Near-Earth Interplanetary Coronal Mass Ejections and Their Association with DH Type II Radio Bursts During Solar Cycles 23 and 24

We analyse the characteristics of interplanetary coronal mass ejections (ICMEs) during Solar Cycles 23 and 24. The present analysis is primarily based on the near-Earth ICME catalogue (Richardson and Cane, 2010). An important aspect of this study is to understand the near-Earth and geoeffective aspects of ICMEs in terms of their association (type II ICMEs) versus absence (non-type II ICMEs) of decameter-hectometer (DH) type II radio bursts, detected by Wind/WAVES and STEREOS/WAVES. Notably, DH type II radio bursts driven by a CME indicate powerful MHD shocks leaving the inner corona and entering the interplanetary medium. We find a drastic reduction in the occurrence of ICMEs by 56% in Solar Cycle 24 compared to the previous cycle (64 versus 147 events). Interestingly, despite a significant decrease in ICME/CME counts, both cycles contain almost the same fraction of type II ICMEs (≈ 47%). Our analysis reveals that, even at a large distance of 1 AU, type II CMEs maintain significantly higher speeds compared to non-type II events (523 km s⁻¹ versus 440 km s⁻¹). While there is an obvious trend of decrease in ICME transit times with increase in the CME initial speed, there also exists a noticeable wide range of transit times for a given CME speed. Contextually, Cycle 23 exhibits 10 events with shorter transit times ranging between 20 – 40 hours of predominantly type II categories while, interestingly, Cycle 24 almost completely lacks such “fast” events. We find a significant reduction in the parameter V<inf>ICME</inf>× B<inf>z</inf>, the dawn to dusk electric field, by 39% during Solar Cycle 24 in comparison with the previous cycle. Further, V<inf>ICME</inf>× B<inf>z</inf> shows a strong correlation with Dst index, which even surpasses the consideration of B<inf>z</inf> and V<inf>ICME</inf> alone. The above results imply the crucial role of V<inf>ICME</inf>× B<inf>z</inf> toward effectively modulating the geoeffectiveness of ICMEs.