Abstract
Abstract Synthetic intensity maps are generated from a 3D kink-unstable flux rope simulation using several DKIST/DL-NIRSP spectral lines to make a prediction of the observational signatures of energy transport and release. The reconstructed large field-of-view intensity mosaics and single tile sit-and-stare high-cadence image sequences show detailed, fine-scale structure and exhibit signatures of wave propagation, redistribution of heat, flows, and fine-scale bursts. These fine-scale bursts are present in the synthetic Doppler velocity maps and can be interpreted as evidence for small-scale magnetic reconnection at the loop boundary. The spectral lines reveal the different thermodynamic structures of the loop, with the hotter lines showing the loop interior and braiding and the cooler lines showing the radial edges of the loop. The synthetic observations of DL-NIRSP are found to preserve the radial expansion, and hence the loop radius can be measured accurately. The electron number density can be estimated using the intensity ratio of the Fe xiii lines at 10747 and 10798 Å. The estimated density from this ratio is correct to within ±10% during the later phases of the evolution; however, it is less accurate initially when line-of-sight density inhomogeneities contribute to the Fe xiii intensity, resulting in an overprediction of the density by ≈30%. The identified signatures are all above a conservative estimate for instrument noise and therefore will be detectable. In summary, we have used forward modeling to demonstrate that the coronal off-limb mode of DKIST/DL-NIRSP will be able to detect multiple independent signatures of a kink-unstable loop and observe small-scale transient features including loop braiding/twisting and small-scale reconnection events occurring at the radial edge of the loop.
Highlights
One mechanism capable of producing the high temperatures observed in the solar corona is nanoflares, where a cascade of reconnection events releases magnetic energy, leading to heating (Parker 1988)
Synthetic intensity maps are generated from a 3D kink-unstable flux rope simulation using several Daniel K. Inouye Solar Telescope (DKIST)/DL-NIRSP spectral lines to make a prediction of the observational signatures of energy transport and release
We have used forward modelling to demonstrate that the coronal off-limb mode of DKIST/DL-NIRSP will be able to detect multiple independent signatures of a kink-unstable loop and observe small-scale transient features including loop braiding/twisting and small-scale reconnection events occurring at the radial edge of the loop
Summary
One mechanism capable of producing the high temperatures observed in the solar corona is nanoflares, where a cascade of reconnection events releases magnetic energy, leading to heating (Parker 1988). Such heating events are assumed to be the result of reconnection occurring in tangled or twisted magnetic fields Twisted flux can emerge from below the photosphere (Ishii et al 1998; Cheung & Isobe 2014; Takasao et al 2015) These twisted magnetic structures are susceptible to instabilities, such as the kink instability, whereby magnetic energy is released creating pressure gradients, flows and local temperature increases. We consider the observational signatures of energy transport from a simulation of a kink-unstable flux rope via forward modelling using the off-limb coronal mode of the forthcoming DKIST/DL-NIRSP instrument
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