Using the World Wide Lightning Location Network (WWLLN) to study Very Low Frequency transmission in the Earth‐Ionosphere Waveguide: 2. Model test by patterns of detection/non‐detection

Abstract. The modeling of very low-frequency (VLF) electromagnetic (EM) beam propagation in the Earth–ionosphere waveguide (WGEI) is considered. A new tensor impedance method for modeling the propagation of electromagnetic beams in a multi-layered and inhomogeneous waveguide is presented. The waveguide is assumed to possess the gyrotropy and inhomogeneity with a thick cover layer placed above the waveguide. The influence of geomagnetic field inclination and carrier beam frequency on the characteristics of the polarization transformation in the Earth–ionosphere waveguide is determined. The new method for modeling the propagation of electromagnetic beams allows us to study the (i) propagation of the very low-frequency modes in the Earth–ionosphere waveguide and, in perspective, their excitation by the typical Earth–ionosphere waveguide sources, such as radio wave transmitters and lightning discharges, and (ii) leakage of Earth–ionosphere waveguide waves into the upper ionosphere and magnetosphere. The proposed approach can be applied to the variety of problems related to the analysis of the propagation of electromagnetic waves in layered gyrotropic and anisotropic active media in a wide frequency range, e.g., from the Earth–ionosphere waveguide to the optical waveband, for artificial signal propagation such as metamaterial microwave or optical waveguides.

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Extremely low frequency detection of electrical discharges at Minamidake crater (Sakurajima volcano, Japan)

10.5194/egusphere-egu2020-5298 ◽

2020 ◽

Author(s):

Caron E.J. Vossen ◽

Corrado Cimarelli ◽

Alec J. Bennett ◽

André Geisler ◽

Damien Gaudin ◽

...

Keyword(s):

Low Frequency ◽

Japan Meteorological Agency ◽

Frequency Range ◽

Electrical Discharges ◽

Very Low Frequency ◽

Extremely Low Frequency ◽

Sakurajima Volcano ◽

Frequency Detection ◽

The World ◽

Active Volcanoes

Volcanoes are increasingly better monitored around the world. Nonetheless, the detection and monitoring of volcanic ash plumes remains difficult, especially in remote areas. Intense electrical activity and lightning in volcanic plumes suggests that electrical monitoring of active volcanoes can aid the detection of ash emissions in near real-time. Current very low frequency and wide-band thunderstorm networks have proven to be able to detect plumes of large magnitude. However, the time delay and the relatively high number of non-detected explosive episodes show that the applicability of these systems to the detection of smaller (and often more frequent) ash-rich explosive events is limited. Here we use a different type of thunderstorm detector to observe electrical discharges generated by the persistent Vulcanian activity of Minamidake crater at Sakurajima volcano in Japan. The sensors consist of two antennas that measure the induced current due to the change in electric field with time. In contrast to the current thunderstorm networks, these sensors measure within the extremely low frequency range (1-45 Hz) and can detect lightning up to 35 kilometres distance.Two detectors were installed at a distance of 3 and 4 kilometres from Minamidake crater and recorded almost continuously since July 2018. Within this period, the ash plumes reached a maximum height of 5.5 kilometres above the crater rim. Using a volcanic lightning detection algorithm and the catalogue of volcanic explosions compiled by the Japan Meteorological Agency (JMA), the number of electrical discharges was determined for each individual explosive event. In addition, the start of electrical discharges was compared to the eruption onset estimated by the JMA.Preliminary results show that the detector closest to the crater had the highest detection efficiency. It detected electrical discharges during 60% of the eruptions listed by the JMA. This is significantly higher than for the World Wide Lightning Location Network, which detected electrical discharges (in the very low frequency range) within 20 kilometres of Sakurajima for less than 0.005% of the eruptions. Furthermore, the results show that for 40% of the detected eruptions, electrical discharges were detected before the estimated JMA timing. Hence, electrical discharges can mark the inception of the explosion with a higher precision and are an indication of ash emission. This demonstrates the value of the cost-effective sensors used here as a monitoring tool at active volcanoes.

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Excitation of modes at very low frequency in the earth-ionosphere wave guide

Journal of Geophysical Research Atmospheres ◽

10.1029/jz067i010p03823 ◽

1962 ◽

Vol 67 (10) ◽

pp. 3823-3828 ◽

Cited By ~ 10

Author(s):

James R. Wait

Keyword(s):

Low Frequency ◽

Wave Guide ◽

Very Low Frequency ◽

The Earth

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CONCATENATION DIAGRAMS IN PERSONALITY TYPOLOGY: EXAMINING ENNEAGRAMS

Social Behavior and Personality An International Journal ◽

10.2224/sbp.1992.20.2.101 ◽

1992 ◽

Vol 20 (2) ◽

pp. 101-109 ◽

Cited By ~ 3

Author(s):

K. H. Wolf

Keyword(s):

World Wide ◽

Earth Science ◽

Ecological Systems ◽

The Earth ◽

The World ◽

Personality Typology

Enneagrams used in personality typological studies are only one of numerous types of diagrams that model actual and potential interrelationships based on nine factors, parameters or variables (=FPVs). However, the psychological-sociological discipline – like any field of investigation (whether non scientific or scientific) – has to deal with so many FPVs that the over-simplistic enneagrams and similar conceptual figures do not reveal all possible interconnections. When all known FPVs are integrated, many hundreds of additional complexities become obvious. Several linkage or concatenation diagrams useful in handling more than just nine (=ennea-), or multiple of nine, FPVs are offered here; psychological-sociological “systems” are as complex as any of the earth science-based complexes, like the world wide ecological systems (e.g. Gaia-type) which are controlled by “innumerable” FPVs. Investigations should go far beyond the simplistic enneagrams.

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A performance assessment of the World Wide Lightning Location Network (WWLLN) via comparison with the Canadian Lightning Detection Network (CLDN)

Atmospheric Measurement Techniques Discussions ◽

10.5194/amtd-3-1861-2010 ◽

2010 ◽

Vol 3 (2) ◽

pp. 1861-1887 ◽

Cited By ~ 3

Author(s):

D. Abreu ◽

D. Chandan ◽

R. H. Holzworth ◽

K. Strong

Keyword(s):

Standard Deviation ◽

World Wide ◽

Detection Efficiency ◽

Low Frequency ◽

High Peak ◽

Peak Current ◽

Lightning Detection ◽

The World ◽

The Mean ◽

The Difference

Abstract. The World Wide Lightning Location Network (WWLLN) uses globally-distributed Very Low Frequency (VLF) receivers in order to observe lightning around the globe. Its objective is to locate as many global strokes as possible, with high temporal and spatial (<10 km) accuracy. Since detection is done in the VLF range, signals from high peak current lightning strokes are able to propagate up to ~104 km before being detected by the WWLLN sensors, allowing for receiving stations to be sparsely spaced. Through a comparison with measurements made by the Canadian Lightning Detection Network (CLDN) between May and August 2008 over a 4° latitude by 4° longitude region centered on Toronto, Canada, this study found that WWLLN detection was most sensitive to high peak current lightning strokes. Events were considered shared between the two networks if they fell within 0.5 ms of each other. Using this criterion, 19 128 WWLLN strokes (analyzed using the Stroke_B algorithm) were shared with CLDN lightning strokes, producing a detection efficiency of 2.8%. The peak current threshold for WWLLN detection is found to be ~20 kA, with the detection efficiency increasing to ~70% at peak currents of ±120 kA. The detection efficiency is seen to have a clear diurnal dependence, with a higher detection efficiency at local midnight than at local noon; this is attributed to the difference in the thickness of the ionospheric D-region between night and day. The mean time difference (WWLLN – CLDN) between shared events was −6.44 μs with a standard deviation of 35 μs, and the mean absolute location accuracy was 7.24 km with a standard deviation of 6.34 km. These results are generally consistent with previous comparison studies of the WWLLN with other regional networks around the world. Additional receiver stations are continuously being added to the network, acting to improve this detection efficiency.

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1. Past sounds

Sound: A Very Short Introduction ◽

10.1093/actrade/9780198708445.003.0001 ◽

2015 ◽

pp. 1-9

Author(s):

Mike Goldsmith

Keyword(s):

Low Frequency ◽

Big Bang ◽

Sound Waves ◽

Very Low Frequency ◽

Living Things ◽

The World ◽

Sonar Systems ◽

History Of ◽

Hearing Evolution ◽

The Big Bang

‘Past sounds’ provides a history of sound from the origin of sound waves 300,000 years after the Big Bang to the modern day of ultrasound and electroacoustic technology. Primordial sound was of a very low frequency, but powerful and omnipresent, and the environment in which the first living things evolved was an acoustically rich one, profoundly affecting the forms, habits, and destinies of those creatures. Hearing evolution is described along with the human development of music and musical instruments. The Greeks built amphitheatres that dealt with the practicalities of sound and Pythagoras studied harmony on a monochord. The World Wars of the twentieth century accelerated electronics development and inspired underwater acoustic research and sonar systems.

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The model of own seismoelectromagnetic oscillations of LAI system

Solid Earth Discussions ◽

10.5194/sed-2-233-2010 ◽

2010 ◽

Vol 2 (2) ◽

pp. 233-250 ◽

Cited By ~ 3

Author(s):

M. K. Kachakhidze ◽

Z. A. Kereselidze ◽

N. K. Kachakhidze

Keyword(s):

Low Frequency ◽

Electrostatic Model ◽

Charge Generation ◽

Atmospheric Effect ◽

Very Low Frequency ◽

The Earth ◽

Atmosphere System ◽

Preparation Period ◽

Electromagnetic Oscillations ◽

Precursor Effects

Abstract. Very low frequency (VLF) electromagnetic radiation (in diapason 1 kHz – 1 MHz) in atmosphere, generated during earthquake preparation period, may be connected with linear size, characterizing incoming earthquake source. In order to argue this hypothesis very simple quasi-electrostatic model is used: local VLF radiation may be the manifestation of own electromagnetic oscillations of concrete seismoactive segments of lithosphere-atmosphere system. This model explains qualitatively well-known precursor effects of earthquakes. At the same time, it will be principally possible to forecast expected earthquake with certain precision if we use this model after diagnosing existed data. As physical basis of working hypothesis is atmospheric effect of polarization charges occurred in surface layer of the Earth, it is possible to test the below constructed model in medium, where reasons of polarization charge generation may be different from piezoelectric mechanism, for example, due to electrolytic hydration.

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Impact of earthquakes and tsunamis on the ionosphere

Физика земли ◽

10.31857/s0002-333720191199-213 ◽

2019 ◽

pp. 199-213

Author(s):

S. L. Shalimov ◽

A. A. Rozhnoi ◽

M. S. Solov`eva ◽

E. V. Ol`shanskaya

Keyword(s):

Low Frequency ◽

Global Network ◽

Very Low Frequency ◽

Complex Processes ◽

The Earth ◽

Navigational Systems

Fairly complex processes of lithosphere–ionosphere interactions can be explored by diagnosing the outer envelopes of the Earth with the use of global satellite navigational systems and equally global network of ground receivers and very-low-frequency transmitters. The earthquake and tsunami impacts on the ionosphere are the example of these processes. The current advances in the studies of these processes are briefly outlined.

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