Abstract
Keywords
1 Executive summary
This paper presents the result of detailed discussions initiated in 2018 at the ECLIM conference and further promoted by the authors with the involvement of the broader scientific community, to propose a realistic but ambitious and coordinated approach to the development of a fusion power plant based on the concept of inertial confinement fusion (ICF) driven by high-power lasers. This project aims to create a scientific basis and a technological readiness that will enable future commercialization of laser fusion energy. The goal is to demonstrate direct-drive ignition of fusion reactions with lasers and high repetition rate (HRR) high-gain laser operation using frontier laser technology and sustainable materials. This goal will be achieved on a time scale of 20–30 years. It will be facilitated by creating a European Laser Fusion Research Centre – a joint venture of several major stakeholders – including research laboratories, universities, governmental organizations and private companies. In parallel with resolving scientific and technological challenges, this centre will enable the development of innovative laser technologies, neutron-resistant materials and high-performance computing, thus demonstrating the viability of inertial-fusion energy (IFE), attracting private investments and providing education of qualified personnel, all of which is of broader societal interest.
The critical element of the laser-driven ICF is a ‘target’, comprising a millimetre-sized hollow spherical shell filled with a mixture of deuterium (D) and tritium (T) fuel. An array of laser beams illuminates the shell, compressing the fuel more than 1000 times. This heats the fuel to 100,000,000°C in a few billionths of a second. At such extreme conditions corresponding to pressures of hundreds of billions of atmospheres, the nuclei of deuterium and tritium fuse and release energy in the form of the kinetic energy of fusion products that can be transformed into heat and electricity.
Until recently, uncertainty remained about how much laser energy was needed to produce more fusion energy than what was input by the lasers (energy gain). This was resolved by an experiment at the National Ignition Facility (NIF) in the United States, which provided a quantitative answer to this crucial question. In December 2022, it was demonstrated that with 2.1 MJ of laser energy, it is possible to achieve energy gain; the DT fuel released 1.5 times more nuclear energy than what was input by the lasers. A second successful experiment was announced in August 2023, confirming an ever-higher gain factor of around 1.7.
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NIF’s achievement opens the way for the next stages of research and development, including (i) a robust control of fusion ignition, (ii) the design of targets able to produce approximately 100 times more fusion energy than the laser energy input, (iii) the creation of the supporting infrastructure, technology and materials for an IFE reactor that is expected to routinely produce about 10 laser–capsule interactions per second, (iv) education and training of the personnel. Based on existing projects, IFE power plants can be built on a safe separable modular technology that offers considerable flexibility in energy production and can be commercially viable. Building on the NIF’s success, ambitious IFE national programmes have been proposed recently in the United States[1] and Germany[2].
There are currently two ways to compress the DT fuel: the direct illumination of the target by laser light, the direct-drive approach, or the so-called indirect drive. In the latter approach, the laser beams are injected into a hollow gold cylinder, producing X-rays by heating its inner wall. Intense X-ray radiation then drives the implosion of the spherical capsule placed inside. The indirect-drive ignition scheme used at the NIF aims to achieve ICF for defence applications; the laser energy is used inefficiently due to the need to convert laser light into X-rays. In contrast, the direct-drive approach promises a four to five times more efficient use of the laser energy[3]. Thus, a lower energy is needed for ignition, and a higher fusion energy yield can be achieved. Yet, there is no laser facility in the world where direct-drive ignition can be demonstrated.
European scientists have made ground-breaking contributions to inertial fusion in theory, numerical developments and experiments. They performed pioneering works in high-energy-density physics by studying laser–plasma interactions (LPIs), including parametric instabilities, hot electron production and transport[4–9]. European scientists are also leading in high-field physics with short-pulse, high-intensity lasers. These important contributions to high-energy, high-density and high-field physics have led to two large-scale laser projects included in the roadmap of the European Strategic Forum for Research Infrastructures (ESFRI): High Power Energy Research (HiPER)[10], dedicated to laser-driven IFE, and Extreme Light Infrastructure (ELI)[11], dedicated to fundamental studies of electromagnetic processes at extreme laser intensities. Unfortunately, due to the delay in achieving ignition at NIF, HiPER was stopped in 2013, while ELI is progressing successfully with its implementation at three sites in the Czech Republic, Hungary and Romania.
The recent achievement of ignition at the NIF calls for a change in the quest for inertial-fusion energy research, leveraging the significant legacy of the HiPER project but at a new level of knowledge and technology developed over the last 10 years. Different from other IFE national initiatives in the United States, Japan, Russia and China, European scientists propose a European project truly open to international collaboration. HiPER+ will be dedicated to civilian fusion energy production and developing high-level spin-off technologies.
HiPER+ centres on the shock ignition (SI) scheme developed by the European academic community in close collaboration with US scientists at the Laboratory for Laser Energetics (LLE) at the University of Rochester. This scheme is based on the direct-drive approach with a specific laser pulse shape conceived to facilitate ignition using less energy with respect to the original direct-drive scheme. According to preliminary experiments and numerical simulations, ignition via SI is possible with a laser energy of about 0.4–0.5 MJ, with higher energy gains with a 1 MJ laser. The SI scheme has already confirmed its advantages in dedicated sub-scale experiments at the multi-beam, multi-kJ US laser facility OMEGA. However, SI still faces scientific challenges, which require programmatic investigations. This concerns the efficiency of laser–target coupling and the generation of a sufficiently strong shock to produce a robust ignition. At the same time, the development of lasers operating at HRRs and technologies for target fabrication and energy recovery are needed. The SI approach shares many features with other advanced ignition schemes, like fast ignition, where the hot spot is produced by energetic protons or electrons. In all cases, a direct-drive implosion requires stable compression before the onset of the specific ignition scheme. This also means that many of the laser specifications and diagnostics concerning the implosion phase, which accounts for most investments, are common to all these schemes.
The project HiPER+ aims at the stage beyond the single-shot ignition demonstration through the construction of a high-performance laser facility with an HRR, the demonstration of robust and repetitive fusion energy production and then the conceptual design of a commercial inertial-fusion power plant. It will be conducted at the European Laser Fusion Research Centre in close collaboration with national laboratories, universities, private companies and industry. The centre will provide user access to conduct programmatic research and development activities at the best possible level, to test innovative target designs, for advanced diagnostics, for mass target fabrication, for laser and fusion technologies and provide internationally competitive theoretical, computational and logistics support. To this respect, we can count on the experience gained with the original HiPER project, which was a turning point in demonstrating the possibility of bringing together the European scientific community beyond the national limits within one joint research and development project directed towards IFE production. The new project HiPER+ takes off from the heritage of HiPER with the lessons learnt from the NIF experiments and the major advances in laser technology developments also driven by the ELI project.
A multi-beam laser facility operating at the energy level of a few hundred kilojoules, up to one megajoule (depending on the chosen target design) and with a repetition rate depending on the laser technology readiness (a realistic starting point can be one laser shot per minute) is the major milestone of this project, with a hundredfold increase compared to currently operating facilities and within reach of advanced high-power laser technology. This will be a test-bed for research on (i) the physics of IFE targets, (ii) the study of laser–target interactions, (iii) the development of new laser and target technologies and (iv) the design and testing of new materials resistant to extreme conditions of radiation, temperature and mechanical stress. This will be the first-in-the-world international laser facility dedicated to research on IFE and other applications in high-energy-density physics. It will unlock the major scientific and technological issues related to the ignition-scale experiments. It will address problems such as reproducibility of the capsule implosion, control and mitigation of different instabilities, optimization of target implosion and ignition schemes and the injection and alignment of targets. Such a laser facility will also address the technical aspects of primary importance: the effects of target debris and vapours in the chamber, damage to optics and chamber walls, activation of materials, protection from electromagnetic pulses (EMPs) and development of novel advanced diagnostics.
The progress made by laser technology in the last decade and the maturity of optics and the laser industry make it possible to build such a facility at an industrial level as a modular structure by replicating elementary blocks with an average power of a few hundred watts and laser pulse energy of a few kJ. The design and construction of such a laser facility will strongly benefit European industry, since the elementary laser modules will find many other industrial applications: compact secondary sources of protons and neutrons for material analysis and medicine; a new generation of thrusters for space propulsion; material modifications with lasers; space debris removal; mass fabrication of high-precision objects; and many others. It will also build stronger connections with magnetic confinement fusion research and related development activities, which share many common objectives in the design of the fusion power plant.
The creation of the European Laser Fusion Research Centre will be beneficial for both science and industry by consolidating the research groups spread over the different countries, providing them with a common, modern, high-performance research tool and prompting the development of innovative laser, material and optics technologies, which are the critical elements for the sustainable progress in the 21st century. It will also be a hub for the coordination of the IFE development with private initiatives and companies operating in the domain of high-energy lasers and applications. All these features make establishing a new European IFE initiative most timely and compelling, with the primary aim to create a breakthrough in direct-drive ICF ignition and prepare the technological bases for future clean, sustainable, flexible and safe IFE production.
2 Background
The concept of laser-driven ICF was proposed in 1972 in seminal papers by American and Russian scientists[12,13], which initiated a worldwide effort to demonstrate inertial fusion in the laboratory. After five decades of continuous progress towards ignition, scientists at the NIF at the Lawrence Livermore National Laboratory, United States, announced major advances. In an experiment in August 2021, about 70% of the input laser energy was converted into products of the DT fusion reactions[14–16]. In an experiment in December 2022, the released fusion energy surpassed by 50% the 2.1 MJ input laser energy[17]. A recent experiment in August 2023 provided an even larger yield: about 170% of the input laser energy[18,19]. It confirms the repeatability of the achieved ignition conditions. These ground-breaking results provide an unambiguous demonstration of the validity and feasibility of the concept of IFE with lasers. Much larger energy gains will likely be demonstrated by US scientists shortly.
The approach pursued by the Livermore scientists is based on the indirect-drive scheme, where the incoming laser radiation is first converted to soft X-rays in a gold cylinder cavity called a hohlraum (see Figure 1(a)). Then, these X-rays symmetrically irradiate a spherical capsule filled with DT fuel positioned in the centre of the cylindrical cavity. The radiation ablates the outer layers of the capsule, compressing the fuel inside more than 1000 times and heating it to a temperature of 100,000,000°C.
Figure 1.(a) Laser beams irradiating the hohlraum enclosing and the DT-filled capsule at the NIF (image courtesy of the LLNL). (b) Sequence of four stages of the ICF process in the indirect-drive scheme: (i) irradiation of the spherical capsule by X-rays; (ii) ablation of the outer part of the capsule and implosion of the DT fuel; (iii) ignition of the fusion reactions in the central hot spot; (iv) combustion of the compressed fuel and energy release.
These are conditions where the fusion reactions take place and release a surplus of energy in the form of energetic neutrons and radiation. Since this is a national, defence-motivated programme, the NIF laser was not built for the conversion of fusion energy into electricity, and the beam arrangement is not optimized for IFE. The facility time is shared among the stockpile-stewardship programme, basic science experiments, and ICF[20]. As such, it is not well suited for open IFE research from a technical and programme standpoint. Similar national, defence-oriented programmes are pursued in France, the UK, China and Russia.
The indirect-drive scheme can be considered for future energy production. The Livermore scientists have developed a project, LIFE[21], based on solid-state laser technology, and a new startup company, XCIMER, has been recently launched aiming for fusion energy production by using excimer lasers[22]. This approach has certain advantages of smooth target irradiation, target protection from hostile environments in HRR operation and suppression of nonlinear LPIs. However, this scheme suffers from very inefficient laser energy coupling to the target[3], a large quantity of debris in the chamber and a large mass of hohlraum that increases the amount of radioactive waste.
The direct-drive approach consists of the direct laser irradiation of a capsule with a DT fuel, thus bypassing the step of conversion in X-rays in the hollow gold cylinder (see Figure 1(b)). It is more efficient and better suited for energy production, but implosion is less stable and needs better control. This is a promising approach for constructing a fusion power plant: an abundant, clean, sustainable and on-demand energy source for mankind. Research on the direct-drive ICF scheme is concentrated in the United States, the UK, Japan and the EU. The direct-drive project HiPER was included in the roadmap of the ESFRI and conducted for seven years from 2006 to 2013[10].
HiPER was a unique European initiative with international participation in IFE aimed at exploring the science and technology of laser direct-drive fusion schemes, which are suitable for commercial energy production from laser-driven DT fusion reactions. The general scheme of the ICF power plant developed within the HiPER project is shown in Figure 2. It consists of three modules: the laser amplifier and focusing system, the reactor chamber and the system of energy recovery and conversion to electricity.
Figure 2.HiPER original concept of the ICF power plant (adapted from Ref. [10]).
In the second phase, the HiPER project was focused on the SI scheme, which promises ignition at a lower laser energy level and higher fusion energy gains compared to the conventional direct-drive scheme. Many critical elements of the SI scheme can be tested at full scale on the existing laser facilities, including the NIF in the United States and LMJ in France. HiPER also had a crucial role in developing designs of reactor technologies that allowed us to define the research to be done and the risks associated with the different reactor systems. Another equally important objective of the HiPER project was to build a sustainable, long-term, basic science programme, strengthen international collaboration and training and stimulate high-level technological and industrial developments in high-power laser technology, high-resistance materials and optics. HiPER has made a strategic mistake by assuming to provide an electrical power plant in an unreasonably short time.
Unfortunately, HiPER was ahead of its time. Due to the delay in achieving ignition at the NIF, HiPER finished its preparatory phase in 2013[10,23], and the direct involvement of Europe in ICF research has slowed down in the last eight years because of a very low level of funding and severely limited access to experimental facilities. Nevertheless, the funding coming mainly from the EUROfusion Enabling Research (ENR) projects at the level of 1 M€ per year and also from some national projects has allowed the European community to remain active and productive. The latest ENR action, ‘Advancing shock ignition for direct-drive inertial fusion’, for the period 2021–2024 is the continuation of two previous ENR projects, aiming at realizing a European research programme on an SI scheme and its implantation in a reactor, a promising approach to ICF developed in collaboration with US scientists[24,25]. In addition, funding from the Erasmus+ programme contributed to the training of young scientists in the fusion sciences[26]. Yet, the most important output of the HiPER project was its impact on the laser fusion community, which has experienced impressive growth in Europe, mainly directed towards exploiting a new generation of high-power, HRR laser facilities[11].
The energy gain of 1.5, achieved at the NIF in 2022, finally confirms that the physics of laser-driven ICF works as anticipated, thus enhancing the confidence that it could provide a viable solution for fusion energy. An inertial-fusion reactor has the advantages of modular technology, flexible configuration, a low tritium inventory and a relaxed constraint on first-wall damage. Moreover, ICF shares with magnetic confinement fusion common points, such as energy recovery, structural materials, remote robotics in a harsh environment and tritium breeding and handling. Development of both approaches in Europe will benefit each other and enhance the probability of success in establishing a commercial fusion power plant. With a strong background in plasma physics, material and laser technology, accumulated over 50 years of intense research, European scientists are capable of taking a leading role in IFE research and development at an international level[27,28].
The quest for clean and sustainable energy sources has recently attracted growing interest from the private sector[29]. Investments in fusion startups have accelerated in the last few years. In particular, in 2021, various fusion approaches, including laser fusion, attracted more than 6 B€ of venture capital funding, mainly for US companies. In Europe, industries joined the nuclear fusion race with growing interest. Industrial companies such as SIEMENS ENERGY, THALES and TRUMPF are interested in developing laser technology for nuclear fusion. The German company MARVEL FUSION raised 35 M€ in a funding round led by venture capital investor EARLYBIRD[30]. The German–US company FOCUSED ENERGY[31,32] is one of the two companies devoted to IFE selected by the US Department of Energy for funding under the public–private Fusion Development Program. MARVEL FUSION and FOCUSED ENERGY also are receiving significant funding from the Germany fund SPRIN-D[33]. There is an evident need for much better coordination of IFE research through establishing a new ambitious programme in Europe. The HiPER+ initiative will pursue the original HiPER objectives at a new level of knowledge, technology and organization[28].
3 Inertial confinement fusion research in Europe
3.1 Physics of inertial confinement fusion
ICF entails a large variety of interesting physical phenomena such as nonlinear LPIs, target hydrodynamics and implosion symmetry, energy transport in the plasma by thermal and non-thermal particles and X-ray radiation, atomic physics, equation-of-state of matter at high energy densities, ionization processes and transition from the solid state to plasma, fusion burn physics, the generation of strong electric and magnetic fields and energy recovery. Correctly modelling target implosion under laser irradiation and fusion energy release requires accounting for all of these processes simultaneously, which needs a significant amount of theoretical, numerical and experimental work supported by innovative technologies and materials development. Simulation codes have been a fundamental building block in the development of ICF, particularly in achieving ignition. Open 1D codes, including hydrodynamics, laser energy deposition, electron and photon energy transport, energy production in fusion reactions and energy deposition by alpha-particles, were already developed in the 1970s and 1980s[7,34,35]. However, the radiation transport was somewhat simplistic, corresponding to the then computer performance. In the last 20 years, the ICF community in Europe has made critical contributions to ICF code development in one and two dimensions, as summarized in several key references[9,36–46]. This work, in turn, feeds through to the development of state-of-the-art simulation codes[47–50], validated by experiments and used to explore implosion physics, target designs and implosion schemes.
The original direct-drive ICF design is based on the central hot-spot ignition scheme, where a spherical shell target is symmetrically compressed at high velocity by direct irradiation of lasers until it reaches a sufficient convergence ratio (also called the ‘fuel assembly’ phase). The kinetic energy of the imploding shell is used to compress and heat the fuel in the centre of the target to the level needed to ignite fusion reactions. The burn wave then propagates into the cold, dense surrounding fuel material. This direct-drive scheme has been extensively studied using experiments on the OMEGA laser by US and European scientists. The challenges of this scheme are also shared with the SI approach. Several critical issues of both schemes have already been identified and addressed. However, the OMEGA experiments are limited by the laser energy of 30 kJ, which is two orders of magnitude below the ignition threshold[51,52]. (The exact value depends on the energy scaling and the target design.) Demonstration of energy gain and reliable energy production poses new challenges. One needs reliable new laser systems able to perform many shots per day at the MJ level, a design of simple and robust targets capable of withstanding typical laser system errors[53], which are suited for mass-manufacturing and are cost-effective. One of the possible solutions is the dynamic shell concept[52,54] using foam as a structural element.
An integrated approach must be developed that combines physics requirements with material constraints, reactor chamber issues, high-performance diagnostics and technology availability and capability. The reactor chamber design has to have an optimized laser port layout for both symmetry and robustness, compatible with the systems of target injection and energy recovery[55]. Materials that will be used to construct the reactor chamber, target injection system, energy recovery and tritium production must be resistant to harsh radiation environments, thermal loads and mechanical stresses. Hence, the reactor lifetime will be compatible with commercial energy production. Addressing these formidable challenges is possible at the existing level of science and technology. Still, it requires joint efforts of specialists from different science and technology domains within a common project.
3.2 Direct-drive alternative ignition schemes
The ICF research is mainly concentrated around the central hot-spot ignition approach. The ignition is produced as a culmination of the compression phase when the conditions of pressure, temperature and density reach the fusion threshold. The alternative ignition schemes open the possibility for optimization of ignition conditions by separating the compression stage and using a separate driver to achieve ignition out of the pressure equilibrium. Such schemes offer the possibilities for a more stable implosion, lower ignition threshold and higher fusion energy yield.
There are two families of alternative ignition schemes: fast ignition and SI. The fast ignition schemes enable working with thick shells at lower compression values and rely on the energetic proton or electron beams to achieve ignition in the off-centre hot spot[56,57]. A significant improvement in the laser–target coupling has been reported recently in electron-driven fast ignition by using the method of magnetized isochoric heating[58] and electron super-penetration[59]. Promising new results are also obtained in proton fast ignition by demonstrating tight proton focusing[60,61]. However, fast ignition schemes require an additional high-power, high-energy laser driver with pulse duration in the 10 ps range, a technology still less mature than the nanosecond high-energy lasers. Much of the European ICF research is focused on the SI concept, which relies on the high-energy laser driver with a pulse duration in the sub-nanosecond range and the central hot-spot ignition. These technologies for shock generation are on a much higher level of maturity and technical readiness.
The SI concept was proposed and developed in collaboration with US scientists[24,25,62]. This scheme separates the fuel assembly phase from the ignition phase. The temporal shape of the laser pulse is shown in Figure 3(a). The target is first compressed by lower-intensity laser radiation at a low implosion velocity of approximately 280 km/s and then ignited by a strong laser-driven spherical shock. The separation of these two phases is the primary advantage of this scheme. It provides a more stable and energy-efficient capsule implosion and a larger amount of compressed fuel for the same laser energy. The implosion is achieved with a relatively low-intensity laser pulse of less than
Figure 3.(a) Laser power temporal profile in the direct-drive shock ignition scheme. (b) Laser temporal profile in the shock-augmented ignition approach and the scheme of the capsule (adapted from Ref. [63]).
Preliminary SI experiments at the OMEGA laser facility in the United States at energy levels of 25 kJ have demonstrated the advantages of the SI scheme compared to the conventional direct-drive scheme: the creation of a strong laser-driven shocks resulted in an increased number of fusion reactions manifested in the number of detected neutrons[64] and a shock pressure exceeding 200 Mbar has been reported[65]. Other variants of the SI scheme, potentially more efficient, have been proposed: the ignition shock driven by the laser radiation and hot electrons[66] and the shock-augmented ignition by using a dip in the laser power before launching the shock[63]. The latter scheme allows a reduction in the laser spike intensity by introducing a gap between the main pulse and the spike (see Figure 3(b)) and thus decreases the undesirable nonlinear processes and increases the gain. This scheme has recently passed the first experimental validation on the high-energy laser facilities OMEGA and NIF. There is an evident need for extensive numerical modelling and experimental benchmarking to further develop the SI scheme and its variants.
While the NIF and LMJ are designed for indirect-drive implosion, they can be used (with lower efficiency) in the direct-drive geometry by repointing and refocusing beams. This polar direct-drive (PDD) scheme[67,68] has already been tested in experiments at the NIF[69–71]. We plan to continue these experiments at the NIF and LMJ in application to the SI scheme.
3.3 Challenges in ICF
While the results of radiation-hydrodynamic simulations and experiments are optimistic for the prospect of high gain with the direct-drive scheme and SI in particular, these schemes have scientific and technical challenges yet to be addressed. The major challenges of the direct-drive ignition scheme are shown in Figure 4. The studies on IFE require sustained and coordinated efforts of the scientific community, close relations with the private sector and strong governmental support.
Figure 4.Four stages of direct-drive ignition and the main challenges: (a) laser capsule interaction and energy coupling; (b) the shell inward acceleration – hydrodynamic and parametric instabilities; (c) shell deceleration phase, hot-spot formation and material mix; (d) ignition of fusion reactions and burn propagation (adapted from Ref. [72]).
One major physics question is that of LPIs, particularly during the high-intensity laser spike pulse, which may reduce the amount of laser energy absorbed in the target[73], reduce the amplitude of the shock wave[53] and prematurely heat the fuel by hot electrons[74]. Low-entropy implosions of standard direct-drive capsules have shown a high risk of failure, indicating new sufficiently resistant and robust target designs are needed. Furthermore, modulations of the ablator surface and density inhomogeneities resulting from target fabrication and sub-wavelength scale perturbations imprinted on the ablator by the laser irradiation can grow, reducing the igniting-shock launching window[75,76]. Strategies for mitigating laser imprint on the ablator and hydrodynamic instabilities must be developed. The use of foam materials (see Figure 5) could be promising[77–79]. Studies of ignition physics must be coordinated with developing a new generation of high-energy, HRR lasers and the design of high-performance plasma diagnostics and target mass fabrication technology.
Figure 5.Microscopic views of foams produced by chemical polymerization (a) and two-photon polymerization laser lithography (b) for ICF studies (adapted from Ref. [79]).
Studies of the baseline HiPER target SI design[25] suggest that depending on their energy, hot electrons could either improve or worsen the target performance. Hot electrons with energies less than 50 keV do not produce deleterious effects but amplify the shock strength and improve the target performance[80]. By contrast, more energetic electrons generated during the spike may ablate the DT ice inner interface and significantly increase radiation losses, preventing ignition[74]. These results highlight the necessity of designing more robust targets, considering the detailed characterization of nonlinear LPI effects, hot electron generation and transport.
LPI mitigation strategies allowing the reduction of laser energy losses and diminishing or tuning hot electron generation need to be investigated[81]. The manipulation of laser coherence time and the development of broadband lasers appear promising for suppressing LPI[82]. Increasing laser bandwidth between a few tenths of a per cent and several per cent can inhibit laser filamentation and LPI[83]. Laser zooming[84] for the spike pulse has been proposed to improve laser–shock coupling and significantly reduce cross-beam energy losses. Improved control of LPI might allow the testing of ignition schemes using the second harmonic of Nd:glass lasers instead of the third harmonic, which opens the way to a more efficient use of laser energy[39] and is better suited for operation at HRRs.
3.4 Lessons from the NIF ignition campaign and OMEGA laser facility
The European IFE project profits from the knowledge and experience acquired during the 12 years of experiments at the NIF and several thousands of direct-drive implosion experiments conducted at lower energy on OMEGA[85]. The failure of the National Ignition Campaign in 2013 was due to many issues that needed to be better controlled and understood at that time. They included insufficient symmetry of laser irradiation, laser–plasma instabilities and defects in the target fabrication, which led to premature development of hydrodynamic instabilities and shell break-up. Also, insufficient precision of the radiation-hydrodynamic codes and a limited number of diagnostics available in the experiments did not provide the degree of accuracy needed to design a target that ignites in an experiment with a limited energy budget. The diagnostics were not capable of providing detailed information about the processes going on in the capsule inside a closed hohlraum. The lasers were not capable of delivering precision pulses with sufficient repeatability, power stability and pointing accuracy.
Since then, a large amount of work has been done addressing these issues. The issues related to the quality of implosion have been identified and resolved one after another. The physics included in the codes was greatly improved and now provides a better agreement with experiments and more stringent limitations on the parameter space where ignition and gain can be achieved. More than 60 high-fidelity diagnostics have been developed at the NIF, all providing valuable insights into the physics processes in the imploding target. The laser performance is continuously improving as the operators have better control of the beam quality and focus and better understand the physics issues at play. More than 1000 implosion experiments have been performed at the NIF since 2009. Many numerical simulations have provided an extensive database, which is used for fine-tuning hydrocodes, designing empirical scaling and improving it with machine-learning techniques. Along with a significant improvement in the laser performance and target fabrication technology, the progress in theory, simulations and diagnostics is thus the main reason for the recent successes of the NIF. Similar progress in diagnostics, codes and laser beam control was achieved in the last 10 years at the OMEGA facility. While laser energy is limited to 30 kJ, OMEGA is configured in direct drive and provides an invaluable test-bed for direct-drive physics.
The lessons from the NIF and OMEGA campaigns provide important input for the European IFE project that will reduce the risks and accelerate progress.
These conclusions are considered important information in developing the European IFE roadmap.
3.5 Laser technology developments
ICF research has provided a strong boost for developing new laser technologies and the dramatic growth of the laser industry. In parallel, the advent of chirped pulse amplification has led to the construction of ultrashort pulse, ultra-high-intensity and HRR laser facilities worldwide[87]. Europe-based leading laser manufacturing companies, such as THALES, AMPLITUDE and TRUMPF, are capable of delivering turnkey high-power, HRR laser systems and provide technical support for their operation. The European ESFRI projects, ELI[11] and European Plasma Research Accelerator with excellence in Applications (EuPRAXIA)[88], stimulate rapid scientific and technological developments on a very short time scale aimed at high-field science, particle acceleration and secondary radiation sources. Many of these developments have generated industrial products impacting other commercial areas, including the medical and manufacturing industries.
The scientific communities in high-energy-density physics, plasma physics and high-power laser technology are working closely with each other, with large European research institutes having active research programmes in all of these areas, which share common background knowledge. The laser–plasma community is a large and expanding community partially merging with the synchrotron and X-ray free electron laser communities, sharing a common interest in investigating extreme states of matter with ultrashort and high-brightness X-ray pulses. These communities also share particle and radiation diagnostics and high-power laser technologies, which have significantly advanced over the last 10 years.
However, access to these extensive facilities is minimal due to their high cost, low repetition rate and large size. A further revolution is needed to reduce their size and price and to improve their reliability – the use of flash lamp pumping limits solid-state lasers’ average power and repetition rate. New approaches based on high-efficiency diode pumping and active cooling (see Figure 6(a)) are paving the way to high average power, high-efficiency and HRR lasers[89]. This transition is a necessary step for the IFE programme, and will make lasers and laser-based light sources available to a broader community, empowering small and medium high-tech enterprises and making them capable of industrial research currently only accessible at large installations.
Figure 6.(a) Schematic view of the DiPOLE cryogenically cooled, multi-slab amplifier head[90]. (b) A 3.6 kW diode stack for pumping Yb:YAG pulsed high-energy class solid-state lasers[91].
In collaboration with industry, European laboratories are developing innovative high-power and high-energy laser technologies. The THRILL project, funded by the European Commission for 2023–2026 for 10 M€, involves five countries and aims to develop a kilojoule module with the repetition rate defined by the flash lamp pumping with the possibility to further increase the repetition rate and the wall-plug efficiency in a second stage replacing flashlamps with diodes. Its ambitions are to push the technology of high-energy, HRR lasers to a new level of performance in the context of large physics research infrastructures. Diode-pumped solid-state laser (DPSSL) technologies are under development in several countries: the APOLLON laser system is operating in France, the L3 beamline at ELI and the POLARIS and PENELOPE lasers in Germany. The Central Laser Facility (RAL-STFC) has delivered a kilowatt average power DPSSL system, DiPOLE. The DiPOLE amplifier head contains four ytterbium-doped yttrium aluminium garnet (Yb:YAG) ceramic disks. These disks are pumped from both sides by diode lasers and cooled using a flow of helium gas cooled by liquid nitrogen; see Figure 6(a). More recently, new schemes based on lasing media with broadband amplification and large energy storage, such as thulium-doped crystals[92] or ceramics[93], have been proposed and are being investigated at LLNL and ILIL laboratory at CNR, among the others, and provide an entirely new platform for high-efficiency amplification. Crucial for developing these systems is the availability of efficient and robust diode laser stacks capable of high-duty cycle operation and long lifetime. Europe has an established capability to develop and assemble such light sources for applications that require high output powers with simultaneously high efficiency, such as pump lasers. Diode lasers, that is, single emitters or laser bars, are stacked together to achieve output powers in the kilowatt range, as in the case of the 3.6 kW diode stack developed[94] by the Ferdinand Brown Institute for pumping Yb:YAG solid-state lasers (see Figure 6(a)). These projects share common objectives with the HiPER+ project in terms of laser development.
The main challenges of laser technology for IFE are the average power and the wall-plug efficiency. The design of the lasers used for ICF research – such as OMEGA, LMJ and NIF – dates back to the last century and did not consider these features. Nowadays, the laser industry can produce kilojoule laser beamlines with a repetition rate in the minute range. That is an increase of two orders of magnitude compared to the existing ICF lasers, which opens the way to commercial solutions. Laser technology for high-energy lasers is still far from mature. Significant performance leaps will be seen in the next decade when laser diode pumping becomes kilojoule capable, improving high-energy laser performance in average power and wall-plug efficiency. The transition of high-energy, single pulse lasers to high average power and HRR is a crucial milestone for IFE research. Assuming an improvement of efficiency by a factor larger than 10, as anticipated by theoretical studies and demonstrated on sub-scale prototypes such as DiPOLE, the total energy needed per ignition cycle will still be above 100 kJ, which corresponds to an average laser output power of 100 kW at 1 Hz operation rate. In addition to this outstanding challenge of laser efficiency and robustness, special temporal and spatial laser pulse shape requirements are to be fulfilled. The laser architecture should also allow a maintenance scheme for 24/7 operation.
The transition from a proof-of-principle demonstration of ignition of fusion reactions at the NIF to the repetitive operation required in a future reactor is at the core of this IFE project. Technical specifications for IFE lasers are extremely challenging, but these technological developments are largely overlapping with other needs for industrial applications. Actually, two complementary strategies are pursued in laser technology development: a kilojoule module with flash lamp pumping and with a repetition rate on the 1 minute scale and a DPSSL module with a repetition rate on the few Hz scale and with pulse energy in the hundred joules range. There are no doubts that innovative and ground-breaking solutions in laser technology will emerge soon, permitting one to combine these approaches and bring them to the level needed for IFE plant construction. The European laser industry is sufficiently mature today to take on the construction of such a modern multi-beam, high-energy and HRR laser facility. An ambitious IFE programme will play a driving role by setting the laser specifications of interest for other high-tech applications.
3.6 Reactor technology developments
The history of the development of reactor designs in Europe comes from the 1980s[95,96]. A significant European contribution, HIBALL and HIBALL-II, was developed for a heavy ion-driven IFE facility, contemporary to several similar projects in the United States, including lasers and X-rays. Some of the proposed solutions, such as the INPORT concept of using porous, flexible tubes of woven C or SiC fibres to contain liquid metals inside the vacuum chamber of an ICF system[97], are of interest now, not only in inertial fusion but also considered as a solution for a magnetic fusion divertor. IFE reactor designs have been significantly extended in the United States and Japan since the 1970s in collaboration with European groups on specific research subjects. From those computationally developed ideas, key IFE concepts emerged that enable first-wall protections in IFE: thick liquid jets[98,99], thin liquid[95,100–102] and gas protections[21,103] have been studied and in some cases also experimentally proved. The neutronic fluxes/fluences and their corresponding responses (heating, tritium breeding, damage, activation) in the blanket and final protection have been extensively studied over many years[104,105], but also with more extensive and detailed numerical computations[106,107]. Extraordinary new advanced models for determination of the activation and safety in 3D extremely detailed geometry, with advanced variance reduction techniques, have been developed in the last few years[108–110]. However, the conclusions concerning neutron-irradiated materials are waiting for experimental proof. These studies need coordination with similar research in magnetic confinement fusion and further studies for the specific IFE conditions of pulsed irradiation.
HiPER marked a significant European step towards designing a power plant prototype with direct-drive laser irradiation. The project has finished with a realistic computational design of the reactor systems, including the chamber dimensional layout, the first wall and blanket design with cooling systems and the neutron management, damage and activation assessment and safety considerations[111–113]. Significant progress in the multidisciplinary science of materials at extreme conditions driven by the HiPER project[10,23] has enabled improvements in laser optics and structural materials, the key parts of the IFE chamber. After HiPER, more of the national research was dedicated to a better understanding of optical materials under extreme irradiation conditions[114–116], including basic theory and proposal of optical materials[117–119]; tritium breeding optimization[120] and its retention assessment; control of irradiation conditions of the first wall[121] and its material resistance to charged particles and X-rays[122,123]; blanket material damage and liquid metal corrosion, including research on coatings[124–126]; determination of neutron activation to establish the responses to thermo-fluid dynamics for the cooling and energy recovery systems. Beyond the ignition demonstration, three operation modes for the IFE facility were considered in HiPER: (i) a burst mode demonstrating some critical elements of the future power plant, such as repetitive laser shots, target injection and debris mitigation and management; (ii) a prototype of the fusion reactor with a blanket and heat exchanger for the energy recovery and tritium breeding studies; and (iii) a demo power plant with the fuel breeding and electricity generation for the optimization and commercialization of the IFE technology. This strategy can be reduced to two steps, (i) and (iii), thus reducing the overall time of the HiPER+ project. A chamber for goal (i) is the first affordable requirement to build a repetitive experimental facility, together with advances in power plant research (iii).
Improving the damage resistance and the development of optics refurbishing technologies are indispensable parts of the IFE technical background, which are also needed for promoting the insertion of lasers in the industry. Indeed, the development of radiation and neutron-resistant materials is a subject of common interest for any fusion energy project. It could act as an incubator of innovative solutions indispensable for a future power plant and for driving industrial development in other areas.
3.7 Targetry
One of the critical points that allowed the remarkable 2022 NIF results was the extremely high quality of the produced capsule. The future of IFE advancement towards an energy reactor needs to deal with the high-importance and delicate issues of the development of target mass fabrication, improvement of the target quality and metrology and target injection technologies. They will be in the scope of the IFE projects and will also benefit other industrial applications. Target fabrication is under permanent development because of new challenges not only linked to ICF/IFE but also to other science experiments on high-energy-density physics at X-ray radiation facilities such as ELI, XFEL and ESRF. The international situation is favourable for IFE, with target laboratories in the United States (General Atomics, LLE, LLNL), Japan (Institute Laser Engineering, Osaka) and China.
Europe contributed to developments in this area with the HiPER project, promoting collaboration among European groups with expertise in materials and targetry. More recently, such cooperation has been maintained[127,128] and further expanded through Laserlab Europe AISBL, that is acting as a coordinator and launcher of new initiatives, such as the expert groups on laser-driven inertial confinement fusion (ICF) - inertial fusion energy (IFE)[129] and on micro- and nano-structured materials for experiments with high-power lasers[130].
The critical point is that the requirements for the target quality, the cost and the materials are compatible with the technologies already developed in the industry. It is clear that their cost needs to be a small fraction of the energy value per target, so of the order of centimes of the euro. At the same time, the repetition rate needs to be in the range of 5–10 Hz, the target surface quality needs to be in the range of 10–100 nm and a precision of 10 μm is required. Mass-produced, cost-effective target configurations have to be pursued, an objective that can also be potentially achieved with low-density structured materials[52,54] (see Figure 5). In particular, the recent achievements in the micro-lithography and mass production of microchips share many technological requirements with IFE. They will provide a solid reference point for future IFE technologies.
Low-density micro-structured materials, also known as foams, have been studied for a long time[131–133]. The ability to smooth the laser inhomogeneities by distributing the laser energy inspired new schemes for ICF[132] and has been confirmed experimentally[77,134,135]. Foams have found many more applications over the decades, as neutron sources[136], as pressure amplifiers for equation-of-state studies[137] for extremely bright electron and X-
Foams have a wide variety of parameters, such as density, pore size and shape, wall thickness and constituent elements. They have been traditionally obtained by chemical methods, but nowadays, some can be printed via the two-photon polymerization technique[79,143]. In the near future, this technology could replace the chemical means for their production, overcoming the actual limitations in printing speed and price. The non-trivial internal structure of foams poses severe challenges for hydrodynamic simulation since it cannot be directly resolved in the codes and modelling them as homogeneous media of the same average density commonly fails when directly irradiated by the laser[135,144], but they seem to be suitable when a foam with specific features is not directly exposed to the laser[145,146]. Some reduced models for the interaction of high-power lasers with foams have been developed over the years and implemented in hydrocodes[78,147–149], but a lot of work remains to solve the problem fully.
3.8 Diagnostics
A large-scale IFE demonstrator can only be successful if a significant effort of the project is put into fusion-relevant diagnostics[150–154]. They are required to characterize fusion products, the plasma and capsule evolution over time and the electromagnetic and particle radiation emitted. Over the last two decades, the US laboratories have acquired extensive experience in the field, such that methods and devices have been developed, fielded and tested. These are points of high technological importance in the path of improvement necessary for new IFE projects.
A central point for HiPER+ is the combination of driver lasers with laser backlighting capabilities from the early stage of the project. This technique, requiring laser beams of kilojoule energy and picosecond duration, has shown an invaluable advantage for generating ICF data indispensable for the target design, wherever it has been implemented[16,51]. Having a short-pulse capability on HiPER+ not only fosters diagnostics but also enables testing of the fast ignition schemes[7] that require short-pulse capability, particularly the proton fast ignition. This will also be the basis of future ultra-short laser-driven neutron sources[155,156] to couple with the existing neutron source IFMIF-DONES currently under construction in Granada, Spain.
Diagnostics of the LPIs and the emitted wideband radiations, due to the strong interdisciplinary research required, are the subject where different fields of physics can find a common denominator and then collaborate and exchange knowledge. The diagnostics development effort is also what differentiates HiPER+ from the commercial approaches to IFE, as a large set of diagnostics methods ensures a more in-depth and precise understanding of physics, and it also offers the ideal platform for multidisciplinary education and science dissemination to support the commercial approaches to IFE.
A strong contribution to diagnostic development is expected for the fundamental IFE requirement of running experiments in high-intensity and HRR laser facilities[83,157–164]. Another significant issue is to develop high-sensitivity diagnostics[162,165–169], in an environment heavily polluted with high radiation doses and with laser-generated EMPs of high intensity, as discussed in the next section.
3.9 Safety
General safety, personnel and device/electronic security are indispensable parts of the IFE project. They include reliable and sustainable operation of the laser, diagnostic, control and target injection systems, particularly in the HRR regime and harsh radiation environment[170,171]. In addition, safety must be provided for workers and the public in general against potential radioactive emissions during operation and shutdown[172,173]. Adequate measures must be established with respect to national and European licensing procedures, and this needs to be made also by suitable planning and estimation by numerical evaluations[108–110,174,175]. It is mentioned in Section 3.6 that the high precision and accuracy 3D codes link the computer-aided design (CAD)/computer-aided manufacturing (CAM) description with sophisticated computational models for radiation doses, heating and breeding. The radiation doses can be calculated globally, thus helping to design adequate safety procedures and shielding. The magnetic confinement fusion community also faces similar issues. Security includes data storage, with suitable backup and data handling systems and tailored protected storage spaces for the different users that can access the facility.
The interaction of intense laser pulses with matter generates a broad band of electromagnetic radiation and particles. In particular, very intense electromagnetic fields in the radiofrequency–microwave–terahertz regimes have been measured up to the MV/m order[46]. Their intensity requires suitable countermeasures to get an EMP-resistant laser facility, but in many experiments of laser–matter interactions, it is indeed difficult to reach a sufficient protection level for laboratory personnel and hardware (system electronics and diagnostics). The common approach to reduce EMP-related problems implies the application of electric/electronic hardware shielding and careful interconnection of subsystems and instruments with appropriate protection/filtering. Since the protection cost scales with area, volume, complexity and number of devices to be protected, the complete protection price may be relatively high for a large facility with many electronic devices and instruments.
For this reason, the development of tailored mitigation strategies for laser-generated EMPs is of primary importance for present and future experiments of IFE and laser–plasma acceleration[46,176]. It is well known that these fields scale with laser energy and intensity (see Figure 7). So, for future facilities with improved features, the problem will be even more severe. During recent years, primary sources of these intense fields have been so far identified[176–181]. Still, other sources have been recently observed and investigated, with significant potential for developing high fields[182–185] (see Table 1).
Figure 7.Compilation of the measured amplitudes of EMP signals at different laser installations. The blue and red zones outline the data obtained with ps and ns laser pulses. All data were normalized to the reference distance of 1 m from the source. Values for the ABC, XG-III and LMJ experiments were obtained at distances 0.085, 0.4 and 4 m from the target, respectively. The normalization might produce a field overestimation of a few times (adapted from Ref. [46]).
Field source | Distribution | Max. field | Max. duration | Max. frequency |
---|---|---|---|---|
Neutralization current | Vertical monopolar antenna | |||
Surface-sheath oscillations | Horizontal dipolar antenna | MV/m | Few ps | |
Surface photo-ionization | Surfaces exposed to UV & X | MV/m | ||
Wakefields | Charged particle beams | MV/m | ||
Particles on surfaces | Close to surfaces | MV/m |
Table 1. Characteristics of the identified EMP sources[184].
For direct-drive irradiation schemes (both SI and fast ignition), we can expect these fields to be up to the MV/m level within the experimental chamber. This motivates the present international effort for mitigation strategies of these intense fields for future IFE reactors. The research activity related to EMP sources has a high potential for applications related to the generation of tailored localized magnetic[43] or electric[186] fields of high intensity, or travelling electromagnetic waves[187], that can be applied to advanced ICF configurations and also to a comprehensive multidisciplinary set of different fields, capable of attracting the interest of private companies.
3.10 The ICF community and its competences
The academic community is working in inertial fusion in Europe in close collaboration with national organizations such as CEA in France, UKRI and AWE in the UK, ENEA and CNR in Italy, CIEMAT in Spain and the Helmholtz Association in Germany and with international partners in the United States, Japan and China. European scientists have made ground-breaking contributions to ICF in the theory, numerical developments, experiments, materials and reactor developments. They made important, and often pioneering, contributions to the study of LPIs[4–8], including parametric instabilities[188–191], hot electron production[192–194], transport[195–197], X-ray detection[198], IFE SI and fast ignition target design[7,8,62], diagnostics[7,8,199,200] and targetry[7,8]. Experimental and theoretical studies on laser–foam interactions and applications have been extensively performed[77–79,131–137,139–142,144,146–149,201].
European scientists are taking the lead in high-field physics with short-pulse high-intensity lasers. They developed advanced plasma diagnostics[202] based on laser-driven radiation and particle sources and use them for studying new extreme states of matter[192–194,203–209]. European scientists contribute with new ideas and development to the specific IFE challenges appearing when studying advanced nano-structured materials for the first wall[210,211], analysing the first-wall damage by light species accumulation[122,212–217], developing coatings against corrosion[124–126], studying the neutronic transport, materials activation and damage and proposing an integral layout for IFE reactors. Extensive collaboration is established in this area with programmes on IFE[218] in the United States and Japan, the High Average Power Lasers Program (HAPL) in the United States and with magnetic European fusion in common areas, such as structural materials, cooling and tritium breeding.
EU laboratories and universities have recognized historical experience in the development of advanced diagnostics for the described ICF/IFE scenarios, and in general for laser–matter experiments[83,150,152,157–169]. They are thus capable of supplying a solid base for the innovation steps required for future IFE projects; in particular, for devices and methodologies that have to run on HRR regimes with associated data handling issues and with the requirement of high sensitivity in an environment heavily polluted by radiation and EMPs.
European scientists and engineers are the most active in research activities related to laser-generated EMPs[46], and specifically on studies associated with these sources[176–185], their minimization, diagnostics and the use of these intense fields for multidisciplinary applications[43,186,187]. These activities are coordinated through the recently established Laserlab Europe AISBL expert group on laser-generated electromagnetic pulses[219].
Several laser facilities at the kJ energy level operate in France (LULI2000), Germany (PHELIX), the Czech Republic (PALS, L4n[220]) and the UK (Vulcan). Smaller facilities, such as the Italian ABC laser at the 200 J energy level, exist and can allow some basic IFE laser–target interaction studies and diagnostics test-beds. The three ELI pillars in the Czech Republic, Hungary and Romania are joining as the European institution ELI ERIC[11]. Europe is also the worldwide leader in high-power laser facilities with several petawatt class lasers at the tens of joule energy level operating in France (Apollon), Spain (CLPU)[221–223] and Germany (DRACO). However, there are only two multi-beam multi-kJ laser facilities in Europe: Orion in the UK, operated by AWE, and LMJ-PETAL, operated by CEA, with limited academic access. (It has been a recent announcement by UKRI of the funding for the Vulcan 20-20 upgrade due to be operational in 2029 in the UK.) The lack of a research multi-beam, multi-kJ laser facility (like OMEGA in the USA or GEKKO in Japan) has limited the competence of European scientists in critical subjects such as the implosion of spherical targets and hydrodynamic instabilities. The contribution of the European scientific community to ICF for the last 10 years has been mainly related to the basic physics aspects, leaving the integrated approach aside.
Except for the 2006–2013 years of the HiPER project, no pan-European coordinated IFE programmes have existed. IFE-related projects are supported by short-/medium-term competitive low-/medium-level European, national and regional funding[224], which is incompatible with long-term coordinated collaborative projects. Moreover, restrictions connected to the defence commitments in France and the UK complicate the exchange between the academic and government laboratories and the private sector, which is needed to develop high-performance numerical tools indispensable for high-quality research. In contrast, magnetic confinement fusion research and technology development has benefited from the coordination and financial support of the EUROfusion consortium at the international level with a long-term focused programme.
The project HiPER was a turning point that demonstrated the possibility of bringing together the European community beyond national limits within one common research and development project directed to ICF for energy production. Now is the time to restart an IFE project in Europe aiming to construct a joint, entirely civilian, laser fusion research centre at a new level of confidence, with improved laser technologies, high-performance computing and a motivated, high-quality scientific team. A coordinated research programme will be supported by a dedicated educational programme at the master’s and doctoral levels and an exchange programme at the postdoctoral level. Such a programme has been developed within the Erasmus+ programme and tested on a collaboration basis among several European universities[26].
The continuous achievements in IFE science, laser and material technologies and readiness of the laser fusion community provide a strong and valid background for a new European project, demonstrating the feasibility of the commercialization of laser fusion for energy production and paving the way for the development of integrated technologies needed for a demonstration power plant. It will be conducted in close cooperation with European universities and research laboratories, with industry and recently created private companies[225].
4 European roadmap for inertial-fusion energy
The European IFE roadmap was first produced in 2013. It is now outdated and needs to be updated urgently, accounting for significant developments during the last decade and from the contributions of the partner laboratories. Since the number of partners will increase with time, and the commitments and collaborations will evolve with growing support at the national level, the project will gain details, and the timeline will be adjusted correspondingly. In the first version of the IFE roadmap, we put together the main objectives on the long and short time scales. These scientific and technical components are needed for the overall coherence of the project and for achieving the ultimate goal of constructing the demonstrator of an ICF power plant ready for commercialization.
The general overview of the roadmap is presented in Table 2. The subjects are grouped into four primary research and development areas to investigate the physics and technology issues, develop the community and propose and test a power plant ready for commercialization. These areas are detailed in the following sections.
Years 1–10 | Years 11–20 | Years 21–30 | ||
---|---|---|---|---|
R&D IFE | Pilot IFE reactor | DEMO-IFE reactor | ||
A | Physics and technology of IFE. | Achievement of robust ignition. Addressing physics issues, choosing reactor target design. | Optimization of the target performance. Demonstration of reactor operation in burst mode. | Development of IFE operation: improving efficiency, robustness and safety. |
B | Development of IFE laser technology. Construction of IFE laser systems. | Development of broadband DPSSL HRR laser technology. Design of laser module prototype. Optics development. Construction of multi-beam sub-ignition facility. | Design of high-gain laser facility operating in a burst mode. Development of supply chain. Resolving issues related to long-term laser operation. | Optimization of the IFE laser technology. Industrial production of laser modules for the power plant. Design of DEMO-IFE facility. |
C | Material science and reactor technology. | Development of resistant optical materials. Identification of adequate materials for chamber construction and protection. Design of target insertion and tracking system. Development of EMP mitigation strategies. | Development of a laser-based neutron source and material testing. Mass-production target technology. Resolving security and safety issues. Bases for tritium breeding and handling system. | Final layout assembly of tritium and cooling systems and the energy recovery system. Design of the system of material control, replacement and refurbishment. |
D | IFE community building, project management and development. | Development of joint numerical tools, coordination of experimental activities. Personnel training. Collaboration with industry and private companies. | Design of a commercial fusion reactor. Establishing an educational and training system for power plant exploitation. | Integrated approach to the IFE power plant operation. Conception of the full lifetime power plant. Licensing and regulations. |
Table 2. General roadmap of the IFE project.
The overall time scope of the project is estimated to be 30 years, which is divided into three major periods of 10 years each, with a progressive shift of activities from research and development to engineering and technology.
The HiPER+ initiative is organized by setting up a collaboration agreement among the individual researchers, European research laboratories and universities. Several hundred scientists and engineers are working in universities and research institutions today in Europe. We expect their number will increase significantly in the coming years as partner countries and European institutions accept the programme. The project will coordinate joint experiments on high-energy laser facilities, undertake joint training of master’s and doctoral students and prepare proposals for competitive research and development programmes, for example, the application for inserting the European IFE project HiPER+ in the ESFRI roadmap in 2024–2025 based on support at national levels.
4.1 Physics and technology of IFE
4.2 Development of the IFE laser technology and construction of ICF laser systems
4.3 Material science and reactor technology
4.4 IFE community building, project management and development
5 Detailed description of the roadmap
Each roadmap entry is described in more detail in this section with a tentative time scale and partners.
5.1 Physics and technology of IFE
5.2 Development of the IFE laser technology and construction of ICF laser systems
5.3 Material science and reactor technology
5.4 IFE community building, project management and development
European IFE roadmap;
advanced direct-drive schemes;
laser technologies for IFE platforms;
related technology development (targets, diagnostics, etc.);
experiments on existing platforms;
IFE reactor issues (overlap with magnetic fusion technologies);
diversity, training and recruitment.
Erasmus+ mobility tools and actions. Key Action 2 (KA2) ‘Cooperation among Organizations and Institutions’[
Erasmus+ ‘Partnerships for Innovation’ supports projects such as HiPER+ with the ambition of achieving systemic impact at the European level, developing the capacity to deploy the project outcomes at the European scale. It, too, focuses on thematic areas with strategic importance for Europe’s growth, competitiveness and social cohesion, which ideally fits the scope of HiPER+. The following sub-actions full under this type of partnership: (i) alliances for innovation and (ii) forward-looking projects.
Training at the MSc level. Running English-spoken MSc courses earlier developed by HiPER+ partners using the Erasmus curriculum development programme can be adapted to the strategy.
Development of a doctoral school between HiPER+ partners on high-energy-density physics studies. This action will enable training at the doctoral level and reinforce the enlargement of the European community in IFE-related physics and technology. This action can partially be supported by the Erasmus+ tool.
conclusion of cooperation agreements;
collaboration studies in common IFE areas of interest;
laser technologies for IFE platforms;
technology development actions include targetry, diagnostics, large-scale simulations, materials and reactors;
exchange of knowledge where commonly decided;
participation in HiPER+ training activities;
mutual support in lobbying strategies and dissemination activities.
6 Conclusions
The recent achievement of ignition via ICF by lasers paves the way to credible IFE production. This is a historical accomplishment that is boosting research and technology developments worldwide. It is timely to engage in a coordinated programme in Europe aiming to fully demonstrate the viability of IFE in the direct-drive scheme by involving academic institutions, research laboratories, infrastructures and industry. Here, we have outlined a programme based on existing knowledge, instrumental and industrial assets and a strong scientific community. We are confident the proposed programme will attract partners from governmental organizations and the public sector with key contributions and funding. The complexity of fusion energy research needs multiple backgrounds and points of view. We recognize that diversity drives innovation and that motivated participation in the programme is key to this endeavour. We therefore aim to foster international collaboration and research programmes to solve crucial open questions in IFE in a way that is also mindful of participants’ needs to develop and manage their careers. We are committed to adopting both top-down and grassroots approaches to supporting the roadmap initiatives and objectives through the promotion of equality, diversity and inclusivity.
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