Calculating one billion plasma particles in a supercomputer

Research Results

Dr. Hiroki Hasegawa and Dr. Seiji Ishiguro, at the National Institute of Fusion Science, using the NIFS Plasma Simulator supercomputer succeeded for the first time in the world in conducting a micro-level simulation of a plasma blob in the "edge region" of the plasma. The Plasma Simulator has the greatest capacity in the world as a supercomputer dedicated to plasma and fusion science use. Here, in addition to newly developing a calculation program by utilizing the Plasma Simulator's capacity, they also were able to calculate the movements of one billion particles. When calculating plasmas of the same size, the number of calculations exceeded 10,000 in comparison with the method used heretofore for calculating the blob's particles as if they were a unit.

According to this simulation, finely detailed analyses that incorporated the influence mutually provided by the movement of particles and the electrical field, which had not been possible in methods used to date, became possible. Further, at the same time as we pursue the movements of a string-like plasma blob from the particle level, we were able to clarify the micro-level internal structure of particle movements inside the plasma and the temperature distribution. By understanding this type of internal structure, it became possible to investigate the influence of that internal structure upon the movement of a plasma blob. Moreover, we clarified the condition in which a plasma blob carries impurities.

These research results, together with greatly advancing understanding of the behavior of a plasma blob, have greatly improved prediction accuracy. These research results were reported at the 26th International Atomic Energy Association (IAEA) Fusion Energy Conference held in Kyoto, Japan from October 17-22, 2016. The results have also been highly evaluated, and later were presented as an invited lecture at the thirty-third annual meeting of The Japan Society of Plasma and Nuclear Fusion Research in Sendai, Japan, held from November 29 to December 2, 2016, where the research results also garnered much attention.

Vocabulary

1. Simulation from the micro-level

Through a simulation based on a fluid model where we understand a plasma as a whole, we can know the general behavior of a plasma through a small number of calculations. However, we cannot replicate the phenomenon that is caused by the movement of plasma particles. From the movements of all individual particles that comprise a plasma and the method for calculating the electrical field that is produced by those particles (simulation from the micro-level) we can trace the plasma's general behavior. This is compared to the following. We construct a simulation in which we follow all of the monetary transactions of every citizen in a country of one billion people. Then we can grasp the flow of money throughout the country. However, an immense amount of calculations are required.

2. Impurities

In the edge region, for various reasons impurities are generated (other than hydrogen such as carbon, oxygen, iron, and others), and when impurities enter the core plasma, the problem of the falling plasma temperature emerges. Understanding the behavior of these impurities and accurately predicting their behaviors, too, is one of the important issues in achieving fusion energy.

3. Velocity distribution

Particles, which are composed of gases such as air, and plasmas have different velocities as they fly about. Depicting the velocity of the particles on the horizontal axis and the number of particles at that velocity on the vertical axis shows the velocity distribution. The width of the velocity distribution represents the temperature. This indicates that the broader is the width the higher is the temperature.