Ciencias

Turbulencia de plasma de fusión en movimiento de alta velocidad descubierta por primera vez en el mundo

Dispositivo helicoidal grande (LHD)

Dentro del stellarator de dispositivo helicoidal grande (LHD) de Japón, construido para probar el confinamiento de fusión de plasma. Crédito: Justin Ruckman

Nuevos conocimientos sobre la comprensión de la turbulencia en los plasmas de fusión.

Para lograr la fusión en una planta, es necesario confinar de manera estable un[{» attribute=»»>plasma of more than 100 million degrees Celsius in a magnetic field and maintain it for a long time.

A research group led by Assistant Professor Naoki Kenmochi, Professor Katsumi Ida, and Associate Professor Tokihiko Tokuzawa of the National Institute for Fusion Science (NIFS), National Institutes of Natural Sciences (NINS), Japan, using measuring instruments developed independently and with the cooperation of Professor Daniel J. den Hartog of the University of Wisconsin, USA, discovered for the first time in the world that turbulence moves faster than heat when heat escapes in plasmas in the Large Helical Device (LHD). One characteristic of this turbulence makes it possible to predict changes in plasma temperature, and it is expected that observation of turbulence will lead to the development of a method for real-time control of plasma temperature in the future.

Turbulence and Heat Movement Barrier

Left: Forming a barrier in the plasma to confirm heat inside. Right: By breaking the barrier, turbulence was discovered that moves faster than the heat, as the heat escapes from inside the plasma. Credit: National Institute for Fusion Science

In high-temperature plasma confined by the magnetic field, “turbulence,” which is a flow with vortexes of various sizes, is generated. This turbulence causes the plasma to be disturbed, and the heat from the confined plasma flows outward, resulting in a drop in plasma temperature. To solve this problem, it is necessary to understand the characteristics of heat and turbulence in plasma. However, the turbulence in plasmas is so complex that we have not yet achieved a full understanding of it. In particular, how the generated turbulence moves in the plasma is not well understood, because it requires instruments that can measure the time evolution of minute turbulence with high sensitivity and extremely high spatiotemporal resolution.

A “barrier” can form in the plasma, which acts to block the transport of heat from the center outward. The barrier makes a strong pressure gradient in the plasma and generates turbulence. Assistant Professor Kenmochi and his research group have developed a method to break this barrier by devising a magnetic field structure. This method allows us to focus on the heat and turbulence that flow vigorously as the barriers break, and to study their relationship in detail. Then, using electromagnetic waves of various wavelengths, we measured the changing temperature and heat flow of electrons and millimeter-sized fine turbulence with the world’s highest level of accuracy. Previously, heat and turbulence had been known to move almost simultaneously at a speed of 5,000 kilometers per hour (3,100 miles per hour), about the speed of an airplane, but this experiment led to the world’s first discovery of turbulence moving ahead of heat at a speed of 40,000 kilometers per hour (25,000 miles per hour). The speed of this turbulence is close to that of a rocket.

Assistant Professor Naoki Kenmochi said, “This research has dramatically advanced our understanding of turbulence in fusion plasmas. The new characteristic of turbulence, that it moves much faster than heat in a plasma, indicates that we may be able to predict plasma temperature changes by observing predictive turbulence. In the future, based on this, we expect to develop methods to control plasma temperatures in real-time.”

Reference: “Preceding propagation of turbulence pulses at avalanche events in a magnetically confined plasma” by N. Kenmochi, K. Ida, T. Tokuzawa, R. Yasuhara, H. Funaba, H. Uehara, D. J. Den Hartog, I. Yamada, M. Yoshinuma, Y. Takemura and H. Igami, 16 May 2022, Scientific Reports.
DOI: 10.1038/s41598-022-10499-z

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