Temporal Characteristics Of Microwave Radiations Emitted By Narrow Bipolar Events In Tropical Thunderstorms
A lightning flash starts with the very first process called electron avalanche followed by streamer and leader. Each process has their own peaked frequency band, such as the leader is peaked between Very Low Frequency (VLF) and Low Frequency (LF) bands while streamer is peaked at Very High Freque...
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| Format: | Thesis |
| Language: | English English |
| Published: |
2020
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| Subjects: | |
| Online Access: | http://eprints.utem.edu.my/id/eprint/25399/1/Temporal%20Characteristics%20Of%20Microwave%20Radiations%20Emitted%20By%20Narrow%20Bipolar%20Events%20In%20Tropical%20Thunderstorms.pdf http://eprints.utem.edu.my/id/eprint/25399/2/Temporal%20Characteristics%20Of%20Microwave%20Radiations%20Emitted%20By%20Narrow%20Bipolar%20Events%20In%20Tropical%20Thunderstorms.pdf http://eprints.utem.edu.my/id/eprint/25399/ https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=119741 |
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| Summary: | A lightning flash starts with the very first process called electron avalanche followed by
streamer and leader. Each process has their own peaked frequency band, such as the leader
is peaked between Very Low Frequency (VLF) and Low Frequency (LF) bands while
streamer is peaked at Very High Frequency (VHF) band. However, the peak frequency
band of electron avalanche cannot be determined with certain. There are two postulations
regarding the peak frequency of electron avalanche. First postulation suggests that
electron avalanche peaked at VHF band while the second suggests electron avalanche
peaked in microwave band. All simulation results suggest that electron avalanche emits
strong microwave radiations. On the other hand, all experimental works were more focus
on the characteristics of microwave radiation for each lightning event such as initial
breakdown and return stroke rather than investigating whether microwave radiation
emitted by electron avalanche or not. The significance of this project was the contribution
of the new knowledge in lightning initiation by designing a microwave receiver and
distinguishing the difference between microwave and VHF radiations emitted by
lightning flashes. As the streamer is preceded by electron avalanche, detecting microwave
radiation before the onset of VHF could be used as a method to prove that electron
avalanche emits strong microwave radiation. In this thesis, microwave radiations
associated with Narrow Bipolar Events (NBEs) have been chosen to analyze the onset
time of both microwave and VHF radiations. In order to detect the microwave radiation,
a finite-length and small air-gap parallel plates antennas with resonance frequency around
1 GHz were designed and fabricated. Then, the temporal characteristics of these
microwave waveforms were analysed and compared to their corresponding VHF and
LF/VLF waveforms. A total of 74 NBEs accompanied by the VHF and microwave
radiations have been recorded and analysed. Microwave radiations of 16 NBEs were found
to lead VHF and fast antenna (LF/VLF) records with lead time of 125.53 ± 81.32 ns and
600.65 ± 222.34 ns, respectively. Both burst trains of VHF and microwave radiations are
consisting of Rising Phase (RP) and Damping Phase (DP). A total of 21 microwave and 22
VHF waveforms were found to have Initial Stage (IS) at the earlier part of the RP with clear
bipolar shape waveform. Moreover, 27 VHF burst trains consist of a kind of unique temporal
characteristic named as Quiet Phase (QP) where VHF radiation was absent, which was not
found in any microwave radiations. This might be the transient period for the electron
avalanche at a streamer tip delayed due to the attachment factor, |
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