Is nuclear green?

It may not be surprising to you that printing the question “Is nuclear green?” on two large banners at the Bristol Harbour Festival in July caused a bit of a stir, but this is exactly what Dr Tom Scott (reader in Nuclear Materials and member of the Cabot Institute at the University of Bristol) and his group of volunteers wanted to do.  I joined the group at their stall next to the MShed to listen to their conversations with the public ignited by this thought provoking question.

The volunteers largely comprised of Bristol members of the South West Nuclear Hub (a joint research partnership – which Dr Scott co-directs – with Oxford University), University of Bristol physics undergraduates and some employees of Magnox Ltd a nuclear company in the South West. Together, they rolled out a wide range of activities at their marquee that invited everyone to join in and voice their opinions without judgement.

A live opinion poll with green and red plastic tokens (to vote “yes” and “no” respectively) was placed amongst the crowds along the harbour side to encourage participation and, in general, people were happy to vote publicly. We asked people to explain why they thought that way as they voted: “The sooner that they build Hinkley C the better!” one man announced as he dropped in his green token. (Hinkley C is the name of the new nuclear power station scheduled to be built at Hinkley Point in Somerset.) A red token voter proclaimed “We should go back to coal!” as he dropped his token in. Some members of the public even pretended to scoop up large numbers of tokens to demonstrate the intensity of their view.

Yes/No board to take note of people’s thoughts and feelings about nuclear energy.

The juxtaposition of the words “nuclear” and “green” in the question “Is Nuclear Green?” suggests that there is no straight-forward answer, but yet intense opinions on the matter persist. Nuclear energy, in general, suffers from a negative public opinion and there are three key reasons for this:

  1. the perceived risk of the waste product
  2. the potential for disasters like Chernobyl to happen again
  3. the historical link between nuclear energy and nuclear weapons.

Dr Scott and his volunteers set about to change public opinion on nuclear energy by presenting the facts on their activities in a neutral light, such that the public would feel free to make up their own minds.

One of the activities at the stall, popular with children, had a Scalextric set (a slot car racing set) connected to a pedal generator – demonstrating how much human power was required to drive the toy cars. Further inside the marquee, you’d see a bucket of coal, 16kg of which is required to meet the electrical demands of one person per day. Many were impressed when they were then presented with a dummy pellet of nuclear waste the size of the end of their thumb that would produce enough energy for their entire lifetime.

This dummy pellet of nuclear waste shows how much nuclear material
would be needed to produce enough energy for your entire lifetime.

Meeting the energy demands of today is a pressing global issue and nuclear power provides a virtually carbon-free way of producing a large quantity of electrical power. Festival-goers were also surprised to learn that due to the large amounts of cement used to install solar and offshore wind power stations, the amount of carbon dioxide released is greater per unit of energy produced than nuclear over the lifetime of the power station.

However, people are generally fearful of the toxicity of waste that nuclear power reactors produce and how it is dealt with. By mimicking Bruce Forsyth’s TV show, Play Your Cards Right, people could learn about the relative radioactivity from different sources. For example, if you went on three transatlantic flights in a year, you would exceed the average annual occupational exposure of a nuclear power station worker.

What gives off the most radioactivity?

“But what if it all goes wrong?” said one lady from Bristol. This fear is understandable given disasters such as Chernobyl, Three Mile Island and Fukushima and it has resulted in publicly driven change. In Germany, for example, large anti-nuclear protests occurred in the wake of the Fukushima nuclear disaster in March 2011 caused by a tsunami. Partly in response to these protests, the German government have scheduled all nuclear power stations in Germany to be shut down by 2022.

It would be foolish to suggest that the effects of the Fukushima disaster are innocuous and that nothing went wrong. However, it surprised people to learn that despite the large number of fatalities caused by the tsunami directly, there were no recorded fatalities due to short term overexposure of radiation at Fukushima. Of course, the long term effects are unknown and it would be surprising if there were not any future health risks from the disaster.

Many older members of the public were concerned about the connection between nuclear power and nuclear weapons. It is a fact that the idea of using nuclear energy to generate electricity was borne out of the nuclear arms race that started during the Second World War. Nowadays though, the link between nuclear weapons and nuclear energy is unfounded in the UK because the plutonium required to make the weapons is not extracted from nuclear waste reprocessing.

The University of Bristol nuclear research group talking to
the public about nuclear energy at the Bristol Harbour Festival.

The physics of nuclear fission is very well understood by the scientists and engineers working in nuclear energy, and the risks of using this process to generate electricity are met with very strict safety standards. Despite these rigorous safety measures, nuclear power gets a bad press because the evidence for its potential to harm is clearly visible: the waste has to be specially treated before it is buried and the mass evacuations are put into place following a disaster. Nuclear power station disasters are etched into people’s memories because of their scale but the actual risk posed by a nuclear incident is much lower than maintained by the public.

On the other hand, large quantities of greenhouse gases are continuing to be released into the atmosphere from burning fossil fuels and although there is also visible evidence for climate change, the serious threat it poses to our planet it is diluted by politics. This plight is encapsulated by the most solemn of quotes from the event;

“I suppose the truth of it is, that the thing that isn’t green is humanity.” 

Perhaps nuclear fission could be a necessary interim energy source before cleaner nuclear fusion takes over in 50-100 years time.
——————————–
This blog is written by Cabot Institute member and PhD student Lewis Roberts.

Read more about nuclear research at the University of Bristol by visiting the Interface Analysis Centre website.

Building up solar power in Africa

It’s proving tough enough in the UK to increase the amount of renewable energy we use, and attempting this in Africa may seem like a pipe dream. However, six years ago, University of Bristol alumni Edward Matos (Engineering Design, 2009) and Oliver Kynaston (Physics, 2007), fresh faced out of their degrees, created a company to do just this.

Last month, I interviewed Oliver from his home in Tanzania and he gave me the low down on how it all happened.

It all started when Edward won £10K for his social enterprise idea in the 2009 Bristol New Enterprise Competition hosted by RED (Research and Enterprise Development) at the University of Bristol. The basic plan was to design and disseminate biodigesters amongst the rural poor of developing countries that would produce clean fuel for cooking and heating from livestock excrement; thereby avoiding the need to burn firewood in the home. Inhaling smoke in the home causes acute respiratory infections and in Africa alone, this causes more than 400,000 people, mostly children, to die every year.

Intrigued to find out if his idea was at all feasible, Edward flew out to Tanzania for two weeks for a business research trip. Oliver was working at a renewable energy company in the UK at the time and upon Edwards return, he joined Edward in a pub in Bristol for an informal chat. Reminiscing over this meeting Oliver tells me that at as they got talking about the possibilities, they both thought: “May be, may be we could just do this.” By the age of 25 the pair had formed Shamba Technologies, a renewable energy company in Tanzania.

In the early stages of the company, they lived on a farm in rural Tanzania in order to test their products for the local market. This was a crucial step that Oliver and Edward took because only by putting themselves in the shoes of their target market could they design products that were appropriate for low-income households.

Although Shamba Technologies started off with biodigesters, the company has now focussed on a new product that generates electricity from solar power. Increasing access to electricity is key to reducing poverty: health, education and communication can be greatly improved. In Tanzania, 15% of the population have access to electricity and there isn’t any semblance of an electrical grid outside of the cities. Therefore, products that can provide clean electrical power off-grid are pivotal in lifting millions of people out of poverty.

Oliver tells me that there have been three key technological advances which have paved the way to being able to develop such a product: solar panels, LEDs and batteries. They have all become more effective and cheaper over the years. Using these components, Shamba Technologies have developed a domestic solar product with an interesting design feature: the product can be bought in affordable chunks and assembled like Lego. In fact, Oliver says that this modular design was influenced by observing how a Tanzanian built their houses near their farm.

This product can be bought in affordable chunks and assembled like Lego.

“One day the foundations were laid and they were left for a few months, then some trucks came along with bricks and a few layers were laid down. A further six months went by, weeds started growing on the unfinished walls and we’d thought the building had been abandoned, but sure enough they came back with more bricks.”

This erratic building schedule is reflected in how Tanzanians spend their money. A stable wage with an hourly rate is hard to come by in Tanzania, and workers usually get paid in lump sums for a period of work or after selling farm produce. Given the lack of secure banking in Tanzania, it is prudent to turn your money into assets as soon as possible. So a Tanzanian would buy as many bricks as their money can allow, lay them on their house and then wait for the next pay packet.

The modular design of the solar energy product that Shamba Technologies have developed is a brilliant example of how Oliver and Edward have really understood and listened to their market. This underlying ethos of their company has put them in good stead for future success in the renewable energy market in Africa.

Edward and Oliver in Tanzania.

At present, Oliver still lives in Tanzania carrying out market trials of their products and Edward has recently returned from a year in China where he has been learning how to decrease the cost of their products through mass-manufacture. Shamba Technologies have high hopes for the future and would like to be at the forefront of Africa’s renewable energy sector in the next 10 years.

——————————
This blog is written by Cabot Institute member and PhD student Lewis Roberts.