Observations of the Sept. 10, 2017, solar flare and the standard solar flare model. Left: Observations in extreme ultraviolet (grayscale background) and microwave (red to blue indicate increasing frequencies). Light orange curves are selected magnetic field lines from the matching theoretical model. Right: Numerical simulation of the flare. The reconnection current sheet is shown as the thin orange-purple feature located between the erupting magnetic flux rope and the flare arcade. Microwave sources from relativistic electrons are observed to fill the entire region surrounding the current sheet. Credit: NJIT-CSTR, B. Chen, S. Yu; CfA, C. Shen; Solar Dynamics Observatory. Low Resolution (jpg)
Observation of a large solar flare on Sept. 10, 2017 in extreme ultraviolet (grayscale background, by NASA's Solar Dynamics Observatory) and microwaves (red to blue indicate increasing frequencies, observed by the Expanded Owens Valley Solar Array). Light orange curves are selected magnetic field lines from the matching theoretical solar eruptive flare model. The flare is driven by the eruption of a twisted magnetic flux rope (illustrated by a bundle of color curves threading the dark cavity). Microwave sources are observed throughout the region below the cavity where a large-scale reconnection current sheet — the flare's "central engine" — is located, providing crucial measurements for its physical properties. Credit: NJIT-CSTR, B. Chen, S. Yu; NASA Solar Dynamics Observatory. High Resolution (jpg) - Low Resolution (jpg)
According to the study—which closely examined a large solar flare accompanied by a powerful eruption captured on September 10, 2017, by the NJI's Owens Valley Solar Array (EOVSA), at microwaves—the intense energy powering the flare is the result of an enormous electric current "sheet" stretching more than 40,000 kilometers—greater than the length of three Earths placed side-by-side—through the core flaring region, where opposing magnetic field lines approach, break, and reconnect.
"During large eruptions on the Sun, particles such as electrons can get accelerated to high energies," said Kathy Reeves, astrophysicist, CfA, and co-author on the study. "How exactly this happens is not clearly understood, but it is thought to be related to the Sun's magnetic field." Bin Chen, professor of physics at NJIT and lead author on the study added, “It has long been suggested that the sudden release of magnetic energy through the reconnection current sheet is responsible for these major eruptions, yet there has been no measurement of its magnetic properties. With this study, we’ve finally measured the details of the magnetic field of a current sheet for the first time, giving us a new understanding of the central engine of the Sun’s solar flares."
Measurements taken during the study also indicate a magnetic, bottle-like structure located at the top of the flare's loop-shaped base, or flare arcade, at a height of nearly 20,000 kilometers above the surface of the Sun. The study suggests that this is the primary site where a solar flare’s highly energetic electrons are trapped and accelerated to nearly the speed of light.
"We found that there were a lot of accelerated particles just above the bright, flaring loops," said Reeves. "The microwaves, coupled with modeling, tells us there is a minimum in the magnetic field at the location where we see the most accelerated particles, and a strong magnetic field in the linear, sheet-like structure further above the loops."
The sheet-like structure and the loops seem to be working in concert, with significant magnetic energy being pumped into the current sheet at an estimated rate of 10-100 billion trillion joules per second, and 99% of the flare’s relativistic electrons were observed congregating at the magnetic bottle. "While the current sheet seems to be the place where the energy is released to get the ball rolling, most of the electron acceleration appears to be occurring in this other location, the magnetic bottle," said Dale Gary, director, EOVSA and co-author on the study. "Others have proposed such a structure in solar flares before, but we can truly see it now in the numbers." Chen added, "What our data showed was a special location at the bottom of the current sheet—the magnetic bottle—appears to be crucial in producing or confining the relativistic electrons."
The study results were achieved through a combination of microwave observations from EOVSA and extreme ultra-violet imaging observations from the Smithsonian Astrophysical Observatory's Atmospheric Imaging Assembly on the Solar Dynamics Observatory (SDO). The observations were combined with analytical and numerical modeling—based on a 1990s theoretical model of solar flare physics—to help scientists understand the structure of the magnetic field during a large solar eruption.
"Our model was used for computing the physics of the magnetic forces during this eruption, which manifests as a highly twisted 'rope' of magnetic field lines, or magnetic flux rope," said Reeves. "It is remarkable that this complicated process can be captured by a straightforward analytical model, and that the predicted and measured magnetic fields match so well."
Performed by Chengcai Shen, astrophysicist, CfA, the simulations allowed the team to resolve the thin reconnection current sheet and capture it in detail. "Our simulation results match both the theoretical prediction on magnetic field configuration during a solar eruption and reproduce a set of observable features from this particular flare, including magnetic strength and plasma inflow/outflows around the reconnecting current sheet," said Shen. “It is a powerful tool to compare theoretical expectations and observations in detail."
For the team, the study provides answers to long-unanswered questions about the Sun and its solar flares. "The place where all the energy is stored and released in solar flares has been invisible until now," said Gary. "To play on a term from cosmology, it is the Sun's 'dark energy problem,' and previously we’ve had to infer indirectly that the flare's magnetic reconnection sheet existed." For solar physics, the measurements represent a better understanding of the Sun, as well as providing a path to revealing the truth behind the current sheet, and the magnetic bottle and its role in particle acceleration. According to Chen, "There are certainly huge prospects out there for us to study that address these fundamental questions."
The current study builds on the team’s quantitative measurements of the evolving magnetic field strength directly follow a solar flare's ignition, published in Science earlier this year.
About Center for Astrophysics | Harvard & Smithsonian
Headquartered in Cambridge, Mass., the Center for Astrophysics | Harvard & Smithsonian (CfA) is a collaboration between the Smithsonian Astrophysical Observatory and the Harvard College Observatory. CfA scientists, organized into six research divisions, study the origin, evolution and ultimate fate of the universe.
For more information, contact:
Amy Oliver
Public Affairs
Center for Astrophysics | Harvard & Smithsonian
Fred Lawrence Whipple Observatory
520-879-4406
amy.oliver@cfa.harvard.edu
Source: Harvard-Smithsonian Center for Astrophysics (CfA)