information on the link between sports and geology, see the United States Geological Survey’s article on ‘Minerals in Sports: Tennis’: http://minerals.usgs.gov/minerals/pubs/general_interest/sport_mins/tennis.pdf

The wet with the dry: The geology of Siwa Oasis

Flo Bullough March 10, 2014

Flo takes us on a photoblog-trip to Siwa Oasis in Egypt where epic sand seas meet freshwater springs, saline lakes and sulphurous hot pools!

Siwa Oasis, adapted from Google Earth.

The blog’s going on holiday this week! I spent a week in Egypt on holiday last month and braved the 10 hour overnight bus journey from the capital city Cairo to visit the breathaking beauty of the Siwa Oasis in the Egyptian sand sea of the Libyan desert. I have to say that the shift from big-city Cairo to Siwa via a 10 hour bus drive added a real sense of remoteness when we pulled into the town, bleary-eyed the following morning.

Map of Egypt with the route from Cairo-Siwa, adapted from Google Maps.

I really didn’t know anything about Siwa at all before arriving there apart from noticing the numerous and ubiquitous boxes of Siwan bottled water around Cairo, not an industry I had associated with a small town in the middle of the desert. I’ve always thought of oases as being on a small scale and having a fabled quality and so suffice to say I wasn’t ready for the numerous lakes, springs and hot pools that abound in Siwa.

Siwa is an area of contrasts, the epic sand dunes visible to the west of town are juxtaposed with over a 1000 fizzing natural springs, sulphurous hot pools, and hypersaline lakes. It’s this unique collection of features that brought people to settle here over 12,000 years ago and continues to attract tourists, despite its remote location! And it is certainly bizarre to be in the middle of a desert and find that almost all the things to visit are water related.

History

Aside from the mind boggling landscape and geology, Siwa has an unusual and diverse history. It is one of Egypt’s most isolated settlements, both geographically and culturally with a population predominantly made up of ethnic Siwans who speak Siwi, a distinct language of the Berber family with a smaller proportion of Arabic-speaking Egyptians. Historically, Siwa is famous as the home of the Oracle of Amun and the ruins of this temple can still be visited today.

View of Siwa Landscape from the Temple of Amun – Authors own image.

It was here that Alexander the Great travelled (as well as founding Alexandria), during his campaign to conquer the Persian empire in 332 BC to consult the Oracle of Amun. There it is alleged the Oracle confirmed Alexander the Great as both a divine personage and the legitimate Pharoah of Egypt! The remoteness of the oasis meant that contact with the outside world was rare. The first record of a European visiting since roman times was the English traveler William George Browne who arrived in 1792 to see the ancient temple of the oracle. The oasis wasn’t even officially added to Egypt until 1819 and the first asphalt road to Siwa wasn’t built until the 1980’s! This isolation has served to preserve the delicate environmental and cultural balance of the Oasis. A small town of around ~23,000 people, Siwa’s economy is based on agriculture, largely olives and dates, some tourism and the water bottling plants dotted around the Oasis. But how did all this water come to be here? As with all things, we need to start with the geology!

Regional geology and geography

The area around Siwa is described as a ‘slightly undulating limestone plateau’ of Miocene age as the 1910 geological map of Egypt shows below and the vast areas of the map marked ‘Unexplored’ give you some insight as to how remote and difficult some of this terrain is.

1910 Geological Map of Egypt by the Survey Department of Egypt. Image out of Copyright.

Siwa sits in the Qattara depression which spans the north west of Egypt. Much of the depression sits below sea level: at its deepest it sits at 133m below sea level making it the second lowest point in Africa. It is bounded by steep slopes to the North side and to the south and west it grades into the Great Sand Sea.

Map of Egypt showing the location of the Qattara depression in blue – Source – Eric Gaba, Wikimedia Commons.

The depression is thought to be formed by the processes of salt weathering and wind erosion working together. The intense aelioan weathering causes the salt to crumble the depression floor and then the wind blows away the resulting sands.

Souvenirs made from salt-rock for sale in Siwa. Image Author’s own.

Salt is an issue in Siwa (although it makes for a modest market in selling bottled salt and also salt-rock souvenirs such as lamps). A number of fresh water springs that occur naturally in the Oasis run into salt water lakes making a lot of the water useless. Often even the spring water has an elevated level of salt and so not good for agriculture. This limits agricultural production in the area to mostly hardy crops such as dates and olives.

Just one of the 1000’s of springs in the Siwa area, this is ‘Cleopatra’s Pool’. The spring water here bubbles up from depth at pressure. Image Author’s own.

The main Oasis lakes Birket al-Maraqi and Birket Siwa are saline and no marine life survives. Indeed some of the water is so salty that you can see crystals growing in the water. The salty soil of the oasis continues to be used to build the traditional mudbrick houses which creates a problem. While the salt helps to strengthen the walls of the house, it also melts in the rain. And it doesn’t take much to destroy the houses, in 1928, a major storm resulted in the local inhabitants abandoning their ancient town including the ancient Shali Fort found in the centre of the town. These days new houses are prefabricated to remove the risk of rain melting the building materials!

Shali Fort in the centre of Siwa made from salty mud sourced from the oasis. You can see the damage sustained y the 1928 storm in the collapsing walls. Image Author’s own.

The Wet with the Dry

The Wet

With a mean annual precipitation of 8mm and many rainless years, the vast lakes in the region have something other than the weather to thank for their existence. The wide spanning Qattara depression contains a number of small basins on the floor which hold lakes. It is thought that these lakes were much larger during the Pleistocene Ice Age. It is at the fossil shorelines of these lakes that you can find the bounty of fossils we saw on our trip. These days the levels of the lakes fluctuate seasonally with some lakes drying up completely during the summer seasons.

The numerous springs supply that supply water to the lakes is thought to have been underground for 30,000-50,000 years in the Nubian Sandstone Aquifer System which is considered to be a non-renewable source of water in the North Africa area. It covers parts of Libya, Egypt, Sudan and Chad having a huge storage capacity of ~200,000 bcm of fresh water.

Hot sulphurous springs at Bir Wahed. Image Author’s own.

Whilst the features of Siwa Oasis are broadly natural phenomena there are some other beautiful water-related sites in the area which had a bit of a helping hand in their formation. Around 15km South-West of Siwa you come to the hot and cold springs of Bir Wahed. Both public bathing spots, the first is a sulphurous hot pool where you can relax under the desert sun, and the second is a large cold spring water lake. These two formed when a Russian or American ( depending on who you speak to) oil company came to do some prospective drilling in the 80’s. They didn’t find any oil but they did find water and their activity created the two mini-oases found there today. Now they serve as blissful tourist stops amid the dunes of the Great Sand Sea.

The cold spring lake at Bir Wahed, formed during prospective drilling for oil in the 80’s. Image Author’s own.

The Dry

Sand dunes in the Great Sand Sea. Image Author’s Own.

The Great Sand Sea seen to the West of Siwa Oasis is a 72,000 sq km behemoth of a desert (about the size of Ireland) and is made up predominantly of parallel seif dunes some over 100m high and over 150km long. The area has a rather morbid and adventurous past dating back 2,500 years ago when a 50,000 strong Persian army led by the Persian King Cambyses II is thought to have drowned in the sands of the western Egypt desert during a sandstorm. It was reported in 2012 that the remains of the army may have finally been found and thus solving one of archaeology’s biggest outstanding mysteries. Having spent the afternoon in the dunes, it’s wasn’t hard to see how you could lose your bearings without the aid of modern technology.

Great Sand Sea, Egypt. Image Author’s Own.

The landscape of the areas is mainly shaped by aeolian processes causing deflation hollows (where the force of the wind is concentrated on a particular spot in the landscape), erosion can carve out a pit knowns as a deflation hollow. They can range in size from a few metres to a hundred metres in diameter. Much larger, shallower depressions called pans can also form which cover thousands of square kilomeres. The Qattara depression is one of the largest pans in the world, while Siwa is a smaller pan. The Great Sand Sea wasn’t always a desert and large areas are thought to have been submerged underwater as attested to by the presense of rich fossil-bearing sediments outcropping in the desert. The fossil finds in this area include a whale skeleton, a human footprint, oysters and echinoids up to Miocene in age.

Fossils found exposed in the Great Sand Sea. Imasge Author’s Own.

Finding sea-living fossils in the desert reminded me of just how powerful geological understanding is. Standing looking out over the wind shaped dunes, it’s hard to imagine a thriving shallow sea existing here, but that it did and the deposits and fossils help us to observe and understand past environments, however different they may have been! Water Management

Groundwater Well in Siwa. Image Author’s Own.

Groundwater is the only source of water in Siwa which is used for home use as well as for agriculture and the local economy including the four companies that now bottle water in Siwa. For 1000’s of years the natural system was sustainably preserved but emerging pressures from development, tourism and climate change could put this delicate water system and the ecosystems it supports at risk.

Since the 1960s the Oasis has experienced significant changes in activity patterns which have had an impact on land use and water management. These days in drier parts of the year the Oasis lake is often dry leaving only mud flats behind due to local government irrigation practices siphoning water away from the lake.

The large size of the Qattara depression and the fact that it’s at a very low altitude has led to several proposals to create a massive hydroelectric project in northern Egypt rivalling the Aswan high dam. Interest in this has waned slightly in recent years but future stability in the country could create the climate for development and this would have significant impacts on the Siwa region.

Policy Focus: 1 – Creating value from Waste

Flo Bullough January 10, 2014

Waste and recycling is a growing issue in a world where abundant resources are diminishing. This week Flo Bullough looks at recent policy activity in the area of ‘valuing waste streams’ and the geo-relevant example of Rare Earth Elements.

This week, the House of Lords Science and Technology committee has been taking oral evidence on the topic of ‘Generating value from waste’ with a particular focus on the technology and processes used to

House of Lords Chamber. Source – Wikimedia Commons

salvage raw materials from waste and what the government can do to encourage and assist progress in this area.

This topic was also discussed in a recent European Commission consultation on the Review of European Waste Management Targets and the Raw Material initiative which highlights the importance of recycling to ensure safe access to raw materials. Consultations like these seek to engage with experts in the relevant field and are useful research and fact-finding exercises to inform future government policy.

This is all part of a wider plan to try and incorporate the disposal and cost of waste into the manufacturing life cycle. Additionally, waste is not just a cost burden but can also be a source of valuable materials that can be recycled. In 2009 Friends of the Earth published a report entitled Gone to Waste – The valuable resources that European countries bury and burn. This included data on the value of the waste we don’t recycle and the associated CO2 emissions. The report also attempted to calculate the monetary value of recyclables. They found that in the UK in 2004, the value of materials classified as ‘key recyclables’ that had been disposed of as waste, was a minimum of £651 million (based on values for materials such as glass, paper, iron, steel and biowaste. Rare earth elements were not included in their study).

Landfill Site. Source – Wikimedia Commons.

Geo-Relevant Example – Rare Earth Elements

Internal view of an iPhone. Rare earth elements are used in the manufacture of electronics such as smart phones but when replaced often end up in landfill. Source – Wikimedia Commons

The concept of valuable waste is particularly true of the rare earth elements that end up in waste streams through discarded electronics. Demand for rare earth elements is soaring while scarcity and market cost is increasing. Rare earth elements are essential to many commonplace electronics such as mobile phones and computers as well as in renewable technology such as wind power. The supply of these materials is finite and the market is currently dominated by China (see this excellent post from Geology for Global Development on the issue) which has its own geopolitical implications and so increasing focus from both an environmental and economic perspective is to extract these valuable materials from waste streams.

In terms of current research into Rare Earth Element recycling, Japan is the only place where significant research is being undertaken. An example of this is Hitachi who are aiming to be able to recycle electric motor magnets. It was also announced last year that the US is to build a $120 million ‘Critical Materials’ institute in Iowa which will focus, amongst other things on developing recycling techniques.

For more information see the following links:

Chemistry World – Recycling rare earth elements using ionic liquids

Mining.com – Rare earths recycling on the rise

POST note from the Parliamentary Office of Science and Technology – Rare Earth Elements