How to turn a volcano into a power station – with a little help from satellites

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Erta Ale in eastern Ethiopia. mbrand85

Ethiopia tends to conjure images of sprawling dusty deserts, bustling streets in Addis Ababa or the precipitous cliffs of the Simien Mountains – possibly with a distance runner bounding along in the background. Yet the country is also one of the most volcanically active on Earth, thanks to Africa’s Great Rift Valley, which runs right through its heart.

Rifting is the geological process that rips tectonic plates apart, roughly at the speed your fingernails grow. In Ethiopia this has enabled magma to force its way to the surface, and there are over 60 known volcanoes. Many have undergone colossal eruptions in the past, leaving behind immense craters that pepper the rift floor. Some volcanoes are still active today. Visit them and you find bubbling mud ponds, hot springs and scores of steaming vents.

Steam rising at Aluto volcano, Ethiopia. William Hutchison

This steam has been used by locals for washing and bathing, but underlying this is a much bigger opportunity. The surface activity suggests extremely hot fluids deep below, perhaps up to 300°C–400°C. Drill down and it should be possible access this high temperature steam, which could drive large turbines and produce huge amounts of power. This matters greatly in a country where 77% of the population has no access to electricity, one of the lowest levels in Africa.

Geothermal power has recently become a serious proposition thanks to geophysical surveys suggesting that some volcanoes could yield a gigawatt of power. That’s the equivalent of several million solar panels or 500 wind turbines from each. The total untapped resource is estimated to be in the region of 10GW.

Converting this energy into power would build on the geothermal pilot project that began some 20 years ago at Aluto volcano in the lakes region 200km south of Addis Ababa. Its infrastructure is currently being upgraded to increase production tenfold, from 7MW to 70MW. In sum, geothermal looks like a fantastic low-carbon renewable solution for Ethiopia that could form the backbone of the power sector and help lift people out of poverty.

 

Scratching the surface

The major problem is that, unlike more developed geothermal economies like Iceland, very little is known about Ethiopia’s volcanoes. In almost all cases, we don’t even know when the last eruption took place – a vital question since erupting volcanoes and large-scale power generation will not make happy bedfellows.

In recent years, the UK’s Natural Environment Research Council (NERC) has been funding RiftVolc, a consortium of British and Ethiopian universities and geological surveys, to address some of these issues. This has focused on understanding the hazards and developing methods for exploring and monitoring the volcanoes so that they can be exploited safely and sustainably.

Teams of scientists have been out in the field for the past three years deploying monitoring equipment and making observations. Yet some of the most important breakthroughs have come through an entirely different route – through researchers analysing satellite images at their desks.

This has produced exciting findings at Aluto. Using a satellite radar technique, we discovered that the volcano’s surface is inflating and deflating. The best analogy is breathing – we found sharp “inhalations” inflating the surface over a few months, followed by gradual “exhalations” which cause slow subsidence over many years. We’re not exactly sure what is causing these ups and downs, but it is good evidence that magma, geothermal waters or gases are moving around in the depths some five km below the surface.

Taking the temperature

In our most recent paper, we used satellite thermal images to probe the emissions of Aluto’s steam vents in more detail. We found that the locations where gases were escaping often coincided with known fault lines and fractures on the volcano.

When we monitored the temperature of these vents over several years, we were surprised to find that most were quite stable. Only a few vents on the eastern margin showed measurable temperature changes. And crucially, this was not happening in synchronicity with Aluto’s ups and downs – we might have expected that surface temperatures would increase following a period of inflation, as hot fluids rise up from the belly of the volcano.

A productive geothermal well on Aluto. William Hutchison

It was only when we delved into the rainfall records that we came up with an explanation: the vents that show variations appear to be changing as a delayed response to rainfall on the higher ground of the rift margin. Our conclusion was that the vents nearer the centre of the volcano were not perturbed by rainfall and thus represent a better sample of the hottest waters in the geothermal reservoir. This obviously makes a difference when it comes to planning where to drill wells and build power stations on the volcano, but there’s a much wider significance.

This is one of the first times anyone has monitored a geothermal resource from space, and it demonstrates what can be achieved. Since the satellite data is freely available, it represents an inexpensive and risk-free way of assessing geothermal potential.

With similar volcanoes scattered across countries like Kenya, Tanzania and Uganda, the technique could allow us to discover and monitor new untapped geothermal resources in the Rift Valley as well as around the world. When you zoom back and look at the big picture, it is amazing what starts to come into view.
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This blog is written by William Hutchison, Research Fellow, University of St Andrews; Juliet Biggs, Reader in Earth Sciences and Cabot Institute member, University of Bristol, and Tamsin Mather, Professor of Earth Sciences, University of Oxford

This article was originally published on The Conversation. Read the original article.
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Juliet Biggs is a member of the University of Bristol Cabot Institute.  She studies Continental Tectonics and Volcanic Deformation and has won numerous awards in her field.  Find out more about Juliet Biggs research.

Power within the rift

Lying just under the Earth’s surface, the East African Rift is a region rich in geothermal resources. Exploitation of this clean and green energy source is steadily been gaining momentum. What is the geological mix that makes the Rift Valley ripe for geothermal power and how is it being tapped?

The East African Rift, stretching from Djibouti to Mozambique, marks the trace of a continent slowly tearing apart. At rates of about 1-2 cm per year, the African continent will one day split into two separated by a new ocean.

When continental rifting occurs, volcanism shortly follows. As the continent steadily stretches apart, the Earth’s crust thins allowing an easier path for buoyant magma to rise up. Where the magma cracks the surface, volcanoes build up. Dotting the Rift Valley are many active, dormant and extinct volcanoes. Famously active ones include Nyiragongo in the Democratic Republic of Congo, Ol Doinyo Lengai in Tanzania and the bubbling lava lake at Erta Ale volcano in Ethiopia.

How to brew a geothermal system

The presence of volcanoes in the Rift Valley indicates one important occurrence –hot rocks under the Earth’s surface. This, combined with a thinned crust due to extension, provides the first geological ingredients for a geothermal system. Active magma chambers are typically extremely warm; consequently they will heat up groundwater in fractures and pores in the surrounding rock up to temperatures of 200-300°C.

Hence, a geothermal field can be defined as a large volume of underground hot water and steam in porous and fractured hot rock. A geothermal system refers to all parts of the hydrological system involved, including the water recharge and the outflow zone of the system. The area of the geothermal field that can be exploited is known as the geothermal reservoir and the hot water typically occupies only 2 to 5% of the rock volume. Nevertheless, if the reservoir is large and hot enough, it can be a source of plentiful energy.

To keep a geothermal system brewing you need three essential components: a subsurface heat source; fluid to transport the heat; and faults, fractures or permeability within sub-surface rocks that allow the heated fluid to flow from the heat source to the surface or near surface.

East African Resources

The presence of geothermal systems in East Africa has not gone unnoticed. At present, geothermal electricity is produced in Kenya and Ethiopia with Djibouti, Eritrea, Rwanda, Zambia, Tanzania and Uganda at the preliminary exploration and test drilling stages. Kenya is steams ahead in terms of development with an installed capacity of 200 MW, but still progress has been slow over the last few decades. In comparison, Ethiopia currently has a 7.3 MW installed capacity with a proposed expansion of 70 MW.  


In Hells Gate National Park, just south of Lake Naivasha, Kenya’s geothermal energy is generated from Olkaria power station. Exploration at Olkaria started in 1955 but it wasn’t until the 1960s when 27 test wells were drilled that extensive exploration kicked off. At present, Olkaria I power station generates 45 MW, Olkaria II produces 65 MW and Olkaria III is a private plant generating 48 MW.  Olkaria IV power plant is under construction, due to be completed in 2014 and has an estimated potential of between 280 and 350 MW. By 2030, Kenya hopes to produce at least 5,000 MW of geothermal power.


Geological and financial risk


Whilst the East African Rift naturally provides the perfect geological conditions in order to meet future energy demands, the risks involved have so far prevented significant development. Geothermal exploration and development is a high-risk investment. Financially, investing in geothermal has high up-front costs followed by relatively low running-costs. If drilling encounters a dry well during exploration, then the financial loses can be substantial, at roughly $3 million of investment for each MW produced, dry wells can cause significant financial set backs, consequently detracting investors.

It’s not just financial risks, there’s geological risk too – they are volcanoes after all. In Kenya, geothermal fields comfortably sit on top of the volcanoes Olkaria, Longonot, Eburru, Paka and Menengai. The picture is similar in Ethiopia where the Alutu Langano power plant is situated within Alutu volcano. In fact, nearly every geothermal prospect site throughout East Africa is located near, or on a volcano.

Whilst many of the volcanoes have not erupted in historical times, recent satellite observations using a technique called InSAR, has revealed that these volcanoes may not be as quiescent as previously thought. Menengai, Alutu, Corbetti and Longonot have all shown periods of ground deformation, both uplift and subsidence. The precise cause of these ground movements is subject to further research with possibilities including the rise or withdrawal magma within the crust or perturbations to the geothermal system. What these observations do mean however is that perhaps accounting for geological risk could be considered in future geothermal development.

Overall, the outlook is bright for East African geothermal resources. The World Bank has a history of supporting and cultivating geothermal in East Africa, for example, since 1978, Kenya has built up its geothermal generation with $300 million in support from the World Bank. The World Bank recently announced their Global Geothermal Development Plan (GGDP), that will “scale up geothermal energy in developing countries” bringing geothermal energy “into the mainstream, and deliver power to millions” – an initiative that will greatly benefit East Africa.

 
This blog has been written by Elspeth Robertson, Earth Sciences, University of Bristol

Read Elspeth’s other blog post ‘Geothermal workshop: Accelerating the impact of research and development in East Africa‘.

 

Elspeth Robertson