SH33D-06
Contextualizing Solar Cycle 24: Report on the Development of a Homogenous Database of Bipolar Active Regions Spanning Four Cycles

Wednesday, 16 December 2015: 14:56
2011 (Moscone West)
Andres Munoz-Jaramillo1,2, Zachary A Werginz3, Michael D DeLuca4, Juan Pablo Vargas-Acosta5, Dana W Longcope1, John W Harvey6, Piet Martens2, Jie Zhang7, Santiago Vargas-Dominguez5, Craig E DeForest8 and Derek A Lamb9, (1)Montana State University, Bozeman, MT, United States, (2)Georgia State University, Atlanta, GA, United States, (3)Saint Norbert College, De Pere, WI, United States, (4)University of Colorado at Boulder, Boulder, CO, United States, (5)Universidad Nacional de Colombia, Bogota, Colombia, (6)Natl Solar Observatory, Tucson, AZ, United States, (7)George Mason Univ, Fairfax, VA, United States, (8)Southwest Research Institute, Boulder, CO, United States, (9)Southwest Research Institute Boulder, Boulder, CO, United States
Abstract:
The solar cycle can be understood as a process that alternates the large-scale magnetic field of the Sun between poloidal and toroidal configurations. Although the process that transitions the solar cycle between toroidal and poloidal phases is still not fully understood, theoretical studies, and observational evidence, suggest that this process is driven by the emergence and decay of bipolar magnetic regions (BMRs) at the photosphere. Furthermore, the emergence of BMRs at the photosphere is the main driver behind solar variability and solar activity in general; making the study of their properties doubly important for heliospheric physics. However, in spite of their critical role, there is still no unified catalog of BMRs spanning multiple instruments and covering the entire period of systematic measurement of the solar magnetic field (i.e. 1975 to present).

In this presentation we discuss an ongoing project to address this deficiency by applying our Bipolar Active Region Detection (BARD) code on full disk magnetograms measured by the 512 (1975-1993) and SPMG (1992-2003) instruments at the Kitt Peak Vacuum Telescope (KPVT), SOHO/MDI (1996-2011) and SDO/HMI (2010-present). First we will discuss the results of our revitalization of 512 and SPMG KPVT data, then we will discuss how our BARD code operates, and finally report the results of our cross-callibration.

The corrected and improved KPVT magnetograms will be made available through the National Solar Observatory (NSO) and Virtual Solar Observatory (VSO), including updated synoptic maps produced by running the corrected KPVT magnetograms though the SOLIS pipeline. The homogeneous active region database will be made public by the end of 2017 once it has reached a satisfactory level of quality and maturity.

The Figure shows all bipolar active regions present in our database (as of Aug 2015) colored according to the sign of their leading polarity. Marker size is indicative of the total active region flux. Anti-Hale regions are shown using solid markers.