Dr. Chris Edwards
HiPER Fusion Project Director chris.edwards@stfc.ac.uk
www.hiper.org

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STFC: The home of HiPER
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HiPER: Europe’s “other” fusion energy project
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Europe: Capability, Complexity & Constraints
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Aspirations and Relationships
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Funding prospects and the importance of ignition at NIF
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Discussion

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STFC: Science & Technology Facilities Council
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Funded via Research Councils UK by Ministry of Business,
Innovation and Skills (BIS)
•
Science Minister David Willetts
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STFC operates large scale facilities (VULCAN laser, telescopes, ISIS spallation neutron source, Diamond synchrotron, HPC infrastructures) for university researchers and manages UK contributions to CERN, etc., . . . . .
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. . . . but neither ITER nor JET (via EURATOM from E.C. and EPSRC)
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STFC (Mike Dunne) invented HiPER. STFC funded partners’ technical work for 3 years; E.C. funded coordination & governance for (3 + 2) years (to April 2013)

HiPER: Europe’s “other” fusion energy project
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Before LIFE there was HiPER
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HiPER is an “ESFRI” project (European Strategy Forum on Res. Infrastructures)
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HiPER brings together 9 funding agencies and 17 other partners across Europe

• Funding Agency involvement by 9 partners
– STFC (UK)
– CEA, CNRS and CRA (France)
– MSMT (Czech Republic)
– GSRT
– MEC and CAM (through UPM)
(Greece)
(Spain)
– ENEA and CNR (Italy)
• Institutional involvement by 17 other partners
– IST Lisbon (Portugal)
– CNSIM
– TEI, TUC
(Italy)
(Greece)
– IOP-PALS (Czech Republic)
– IPPLM
– FVB, FSU Jena, GSI, TUD
(Poland)
(Germany)
– Lebedev Physical Institute, (Russia)
Institute of Applied Physics-RAS
– Imperial College London, (UK)
Universities of York, Oxford,
Strathclyde, Queens Belfast

HiPER: Europe’s “other” fusion energy project
•
Before LIFE there was HiPER
•
HiPER is an “ESFRI” project (European Strategy Forum on Res. Infrastructures)
•
HiPER brings together 9 funding agencies and 17 other partners across Europe
•
HiPER was conceived in ~ 2006/7 as the next step to laser driven commercial fusion energy following “First Ignition” demonstration at NIF
•
The project was re-scoped in 2009; 10Hz laser driver; full blanket to capture fusion neutrons; electricity generation. (Many implications!)
•
HiPER has developed a delivery strategy that satisfies current constraints: financial, technical & political

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Single major facility construction step to deliver laser energy
2012 2014 2016 2018 2020 2022 2024 2026 2028 2030 2032 2034 2036 2038 2040
NIF
Ignition
LMJ available
LMJ
Ignition
Robust ignition; physics optimisation
Technology Dev t.
& Risk Red n.
Laser: 10kJ / 10Hz beamline prototype; Target mass prod.; Chamber concept
HiPER B. C.
Invest. decision
Exploitation
HiPER construction & commissioning
2012 2014 2016 2018 2020 2022 2024 2026 2028 2030 2032 2034 2036 2038 2040

Europe’s “other” fusion energy project
•
Before LIFE there was HiPER
•
HiPER is an “ESFRI” project (European Strategy Forum on Res. Infrastructures)
•
HiPER was conceived in ~ 2006/7 as the next step to laser driven commercial fusion energy following “First Ignition” demonstration at NIF
•
HiPER brings together 9 funding agencies and 17 other partners across Europe
•
HiPER has a developed a delivery strategy that satisfies current constraints: financial, technical & political
•
This schedule is not ideal, but it is credible, keeps partners engaged and preserves options in the “pre NIF ignition” era

Europe: Capability, Complexity & Constraints
Capability (simplified)
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U.K.
Atomic Weapons Establishment (AWE) maintains UK deterrent:
Orion laser facility, HPC, tritium, in-house HED science programme, physics codes. Working to add “fusion energy” to its mission
STFC Rutherford Appleton Laboratory:
VULCAN laser facility, HPC, centre for DPSSL laser development, HED science programme in partnership with UK university groups
Nuclear power industry (declined); AMEC, RR, BAE Systems, NNL, etc.
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France
CEA:
“NIF-like” LMJ (on-line 2015 – 16) and associated capabilities
Host organisation for ITER
Carbon neutral energy mission; GEN-IV development, solar, etc.
Extensive nuclear power industry; EDF, Areva, etc

Europe: Capability, Complexity & Constraints
Capability (simplified)
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Czech Republic: ELI Beamlines
One of three large laser projects which comprise the Extreme Light
Infrastructure (ELI), funded largely from E.U. “Structural Funds”
Other projects of similar scale are starting in Hungary and Romania
These facilities require a new laser technology; high efficiency, high repetition rate (>10Hz) and high power . . .
. . . also the requirement for the laser driver for inertial fusion energy
Contracts between IoP Prague and U.K. (CLF) and U.S. (LLNL) are driving the development of this DPSSL technology

Europe: Capability, Complexity & Constraints
Complexity & Constraints
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MFE programme, JET and ITER (under construction)
LIFE and HiPER programmes will validate all the physics, engineering, technology and commercial viability of fusion power via single, major facility build using existing materials
ITER will not have a full blanket or tritium cycle; larger machines required for commercial power production will introduce physics unknowns, plasma stability, materials issues
Extreme sensitivity over IFE / MFE delivery schedule
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Physics design for IFE based on X-ray (indirect) drive (NIF) requires access to computer codes that are not in the public domain
HiPER Executive Board determined an ignition physics strategy based on direct drive (shock ignition) to be demonstrated at LMJ ~ 2022
UK works on both schemes; indirect drive is outside of HiPER scope
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Demonstration of ignition at NIF is likely to change this landscape

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Affordable
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Security of supply
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Environmentally responsible
Ludwig Boltzmann (attrib), 1886

U.K.
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UK has the opportunity to be on the supply side of IFE through laser technology, fuel capsule design and manufacture, etc.
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AWE is actively seeking an energy remit, supported (not funded) by MoD;
AWE’s Board has agreed to co-fund start-up programme
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STFC, AWE and Livermore have signed an MoU to collaborate on IFE; announced by BIS Minister David Willetts and Ed Moses at an IFE event at
Royal Society in London
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STFC has a long history of collaboration on ICF with Japan. MoU and staff exchanges, etc.
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An inter-Gov t.
agreement on IFE is possible following ignition

France
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Keeping options open; CEA maintaining influence
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France (CEA) partnered with US on production of NIF & LMJ laser glass and other components
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France and UK are collaborating on defence procurement; CEA and AWE are developing joint facilities
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Local Government in Bordeaux region is contributing additional capability to LMJ which can be used for HiPER relevant research
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LMJ beam time will be available for academic access and HiPER, from 2016

14 th October 2010
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“LMJ to be used for energy research”
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“By choosing to build the PETAL laser next to the Laser MegaJoule, we open the way to explore a new type of energy”

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HiPER “Preparatory Phase” was funded by EC (coordination & governance);
STFC and MSMT funded technical work
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STFC is funding continued coordination and governance until April 2014 . . . .
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. . . beyond April ‘14, STFC will fund 50%; seeking 50% from partners in return for representation on the HiPER Steering Board
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Technical work is funded on a national basis
Laser technology in UK, France & Czech Republic
Physics modeling in UK, France & Italy
Systems engineering in France & Spain
Materials and chamber design in Spain
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Funding from E.C. is likely beyond 2014 within “Horizon 2020” programme
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Ignition at NIF is likely to unlock substantial funding, at least in UK and France

Fuel
D: 115 ppm in seawater; chemical extraction
+
+
+
+
TBR >1.1
Li: abundant in earth’s crust
7%
6
slow
4
3
4.8 MeV
93%
7
fast
4
3
slow
2.466 MeV
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Castle Bravo (1954) yielded 15MT compared to a predicted 5MT
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Also neutron breeding from 207 Pb (or 9 Be) (n,2n) reactions

Beryllium
Gallium
Arsenic
Yttrium
Indium
Xenon
Ytterbium
Tungsten
Gold
Lead
Material
Deuterium
Tritium
Helium
Lithium
Use
Fuel
Fuel
Cryogenics
Turbine fluid
Coolant
3 H production n 0 breeding
Laser diodes
Laser diodes
Laser host
Laser diodes
Chamber gas
Laser material
First wall
Target cones n 0 breeding
Target cones
Consumption Inventory
95 t/yr Small
143 t/yr ?
3800 t/yr
340 t/yr
155 t/yr
?
100 t/yr
240 t/yr
500 t/yr
17600 t/yr
7000 t/yr
?
349000 t
3100 t
1370 m
2000 t
24000 t
Small
?
Small
3
Production
140 t/yr
N/A
25000 t/yr
340 t/yr
7000 t/yr
5000-7000 m 3 /yr
50 t/yr
58000 t/yr
2350 t/yr
4 ×10 6 t/yr
Reserve
2.3
2.3
80000-485000 t
425000 t
3.5
1
×10
N/A
×10
×10
×10
2.8
1.5
13
11
11
6
×10
×10
6 t t t m
470000 t
9 t t
3

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Laser energy must be commercially and technologically viable
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Many aspects to be assessed
• Role of laser energy as part of the energy mix
• Value of “security of supply” & “first to market” advantage
• Cost of electricity ( €/kWh) & dependencies
• Rate and cost of build
• Investment & funding scenarios (NPV, DCF, debt, …)
• Impact of carbon (obligations, taxing, …)
• Economic Impact on the collaborating nations
• Industrial sector impact and alignment
• Exploitation of spin-off technology development
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Studies in progress; no “show stoppers” identified so far
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High gain ignition scheme and > 10 Hz repetition rate

UK Electricity Production
Slide20

2 GW coal station at Didcot closed in March ‘13
UK is facing high probability of power cuts in 2015
Slide21

fusion, fission,
(or coal!)
Wind (offshore)
Tidal
Solar
(PV)
45km
Wind (onshore)
Solar bio-mass
(Hydro is twice this size;
Geo-thermal is 30 times this size
)
For 1GWe
Energy form
Onshore wind
Offshore wind
Solar
(photovoltaic)
Solar biomass
Tidal
Hydro
Geothermal
Fission/fusion
0.5
3
0.24
0.017
1000
Energy
Density
(W/m 2 )
2
3
10
DJC McKay (2009)
22

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There are options for the future, but they come with difficult choices
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In the short term, UK is committed to replace coal with gas (from Norway &
Eastern Europe; lpg from Qatar)
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. . . . followed by a fission reactor build programme in the medium term . . . .
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. . . . or a huge scale-up of renewables supported by feed-in subsidies
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Fusion could solve our energy needs beyond 2050
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Requires ignition at NIF, long term political vision and investor support
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Progress to date is encouraging!

Strengths
1. Deliverable on "energy relevant" timescale
2. Separability enables parallel development
3. Physics can be demonstrated at full scale at NIF & LMJ
4. < 1kg Tritium inventory
5. Sustainable
6. Inherently (comparatively?) safe
Opportunities
1. Technology has high, immediate exploitation potential
2. First wall has no containment function
2. Use of existing, qualified materials simplifies licensing
3. High reaction temperature enables chemical processes
Weaknesses
1. Laser driver scalability not yet demonstrated
2. Mass production of fuel capsules to quality and cost
3. Novel material may be required for first wall (HiPER)
4. Commercial viability not yet demonstrated
5. "Fusion is always 50 years away!"
Threats
1. First Ignition" is not assured
2. Laser diode cost reduction not yet demonstrated
3. Political focus on renewables
4. Difficult economic environment for R & D funding