Abstract
Abstract. The nonlinear evolution of equatorial F-region plasma bubbles under varying ambient ionospheric conditions and gravity wave seeding perturbations in the bottomside F-layer is studied. To do so, the gravity wave propagation from the convective source region in the lower atmosphere to the thermosphere is simulated using a model of gravity wave propagation in a compressible atmosphere. The wind perturbation associated with this gravity wave is taken as a seeding perturbation in the bottomside F-region to excite collisional-interchange instability. A nonlinear model of collisional-interchange instability (CII) is implemented to study the influences of gravity wave seeding on plasma bubble formation and development. Based on observations during the SpreadFEx campaign, two events are selected for detailed studies. Results of these simulations suggest that gravity waves can play a key role in plasma bubble seeding, but that they are also neither necessary nor certain to do so. Large gravity wave perturbations can result in deep plasma bubbles when ionospheric conditions are not conducive by themselves; conversely weaker gravity wave perturbations can trigger significant bubble events when ionospheric conditions are more favorable. But weak gravity wave perturbations in less favorable environments cannot, by themselves, lead to strong plasma bubble responses.
Highlights
The collisional interchange instability (CII) is believed to play a crucial role in the onset and development of equatorial spread F (ESF) turbulence (Haerendel, 1973)
On the basis of ambient ionospheric conditions and gravity waves (GWs) activity, we consider following cases within the Event 1: Case 1.a: Ambient condition and GW amplitude corresponding to 23–24 October, i.e. δW =δW o; www.ann-geophys.net/27/1657/2009/
Under the same less favorable conditions as Case 1.b, but with enhanced GW activity corresponding to 24–25 October, rapid rising bubble are formed though not as rapid as in Case 1.a. These results indicate that though the ambient ionospheric conditions were less favorable to CII and to the excitation of deep plasma bubbles on 24–25 October, bubbles could, develop owing to the enhanced GW activity
Summary
The collisional interchange instability (CII) is believed to play a crucial role in the onset and development of equatorial spread F (ESF) turbulence (Haerendel, 1973). 19–20, weak 19–21, strong (almost 1.25 times stronger than 24–25 Oct) found that gravity waves with wind amplitude of a few meter per second, horizontal wavelength of few hundred kilometers and vertical wavelength of few tens of kilometers are a very effective seed mechanism for production of ESF. These studies clearly indicate the potential importance of GWs in the seeding process, but definitive measurements confirming the simultaneous occurrence of GWs and bubble seeding remained out of reach
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