ACADEMIA
Germany's HZDR extends the QMC method to gain insights into planets, stars
Using a simulation method based on random numbers scientists were able to describe the properties of warm dense hydrogen as accurately as never before
Finding out the properties of quantum systems that are made of many interacting particles is still a huge challenge. While the underlying mathematical equations are long known, they are too complex to be solved in practice. Breaking that barrier most probably would lead to a plethora of new findings and applications in physics, chemistry, and the material sciences. Researchers at the Center for Advanced Systems Understanding (CASUS) at Helmholtz-Zentrum Dresden-Rossendorf (HZDR) have now taken a major step forward by describing so-called warm dense hydrogen – hydrogen under extreme conditions like high pressures – as accurately as never before. The scientists’ approach, based on a method that puts random numbers to use, can for the first time solve the fundamental quantum dynamics of the electrons when many hydrogen atoms interact under conditions usually found in planet interiors or fusion reactors (Physical Review Letters, DOI: 10.1103/PhysRevLett.129.066402).
Hydrogen is the most abundant element in the universe. It is the fuel that powers the stars including our sun and it constitutes the interior of planets like our solar system’s gas giant Jupiter. The most common form of hydrogen in the universe is not the color- and odorless gas nor the hydrogen-containing molecules like water that are well-known on earth. It is the warm dense hydrogen of stars and planets – extremely compressed hydrogen that is in certain cases even conducting electricity as metals do. Warm dense matter research studies matter under conditions such as very high temperatures or pressures commonly found everywhere in the universe except for the surface of the earth where they do not occur naturally.
Simulation methods and their limits
In trying to elucidate the characteristics of hydrogen and other matter under extreme conditions, scientists heavily rely on simulations. A widely used one is called density functional theory (DFT). Despite its success, it has fallen short to describe warm dense hydrogen. The main reason is that correct simulations require precise knowledge of the interaction of electrons in warm dense hydrogen. But this knowledge is missing and scientists still have to rely on approximations of this interaction, leading to incorrect simulation results. Due to this knowledge gap, it is not possible, for example, to simulate the heat-up phase of inertial confinement fusion (ICF) reactions correctly. Removing this roadblock could significantly advance ICF, one of two major branches of fusion energy research, to become a much-needed zero-carbon power generation technology.
In the new publication, lead author Maximilian Böhme, Dr. Zhandos Moldabekov, Young Investigator Group Leader Dr. Tobias Dornheim (all CASUS-HZDR), and Dr. Jan Vorberger (Institute of Radiation Physics-HZDR) showed for the first time that properties of warm dense hydrogen can be described very precisely with so-called Quantum Monte Carlo (QMC) simulations. “What we did was to extend a QMC method called path-integral Monte-Carlo (PIMC) to simulate the static electronic density response of warm dense hydrogen,” says Böhme who is pursuing a doctorate with his work at CASUS. “Our method does not rely on the approximations previous approaches suffered from. It instead directly computes the fundamental quantum dynamics and therefore is very precise. When it comes to scale, however, our approach has its limits as it is computationally intense. Even though relying on the largest supercomputers, we so far can only handle particle numbers in the double-digit range.”
Higher scales – and still precise
The implications of the new method could be far-ranging: Combining PIMC and DFT cleverly could result in benefiting both from the accuracy of the PIMC method and the speed and versatility of the DFT method – the latter one being by far less computationally intense. “So far scientists were poking around in the fog to find reliable approximations for electron correlations in their DFT simulations,” says Dornheim. “Using the PIMC results for very few particles as a reference they now can tune the settings of their DFT simulations until the DFT results match the PIMC results. With the improved DFT simulations, we should be able to yield exact results in systems of hundreds to even thousands of particles.”
Adapting this approach, scientists could significantly enhance DFT which will result in improved simulations of the behavior of any kind of matter or material. In fundamental research, it will allow predictive simulations that experimental physicists need to compare to their experimental findings from large-scale infrastructures like the European X-Ray Free-Electron Laser Facility (European XFEL) near Hamburg (Germany), the Linac Coherent Light Source (LCLS) at the National Accelerator Laboratory in Menlo Park or the National Ignition Facility (NIF) at Lawrence Livermore National Laboratory in Livermore (both USA).
Speaking more specifically about hydrogen, the work of Böhme and his colleagues could potentially contribute to nailing down the details of how warm dense hydrogen becomes metallic hydrogen, a new phase of hydrogen studied intensively both by experiments and simulations. Generating metallic hydrogen experimentally in the lab could enable very interesting applications in the future.