In September last year, I was lucky enough to go back to visit New Zealand, tone up my accent, learn about the All Blacks and all that sort of stuff. I went to the South Island only, and at the beginning of the trip I went through a tiny village in the north of the South Island called Appleby. In the early to mid-1870s, Appleby had a tiny school with four pupils. Looking at it as I went through, it probably still has a tiny school with four pupils. However, one of those four pupils in the early to mid-1870s grew up to be a man called Ernest Rutherford, the father of nuclear physics. So it always quietly amuses me that, despite that, New Zealand has a mind-numbing allergy to nuclear power. Fortunately for New Zealand, it can get away with it, because it has wind—plenty of it in the north of the North Island at the moment—as well as solar, geothermal and hydroelectric, and all in abundance, as well as a relatively small population.
We do not have that in the UK. For us, nuclear power will have to be a substantial contribution to our power source—perhaps as much as 40%, perhaps more. At the moment, nuclear provides only 19% of our current demand, so, sadly, we are starting from a low base. Of our 13 current reactors, all but one are to close, as I understand it, from 2030. This coincides with the anticipated launch of Hinkley Point C, while Sizewell C has planning permission, but is years away from providing power. Fortunately, the Government have started a little lateral thinking, and they are opening the doors to small modular reactors. A number of British or British-based firms lead the world in this area.
I find the area of nuclear power fascinating, but I have to admit, before I get any awkward technical questions, that this is putting a strain on my physics knowledge, because it is years out of date and I studied it only briefly at university. In the UK, traditionally we are looking at light water reactors, but I understand that we are also looking, and should be looking, at speeding up the process for advanced modular reactors. These, I understand, would be complementary to the other small modular reactors. I am led to believe that advanced modular reactor development should and could be funded by industry, actively supported by the
Government, to move faster. These reactors, I am told, could come on stream early, thus filling the potential impending gap in our energy supply.
Of course, our golden gem, which is almost within the UK’s grasp, is the prospect of harnessing fusion, rather than fission. The research unit at the Culham Centre for Fusion Energy near Oxford is probably leading the world in this field. Fusion energy sustainable technologies have to be the answer to supply a growing population in the UK and potentially globally—perhaps even New Zealand in time. Fusion energy produces no greenhouse gases, is inherently safe and provides virtually limitless fuels, while waste is minimal, so it fits all the criteria. Fusion will have a key role to play in the energy market of the future. I can recommend a visit and a guided tour of Culham: it is exciting. As I have mentioned, I must admit that it strained my ancient university lessons on physics and I struggled to keep up, but even with my limited knowledge, I could see that this has to be our energy saviour.
Culham is in the United Kingdom Atomic Energy Authority collection. While this is sensible in some ways, it does mean that it is within the chicken coop of civil service pay scales.