Indonesia harus mampu mengembangkan sains dan teknologi yang ramah lingkungan sesuai dengan perkembangannya di tanah air, tanpa teknologi yang boros sumber alam dan energi.
Hal yang penting juga ialah memahami dan menghayati filsafat sains untuk bisa menyatakan kebenaran ilmiah dan bisa membedakannya dengan "kebenaran" yang diperoleh dengan cara lain.
The Houw Liong
http://LinkedIn.com/in/houwliong
24 April 2009
ON THE STRUCTURE AND EVOLUTION OF COMPLEXITY IN SIGMOIDS: A FLUX EMERGENCE MODEL
ON THE STRUCTURE AND EVOLUTION OF COMPLEXITY IN SIGMOIDS: A FLUX EMERGENCE MODEL
V. Archontis et al 2009 ApJ 691 1276-1291 doi: 10.1088/0004-637X/691/2/1276
V. Archontis1, A. W. Hood1, A. Savcheva2, L. Golub2 and E. Deluca2
1 School of Mathematics and Statistics, University of St. Andrews, North Haugh, St. Andrews, Fife KY16 9SS, UK
2 Harvard-Smithsonian Center for Astrophysics, 60 Garden Street, Cambridge, MA 02139, USA
ABSTRACT. Sigmoids are structures with a forward or inverse S-shape, generally observed in the solar corona in soft X-ray emission. It is believed that the appearance of a sigmoid in an active region is an important factor in eruptive activity. The association of sigmoids with dynamic phenomena such as flares and coronal mass ejections (CMEs) make the study of sigmoids important. Recent observations of a coronal sigmoid, obtained with the X-Ray Telescope (XRT) on board Hinode, showed the formation and eruption phase with high spatial resolution. These observations revealed that the topological structure of the sigmoid is complex: it consists of many differently oriented loops that all together form two opposite J-like bundles or an overall S-shaped structure. A series of theoretical and numerical models have been proposed, over the past years, to explain the nature of sigmoids but there is no explanation on how the aforementioned complexity in sigmoids is built up. In this paper, we present a flux emergence model that leads to the formation of a sigmoid, whose structure and evolution of complexity are in good qualitative agreement with the recent observations. For the initial state of the experiment a twisted flux tube is placed below the photosphere. A density deficit along the axis of the tube makes the system buoyant in the middle and it adopts an Ω-shape as it rises toward the outer atmosphere. During the evolution of the system, expanding field lines that touch the photosphere at bald-patches (BPs) form two seperatrix surfaces where dissipation is enhanced and current sheets are formed. Originally, each of the BP seperatrix surfaces has a J-like shape. Each one of the J's consist of reconnected field lines with different shapes and different relative orientation. The further dynamical evolution of the emerging flux tube results in the occurrence of many sites that resemble rotational discontinuities. Thus, additional current layers are formed inside the rising magnetized volume increasing the complexity of the system. The reconnected field lines along these layers form an overall S-shaped structure. The reconnection process continues to occur leading to the formation of another current concentration in the middle of the sigmoid where a flaring episode occurs. This central brightening is accompanied by the eruption of a flux rope from the central area of the sigmoid and the appearance of "post-flare" loops underneath the current structure.
Key words: MHD; Sun: activity; Sun: corona; Sun: magnetic fields
Print publication: Issue 2 (2009 February 1)
Received 2008 August 13, accepted for publication 2008 October 1
Published 2009 February 2
The Astrophysical Journal, 691:1276–1291, 2009 February 1 doi:10.1088/0004-637X/691/2/1276
American Astronomical Society. All rights reserved. Printed in the U.S.A.
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