EbookBell.com

Most ebook files are in PDF format, so you can easily read them using various software such as Foxit Reader or directly on the Google Chrome browser.
Some ebook files are released by publishers in other formats such as .awz, .mobi, .epub, .fb2, etc. You may need to install specific software to read these formats on mobile/PC, such as Calibre.

Please read the tutorial at this link: https://ebookbell.com/faq

We offer FREE conversion to the popular formats you request; however, this may take some time. Therefore, right after payment, please email us, and we will try to provide the service as quickly as possible.

For some exceptional file formats or broken links (if any), please refrain from opening any disputes. Instead, email us first, and we will try to assist within a maximum of 6 hours.

EbookBell Team

Ulf Waves Interaction With Cold And Thermal Particles In The Inner Magnetosphere Ren

Name: Ulf Waves Interaction With Cold And Thermal Particles In The Inner Magnetosphere Ren
SKU: BELL-10460952
Price: 31.00 USD
Availability: InStock
Rating: 4.8 (84 reviews)

SKU: BELL-10460952

$ 31.00 ~~$ 45.00~~ (-31%)

4.8

84 reviews

Ulf Waves Interaction With Cold And Thermal Particles In The Inner Magnetosphere Ren instant download after payment.

Publisher: Springer

File Extension: PDF

File size: 11.33 MB

Author: Ren, Jie

ISBN: 9789813293786, 9813293780

Language: English

Year: 2019

Product desciption

Ulf Waves Interaction With Cold And Thermal Particles In The Inner Magnetosphere Ren by Ren, Jie 9789813293786, 9813293780 instant download after payment.

This thesis focuses on ULF (Ultra-low-frequency) waves' interaction with plasmasphere particles and ring current ions in the inner magnetosphere. It first reports and reveals mutual effect between ULF waves and plasmasphere using Van Allen Probes data. The differences and similarities of different ring current ions interacting with ULF waves are extensively explored using Cluster data, which provides a potential explanation for O+-dominated ring current during the magnetic storms. Furthermore, this thesis finds a method to study the phase relationship between ULF waves and drift-bounce resonant particles, and proposes that the phase relationship can be used to diagnose the parallel structure of standing wave electric field and energy transfer directions between waves and particles. The findings in this thesis can significantly promote our understanding of ULF waves' role in the dynamics of inner magnetosphere.