The Case for Combining a Large Low‐Band Very High Frequency Transmitter With Multiple Receiving Arrays for Geospace Research: A Geospace Radar

Hysell, D. L.; Chau, Jorge L.; Coles, W. A.; Milla, Marco; Obenberger, K. S.; Vierinen, Juha

doi:10.1029/2018rs006688

Cited by 12 publications

(8 citation statements)

References 70 publications

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“…Ionospheric radar and radio imaging in the high-frequency band will motivate the development of techniques to quantify and correct for radio propagation effects, including refraction and reflection near the critical plasma level. These techniques will be valuable whenever renewed radar observations of the solar corona might be performed using VHF radar imaging at the critical plasma level in the corona (James, 1970;Hysell et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

Science goals for a high-frequency radar and radio imaging array

Isham,

Bullett,

Gustavsson

et al. 2023

Front. Astron. Space Sci.

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A medium and high-frequency antenna array for radar and radio imaging of the ionosphere is planned for installation in Aguadilla, Puerto Rico. Science goals include the study of space weather, radio propagation, meteors, lightning, and plasma physics. Radio imaging is ideal for the study of stimulated ionospheric radio emissions, such as those induced by the Arecibo Observatory high-power HF radio transmitter, which is likely to be restored to operation in the near future. The array will be complemented by a wide variety of instruments fielded by collaborators, and will be a rich source of student projects at all levels.

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Section: Discussionmentioning

confidence: 99%

Science goals for a high-frequency radar and radio imaging array

Isham,

Bullett,

Gustavsson

et al. 2023

Front. Astron. Space Sci.

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“…A low-band VHF geospace and heliospheric radar for atmospheric, space, and solar science has been a decades-long dream of atmospheric and space scientists, in part inspired by present and past radar observatories, including Jicamarca (50 MHz) (Ochs, 1965), Arecibo (40 MHz) (Mathews, 2013), and El Campo (38 MHz) (Abel et al, 1962). Efforts towards this goal have periodically been made (Thidé et al, 1994(Thidé et al, , 2002Hysell et al, 2019;Coster et al, 2021Coster et al, , 2022.…”

Section: A Geospace and Heliospheric Radarmentioning

confidence: 99%

An Advanced Low-Band VHF Radar for Atmospheric, Geospace, and Solar Research

Isham,

Kooi,

Kassim

et al. 2023

Bulletin of the AAS

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The construction of a low-band VHF (20-80 MHz) radar observatory -for research spanning the solar corona, solar wind, the magnetosphere, ionosphere, neutral atmosphere, meteors, and space plasmas -has been a decades-long dream of space scientists.Over the years our awareness of what might be gained by such an observatory has increased, and the techniques that can be used have dramatically improved, making this an opportune time for the design and construction of a powerful and capable modern radar observatory:-High continuous transmitter power, multiple receiving sites for 3-D velocity measurements and radar imaging, frequency agility for observations at multiple scale lengths, and wide bandwidth for high range resolution, will support a powerful new solar, sun-earth, planetary, space weather, and astronomical research and monitoring capability.-Low VHF frequencies are required for radar measurements of the sun. Solar radar observations were carried out in the past, but the technology and supporting measurements were limited.-High-resolution vector measurements of coherent and incoherent scatter from the neutral atmosphere and ionosphere would change the nature of what can be observed.-Passive radio measurements could be used to study magnetized extra-solar planets, whose magnetic fields, as shields against cosmic rays, could be a prerequisite for life.We note that there is significant overlap between the heliospheric, geospace, and atmospheric science goals outlined here, the science goals discussed at a recent Solar and Space Physics Decadal Survey workshop and at previous workshops (

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“…The coupling between the atmosphere and ionosphere is greatly influenced by the complex characteristics of the upper stratosphere and the mesosphere and lower thermosphere (MLT). However, measurements of wind speeds are still lacking in these altitude regions, particularly between 30 and 60 km, which is also known as the "radar gap" (Shepherd, 2015;Hysell et al, 2019;Liu et al, 2023).…”

Section: Introductionmentioning

confidence: 99%

Feasibility analysis of optimal terahertz (THz) bands for passive limb sounding of middle and upper atmospheric wind

Wang,

Xu,

Wang

2023

Atmos. Meas. Tech.

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Abstract. As of now, direct measurements of middle and upper atmospheric wind are still scarce, and the observation method is limited, especially for the upper stratosphere and lower mesosphere. This paper presents a study of band selection to derive line-of-sight wind from 30 km to more than 120 km using a high-spectral-resolution terahertz (THz) radiometer, which can fill the measurement gap between lidar and interferometer data. Simulations from 0.1–5 THz for evaluating the feasibility of the spaceborne THz limb sounder are described in this study. The results show that high-precision wind (better than 5 m s−1) can be obtained from 40 to 70 km by covering a cluster of strong O3 lines. By choosing strong O2 or H2O lines, the high-quality measurement can be extended to 105 km. The O atom (OI) lines can provide wind signals in the higher atmosphere. In addition, performance of different instrument parameters, including spectral resolution, bandwidth, and measurement noise, was analyzed, and, lastly, four different band combinations are suggested.

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The Case for Combining a Large Low‐Band Very High Frequency Transmitter With Multiple Receiving Arrays for Geospace Research: A Geospace Radar

Cited by 12 publications

References 70 publications

Science goals for a high-frequency radar and radio imaging array

Science goals for a high-frequency radar and radio imaging array

An Advanced Low-Band VHF Radar for Atmospheric, Geospace, and Solar Research

Feasibility analysis of optimal terahertz (THz) bands for passive limb sounding of middle and upper atmospheric wind

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