Alexander A. Massoud , Fabiano S. Rodrigues , Jonas Sousasantos , Marco A. Milla , Danny E. Scipion , Joab M. Apaza , Karim M. Kuyeng , Carlos Padin
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Here, we present what we believe to be the first report describing the quiet-time climatology of sub-meter equatorial F-region irregularities derived from UHF radar measurements. The measurements were made between August 2021 and February 2023 using a 10-beam AMISR-14 mode that scanned the F-region in the magnetic equatorial plane. The results show how F-region sub-meter irregularities respond to variations in season and solar flux conditions. The results also confirm, experimentally, that the occurrence of UHF F-region echoes is controlled by the occurrence of equatorial spread F (ESF). Higher occurrence rates were observed during pre-midnight hours and during Equinox and December solstice. Reduced occurrence rates were observed during June solstice. The results show that an increase in solar flux was followed by an increase in the altitude where noticeable occurrence rates (<span><math><mrow><mo>≳</mo></mrow></math></span> 10%) start and in the maximum altitude of these occurrence rates. The observations also show that occurrence rates lasted longer (in local time) during low solar flux conditions. Comparisons with collocated VHF radar observations showed that, despite differences in radar parameters, observation days, and the scale size (one order of magnitude) of the scattering irregularities, the two systems show similar climatological variations with only minor differences in the absolute occurrence rates. Finally, the analysis of the occurrence rates for different beams did not show substantial climatological variations over local (within a few 100s of km) zonal distances around JRO. We point out, however, that observations on a single day can show strong local variations in echo detection and intensity within the AMISR-14 field of view due to the intrinsic development and decay of ESF structures.</p></div>","PeriodicalId":15096,"journal":{"name":"Journal of Atmospheric and Solar-Terrestrial Physics","volume":"263 ","pages":"Article 106328"},"PeriodicalIF":1.8000,"publicationDate":"2024-08-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S1364682624001561/pdfft?md5=6aa5eab261aa8ae41e8df52359304e59&pid=1-s2.0-S1364682624001561-main.pdf","citationCount":"0","resultStr":"{\"title\":\"First climatology of F-region UHF echoes observed by the AMISR-14 system at the Jicamarca radio observatory and comparison with the climatology of VHF echoes observed by the collocated JULIA radar\",\"authors\":\"Alexander A. Massoud , Fabiano S. Rodrigues , Jonas Sousasantos , Marco A. 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引用次数: 0
摘要
在 Jicamarca 射电天文台(JRO)进行的相干反向散射雷达观测极大地促进了我们对赤道 F 区域不规则现象的了解。不过,雷达观测主要是在甚高频(VHF)波段(50 兆赫)进行的,这相当于对 3 米场对准不规则现象的测量。在 Jicamarca 部署的 14 面板版高级模块化非相干散射雷达(AMISR-14)为观测超高频(UHF - 445 MHz)回波提供了机会,超高频对应于 0.34 米尺度的不规则体测量。在此,我们首次报告了通过超高频雷达测量得出的赤道 F 区域亚米级不规则面的静时气候学。测量是在 2021 年 8 月至 2023 年 2 月期间进行的,使用的是 10 波束 AMISR-14 模式,扫描了磁赤道平面上的 F 区域。测量结果表明了 F 区子米不规则性是如何随季节和太阳通量条件的变化而变化的。实验结果还证实,超高频 F 区回波的出现受赤道展宽 F(ESF)的控制。在午夜前、春分和 12 月至期间,观测到较高的发生率。在六月至期间,观测到的发生率较低。结果表明,太阳通量增加后,开始出现明显出现率(≳ 10%)的高度和出现率的最大高度也随之增加。观测结果还表明,在低太阳辐射通量条件下,出现率持续时间更长(以当地时间计算)。与同地甚高频雷达观测结果的比较表明,尽管雷达参数、观测天数和散射不规则的尺度大小(一个数量级)不同,但两个系统显示出相似的气候学变化,只是在绝对出现率方面有细微差别。最后,对不同波束的出现率进行的分析表明,在 JRO 周围的局部(几百公里内)地带距离上,气候学变化不大。不过,我们指出,在 AMISR-14 视场内,由于 ESF 结构的内在发展和衰减,单日观测会在回波探测和强度方面显示出强烈的局部变化。
First climatology of F-region UHF echoes observed by the AMISR-14 system at the Jicamarca radio observatory and comparison with the climatology of VHF echoes observed by the collocated JULIA radar
Coherent backscatter radar observations made at the Jicamarca Radio Observatory (JRO) have contributed significantly to our understanding of equatorial F-region irregularities. Radar observations, however, have been made predominantly at the Very-High Frequency (VHF) band (50 MHz), which corresponds to measurements of 3-m field-aligned irregularities. The deployment of the 14-panel version of the Advanced Modular Incoherent Scatter Radar (AMISR-14) at Jicamarca provided an opportunity for observations of Ultra-High Frequency (UHF - 445 MHz) echoes which correspond to measurements of irregularities with 0.34 m scale sizes. Here, we present what we believe to be the first report describing the quiet-time climatology of sub-meter equatorial F-region irregularities derived from UHF radar measurements. The measurements were made between August 2021 and February 2023 using a 10-beam AMISR-14 mode that scanned the F-region in the magnetic equatorial plane. The results show how F-region sub-meter irregularities respond to variations in season and solar flux conditions. The results also confirm, experimentally, that the occurrence of UHF F-region echoes is controlled by the occurrence of equatorial spread F (ESF). Higher occurrence rates were observed during pre-midnight hours and during Equinox and December solstice. Reduced occurrence rates were observed during June solstice. The results show that an increase in solar flux was followed by an increase in the altitude where noticeable occurrence rates ( 10%) start and in the maximum altitude of these occurrence rates. The observations also show that occurrence rates lasted longer (in local time) during low solar flux conditions. Comparisons with collocated VHF radar observations showed that, despite differences in radar parameters, observation days, and the scale size (one order of magnitude) of the scattering irregularities, the two systems show similar climatological variations with only minor differences in the absolute occurrence rates. Finally, the analysis of the occurrence rates for different beams did not show substantial climatological variations over local (within a few 100s of km) zonal distances around JRO. We point out, however, that observations on a single day can show strong local variations in echo detection and intensity within the AMISR-14 field of view due to the intrinsic development and decay of ESF structures.
期刊介绍:
The Journal of Atmospheric and Solar-Terrestrial Physics (JASTP) is an international journal concerned with the inter-disciplinary science of the Earth''s atmospheric and space environment, especially the highly varied and highly variable physical phenomena that occur in this natural laboratory and the processes that couple them.
The journal covers the physical processes operating in the troposphere, stratosphere, mesosphere, thermosphere, ionosphere, magnetosphere, the Sun, interplanetary medium, and heliosphere. Phenomena occurring in other "spheres", solar influences on climate, and supporting laboratory measurements are also considered. The journal deals especially with the coupling between the different regions.
Solar flares, coronal mass ejections, and other energetic events on the Sun create interesting and important perturbations in the near-Earth space environment. The physics of such "space weather" is central to the Journal of Atmospheric and Solar-Terrestrial Physics and the journal welcomes papers that lead in the direction of a predictive understanding of the coupled system. Regarding the upper atmosphere, the subjects of aeronomy, geomagnetism and geoelectricity, auroral phenomena, radio wave propagation, and plasma instabilities, are examples within the broad field of solar-terrestrial physics which emphasise the energy exchange between the solar wind, the magnetospheric and ionospheric plasmas, and the neutral gas. In the lower atmosphere, topics covered range from mesoscale to global scale dynamics, to atmospheric electricity, lightning and its effects, and to anthropogenic changes.