Knowledge about the ionospheric response to the geomagnetic storms is needed to support SWIFtS activity in Space Science Center-LAPAN. However, it is difficult to predict its behavior. As an approach, it needs a model of the ionospheric response to geomagnetic storms. In this paper, the modeling of the Indonesia ionospheric storms to the geomagnetic storm was done by modifying the global empirical models developed by Araujo-Pradere. By using ap index data, Dst index, and foF2 ionosphere from BPAA Sumedang of 2005-2015, it was obtained the Indonesia ionospheric storms model related to the geomagnetic storm. The analysis result showed that the Sumedang ionospheric storms model had a deviation or error < 40% of the data. Therefore it can be concluded that this models can be used to support the SWIFtS activity in Space Science Center-LAPAN for future space weather conditions.

 

 

Abstrak

Pengetahuan tentang respon ionosfer terhadap badai geomagnet sangat diperlukan untuk mendukung kegiatan SWIFtS di Pusat Sains Antariksa-LAPAN. Namun, sulit diprediksi perilakunya. Sebagai pendekatan, diperlukan sebuah model respon ionosfer terhadap badai geomagnet. Dalam makalah ini, dilakukan pemodelan badai ionosfer Indonesia terkait badai geomagnet dengan memodifikasi model empiris global yang telah dikembangkan oleh Araujo-Pradere. Dengan menggunakan data indeks ap, indeks Dst dan foF2 ionosfer BPAA Sumedang tahun 2005-2015 diperoleh model badai ionosfer regional Indonesia terhadap badai geomagnet. Dari analisis disimpulkan bahwa model badai ionosfer Sumedang tersebut memiliki simpangan atau kesalahan < 40% terhadap data. Hal ini menunjukkan bahwa model badai ionosfer Sumedang tersebut dapat dipergunakan untuk mendukung kegiatan SWIFtS di Pusat Sains Antariksa-LAPAN sebagai bahan pertimbangan dalam memprediksi kondisi cuaca antariksa akan datang. 

 

 

respon foF2 ionosfer; badai geomagnet; model badai ionosfer Sumedang; foF2 ionospheric response; geomagnetic storm; Indonesia ionospheric storm model

Abdu, M.A., Sobral, J.H.A., Paula, E.R., Batista, I.S., 1991. Magnetospheric Disturbance Effects on the Equatorial Ionization Anomaly (EIA): an Overview. Journal of Atmospheric and Solar-Terrestrial Physics 53, 757–771.

Araujo-Pradere, E. A., and T. J., Fuller-Rowell, 2000. A Model of a Perturbed Ionosphere Using the Auroral Power as the Input, Geofis. Int., 39(1), 29–36.

Araujo-Pradere E. A., Fuller-Rowell T. J., and Codrescu M. V., 2002. STORM: An Empirical Storm-Time Ionospheric Correction Model, RADIO SCIENCE, VOL. 37, NO. 0, 10.1029/2001RS002467.

Bilitza, D., 1990. International Reference Ionosphere 1990, http://www.ngdc. noaa.gov/wdc/webbook/wdca/wdca_rockets. html, Natl. Space Sci. Data Cent., World Data Cent. A for Rockets and Satellites, Greenbelt, Md.

Bilitza, D., 2001. International Reference Ionosphere 2000, Radio Sci., 36(2), 261–276.

Fuller-Rowell, T. J., D., Rees, S., Quegan, R. J., Moffett, M. V., Codrescu, and G. H., Millward, 1996. A Coupled Thermosphere-Ionosphere Model (CTIM), in STEP: Handbook of Ionospheric Models, edited by R. W. Schunk, pp. 239–279, Sci. Comm. on Sol.-Terr. Phys., Boulder, Colorado-USA.

Fuller-Rowell, T. J., M. V., Codrescu, E. A., Araujo-Pradere, and I., Kutiev, 1998. Progress in Developing a Storm-Time Ionospheric Correction Model, Adv. Space Res., 22(6), 821–827.

Gopalswamy, N., 2009. Halo Coronal Mass Ejections and Geomagnetic Storm, Earth Planet Space, 61, 1-3.

Lusiani, E. S., Mumpuni, J. A., Utama, 2011. Analisis Kaitan Badai Geomagnet dengan Badai Ionosfer Sebagai Dampak Kejadian Lontaran Massa Korona Matahari (Oktober-November 2003), Prosiding Seminar Nasional Astronomi Indonesia.

Mukherjee, S., Sarkar S., Purohit P. K., Gwal A. K., 2010. Effect of Geomagnetic Storms in the Equatorial Anomaly Region Observed from Ground Based Data, Int. Journal of Geomagnetics and Geosciences, Vol. 1, No. 3, 478-488.

Rastogi, R.G., 1999. Geomagnetic Storm Effects at Low Latitudes, Ann. Geophys., 17, 438–444.

Rawer, K., D., Bilitza, and S., Ramakrishnan, 1978. Goals and Status of the International Reference Ionosphere, Rev. Geophys., 16, 177–181.

Rodger, A. S., G. L., Wrenn, and H., Rishbeth, 1989. Geomagnetic Storms in the Antarctic F Region, II, physical interpretation, J. Atmos. Terr. Phys., 51, 851–866.

Russell, C.T., 2006. The Solar Wind Interaction with the Earth’s Magnetosphere : Tutorial, Department of Earth and space sciences and Institute of Geophysics and Space Physics of University of California, Los Angeles.

Yatini, C. Y., Jiyo, M., Ruhimat, 2009. Badai Matahari dan Pengaruhnya pada Ionosfer dan Geomagnet di Indonesia, Majalah Sains dan Teknologi Dirgantara Vo. 4 No. 17-24.

Zhao, B., Wan W., Liu L., K., Igarashi, K., Yumoto, Baiqi Ning, 2009. Ionospheric Response to the Geomagnetic Storm on 13-17 April 2006 in the West Pacific Region, Journal of Atmospheric and Solar-Terrestrial Physics 71 (2009) 88–100.