Your search keyword '"Navin Chandra Joshi"' showing total 2 results

1. Relationship between interplanetary field/plasma parameters with geomagnetic indices and their behavior during intense geomagnetic storms

Author

Kavita Pandey, Seema Pande, Navin Chandra Joshi, Bimal Pande, and Neeraj Singh Bankoti

Subjects

Geomagnetic storm, Physics, Plasma parameters, Solar cycle 23, Astronomy and Astrophysics, Astrophysics, Plasma, Atmospheric sciences, Solar cycle, Earth's magnetic field, Space and Planetary Science, Interplanetary spaceflight, Instrumentation, Solar equator

Abstract

This paper presents a correlative study between the peak values of geomagnetic activity indices (Dst, Kp, ap and AE) and the peak values of various interplanetary field (Bt, Bz, E and σ B ) and plasma (T, D, V, P and β ) parameters along with their various products (BV, BzV and B 2 V) during intense geomagnetic storms (GMSs) for rising, maximum and decay phases as well as for complete solar cycle 23. The study leads to the conclusion that the peak values of different geomagnetic activity indices are in good correlation with Bt, Bz, σ B , V, E, BV, BzV and B 2 V, therefore these parameters are most useful for predicting GMSs and substorms. These parameters are also reliable indicators of the strength of GMSs. We have also presented the lag/lead time analysis between the maximum of Dst and peak values of geomagnetic activity indices, various interplanetary field/plasma parameters for all GMSs. We have found that the average of peak values of geomagnetic activity indices and various field/plasma parameters are larger in decay phase compare to rising and maximum phases of cycle 23. Our analyses show that average values of lag/lead time lie in the ≈−4.00 h interval for Kp, ap and AE indices as well as for Bt, Bz, σ B , E, D and P. For a more meaningful analysis we have also presented the above study for two different groups G1 (CME-driven GMSs) and G2 (CIR-driven GMSs) separately. Correlation coefficients between various interplanetary field/plasma parameters, their various products and geomagnetic activity indices for G1 and G2 groups show different nature. Three GMSs and associated solar sources observed during three different phases of this solar cycle have also been studied and it is found that GMSs are associated with large flares, halo CMEs and their active regions are close to the solar equator.

Published

2011

2. Asymmetric behavior of different solar activity features over solar cycles 20–23

Author

Navin Chandra Joshi, Bimal Pande, Kavita Pandey, Neeraj Singh Bankoti, Wahab Uddin, and Seema Pande

Subjects

Solar minimum, Physics, Sunspot, integumentary system, food and beverages, Solar cycle 23, Astronomy and Astrophysics, Solar cycle 22, Solar maximum, Atmospheric sciences, Solar cycle, Solar cycle 20, Space and Planetary Science, biological sciences, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Instrumentation, Sun path, Physics::Atmospheric and Oceanic Physics

Abstract

This paper presents the study of normalized north–south asymmetry, cumulative normalized north–south asymmetry and cumulative difference indices of sunspot areas, solar active prominences (at total, low (⩽40°) and high (⩾50°) latitudes) and Hα solar flares from 1964 to 2008 spanning the solar cycles 20–23. Three different statistical methods are used to obtain the asymmetric behavior of different solar activity features. Hemispherical distribution of activity features shows the dominance of activities in northern hemisphere for solar cycle 20 and in southern hemisphere for solar cycles 21–23 excluding solar active prominences at high latitudes. Cumulative difference index of solar activity features in each solar cycle is observed at the maximum of the respective solar cycle suggesting a cyclic behavior of approximately one solar cycle length. Asymmetric behavior of all activity features except solar active prominences at high latitudes hints at the long term periodic trend of eight solar cycles. North–south asymmetries of SAP (H) express the specific behavior of solar activity at high solar latitudes and its behavior in long-time scale is distinctly opposite to those of other activity features. Our results show that in most cases the asymmetry is statistically highly significant meaning thereby that the asymmetries are real features in the N–S distribution of solar activity features.

Published

2011