The Implications of Temporal Variability in Wave‐Particle Interactions in Earth's Radiation Belts

Watt, Clare E. J.; Allison, Hayley; Thompson, R. L.; Bentley, Sarah; Meredith, Nigel P.; Glauert, S. A.; Horne, Richard B.; Rae, I. J.

doi:10.1029/2020gl089962

Cited by 11 publications

(43 citation statements)

References 30 publications

(55 reference statements)

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“…This suggests that when constructing a drift-average, an average of observation-specific bounce-averaged coefficients is likely to work well, since the effective timescales for electrons drifting through chorus wave regions are very short. Further numerical experiments, similar to those in Watt et al (2021), but using an appropriate distribution of chorus diffusion coefficients constructed as in Watt et al (2019) should confirm whether the timescales indicated in Figure 7c are short enough to allow for straightforward averaging.…”

Section: Temporal Scale Size Of Chorus Wavesmentioning

confidence: 83%

“…The temporal scale size of chorus waves has not been studied statistically and quantitatively before. Recent numerical experiments demonstrate that, the temporal variability is very important for diffusion models due to the wave‐particle interactions (Thompson et al., 2020; Watt et al., 2019, 2021). Figures 5a–5d show the temporal correlations are proportional to time lag ( e −0.0067 *Δ t ) and drops to 0.5 when Δ t = 10 s, which means the statistically temporal scale size of chorus wave only lasts ∼10 s, and could be negligible compared to the electron diffusion timescales.…”

Section: Discussionmentioning

confidence: 99%

“…Numerical experiments demonstrate that the solution of Fokker-Planck equation for the diffusion model is sensitively dependent on the temporal variability of the diffusion coefficient (Thompson et al, 2020;Watt et al, 2021), which will be affected by the spatial and temporal variations of the wave and plasma parameter. Watt et al (2021) performed multiple numerical experiments of bounce-averaged diffusion, and indicated that rapid variations (with timescales of ∼2 min) of whistler-mode wave diffusion coefficients resulted in solutions of the Fokker-Planck equations that were similar to results obtained from an averaged diffusion coefficient. For much longer timescales (∼6 hr), results from averaged experiments did not match well with the results from experiments with temporally varying coefficients.…”

Section: Temporal Scale Size Of Chorus Wavesmentioning

confidence: 99%

“…Traditional pitch angle diffusion models use parameterized diffusion coefficients that are mostly constructed from averaged plasma and wave properties (e.g., Fok et al., 2011; Horne et al., 2013; Tu et al., 2013). While, recent numerical experiments (Watt et al., 2019, 2021) indicate that the spatial and temporal variability of diffusion coefficients have universal importance for the diffusion process. Therefore, it is necessary to identify the temporal and spatial variation scale of wave characteristics to determine whether averaged diffusion coefficients can adequately capture the diffusion process, and to provide crucial information for use when constructing such averages.…”

Section: Introductionmentioning

confidence: 99%

“…In spite of these advances, the global spatial scale size of chorus waves in a physical coordinate system and its dependence on locations are still unclear. Specifically, the temporal scale size of chorus waves has not been studied statistically before, which has been revealed recently to be a significant factor for the radiation belt diffusion (Watt et al., 2021).…”

Section: Introductionmentioning

confidence: 99%

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Determining the Global Scale Size of Chorus Waves in the Magnetosphere

et al. 2021

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Chorus waves outside the plasmapause influence the Earth's radiation belt dynamics by interacting with energetic electrons via cyclotron and Landau resonance. Recent numerical diffusion experiments indicate that the diffusion process is sensitive to the spatial and temporal scale of variability in the wave‐particle interaction, which is reported to be more efficient than that based on the traditional average model. Using Van Allen Probes A and B data from November 2012 to July 2019, the spatial and temporal scale size of chorus waves are calculated by the correlation between the wave amplitudes detected by two satellites with varying spatial separation or time lag. We found that, the chorus wave is incoherent when the spatial extent is greater than 433 km or the time lag lasts ∼10 s, which are significantly smaller than that of plasmaspheric hiss. In addition, the spatial correlations of chorus tend to be higher near noon or with lower geomagnetic activity. The temporal correlations of chorus are always statistically near zero, which are not influenced by the location and geomagnetic activity. Our results can help refine the model of the interactions between energetic particles and chorus waves in the radiation belt.

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Section: Temporal Scale Size Of Chorus Wavesmentioning

confidence: 83%

Section: Discussionmentioning

confidence: 99%

Section: Temporal Scale Size Of Chorus Wavesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Determining the Global Scale Size of Chorus Waves in the Magnetosphere

et al. 2021

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Determining the Temporal and Spatial Coherence of Plasmaspheric Hiss Waves in the Magnetosphere

et al. 2021

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Plasmaspheric hiss is one of the most important plasma waves in the Earth's magnetosphere to contribute to radiation belt dynamics by pitch‐angle scattering energetic electrons via wave‐particle interactions. There is growing evidence that the temporal and spatial variability of wave‐particle interactions are important factors in the construction of diffusion‐based models of the radiation belts. Hiss amplitudes are thought to be coherent across large distances and on long timescales inside the plasmapause, which means that hiss can act on radiation belt electrons throughout their drift trajectories for many hours. In this study, we investigate both the spatial and temporal coherence of plasmaspheric hiss between the two Van Allen Probes from November 2012 to July 2019. We find ∼3,264 events where we can determine the correlation of wave amplitudes as a function of both spatial distance and time lag in order to study the spatial and temporal coherence of plasmaspheric hiss. The statistical results show that both the spatial and temporal correlation of plasmaspheric hiss decrease with increasing L‐shell, and become incoherent at L > ∼4.5. Inside of L = ∼4.5, we find that hiss is coherent to within a spatial extent of up to ∼1,500 km and a time lag up to ∼10 min. We find that the spatial and temporal coherence of plasmaspheric hiss does not depend strongly on the geomagnetic index (AL*) or magnetic local time. We discuss the ramifications of our results with relevance to understanding the global characteristics of plasmaspheric hiss waves and their role in radiation belt dynamics.

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