A. Gordon Emslie – författare

Few phenomena have stirred the imaginations of solar scientists as much as the explosive energy of solar flares. In The Physics of Solar Flares, first published in 1988, Einar Tandberg-Hanssen and A. Gordon Emslie approach this subject by drawing heavily on experimental data from the Solar Maximum Mission, as well as other ground-based and space-borne instruments. The data are incorporated into many theoretical investigations. The authors put the main emphasis on understanding the underlying physical processes. Starting from the language of physics, the authors guide the reader into the more specialised concepts of solar physics. The book is divided into two main parts: four chapters set the essentials of physics needed to attack the complexities of flare phenomena, and then a further four treat different aspects of the phenomena. This important book is aimed primarily at beginning graduate students who are assumed to have knowledge of basic physics.

This edited volume describes many aspects of current research on solar flares, emphasizing recent progress in understanding their X-ray and gamma-ray emissions.

This edited volume describes many aspects of current research on solar flares, emphasizing recent progress in understanding their X-ray and gamma-ray emissions.

Further, Fourier imaging is hardly intuitive, and extensive validation of the methods was necessary to ensure that they produced images with sufficient accuracy and fidelity for scientific applications. This book summarizes the results of this development of imaging techniques specifically designed for this form of data.

The idea for this text emerged over several years as the authors participated in research projects related to analysis of data from NASA''s RHESSI Small Explorer mission. The data produced over the operational lifetime of this mission inspired many investigations related to a specific science question: the when, where, and how of electron acceleration during solar flares in the stressed magnetic environment of the active Sun.A vital key to unlocking this science problem is the ability to produce high-quality images of hard X-rays produced by bremsstrahlung radiation from electrons accelerated during a solar flare. The only practical way to do this within the technological and budgetary limitations of the RHESSI era was to opt for indirect modalities in which imaging information is encoded as a set of two-dimensional spatial Fourier components. Radio astronomers had employed Fourier imaging for many years. However, differentlythan for radio astronomy, X-ray images produced by RHESSI had to be constructed from a very limited number of sparsely distributed and very noisy Fourier components. Further, Fourier imaging is hardly intuitive, and extensive validation of the methods was necessary to ensure that they produced images with sufficient accuracy and fidelity for scientific applications.This book summarizes the results of this development of imaging techniques specifically designed for this form of data. It covers a set of published works that span over two decades, during which various imaging methods were introduced, validated, and applied to observations. Also considering that a new Fourier-based telescope, STIX, is now entering its nominal phase on-board the ESA Solar Orbiter, it became more and more apparent to the authors that it would be a good idea to put together a compendium of these imaging methods and their applications. Hence the book you are now reading.