Astrometric performance of the five major uranian satellites using a narrow-band Methane filter

IF 1.8 4区物理与天体物理 Q3 ASTRONOMY & ASTROPHYSICS

Planetary and Space Science Pub Date : 2025-03-14 DOI:10.1016/j.pss.2025.106085

X.Q. Fang , Q.Y. Peng , X. Lu , B.F. Guo

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Abstract

During ground-based observations of satellites near a bright planet, the satellite images are often affected by the planet’s halo, introducing significant uncertainty in their astrometric positions. To address this issue, we employed a narrow-band methane filter for observations of the five major Uranian satellites, which makes them easily discernible on CCD frames without requiring halo removal procedures. We systematically evaluated the astrometric performance of this Methane filter and compared it to that of the commonly used Clear and Cousins-I filters. Totally, the positional precision for most of the four brightest satellites is approximately 30 mas in both right ascension and declination, comparable to the Cousins-I filter and superior to the Clear filter. On the other hand, the faint satellite Miranda achieves a precision of better than 80 mas after image stacking in the methane band images. Based on our experiments, we recommend using the Methane filter for observing objects with an apparent visual magnitude brighter than 15, as it offers a sufficient signal-to-noise ratio (SNR) of approximately 55 within a reasonable exposure time of 200 s using a 0.8 m telescope.

Abstract Image

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在对明亮行星附近的卫星进行地面观测时，卫星图像往往会受到行星光晕的影响，从而给它们的天体测量位置带来很大的不确定性。为了解决这个问题，我们采用了一种窄带甲烷滤光片来观测天王星的五颗主要卫星，这种滤光片可以在 CCD 图像上轻松辨别这些卫星，而不需要进行光晕去除程序。我们系统地评估了这种甲烷滤光片的天体测量性能，并将其与常用的Clear和Cousins-I滤光片进行了比较。从总体上看，四颗最亮卫星中的大多数在赤经和赤纬上的定位精度都大约为30mas，与Cousins-I滤光片相当，优于Clear滤光片。另一方面，昏暗卫星米兰达在甲烷波段图像叠加后的精度超过了 80mas。根据我们的实验，我们建议在观测视星等亮度大于 15 的天体时使用甲烷滤光片，因为使用 0.8 米望远镜，在 200 秒的合理曝光时间内，甲烷滤光片可以提供约 55 的足够信噪比（SNR）。

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来源期刊

Planetary and Space Science 地学天文-天文与天体物理

CiteScore

5.40

自引率

4.20%

发文量

126

审稿时长

15 weeks

期刊介绍： Planetary and Space Science publishes original articles as well as short communications (letters). Ground-based and space-borne instrumentation and laboratory simulation of solar system processes are included. The following fields of planetary and solar system research are covered: • Celestial mechanics, including dynamical evolution of the solar system, gravitational captures and resonances, relativistic effects, tracking and dynamics • Cosmochemistry and origin, including all aspects of the formation and initial physical and chemical evolution of the solar system • Terrestrial planets and satellites, including the physics of the interiors, geology and morphology of the surfaces, tectonics, mineralogy and dating • Outer planets and satellites, including formation and evolution, remote sensing at all wavelengths and in situ measurements • Planetary atmospheres, including formation and evolution, circulation and meteorology, boundary layers, remote sensing and laboratory simulation • Planetary magnetospheres and ionospheres, including origin of magnetic fields, magnetospheric plasma and radiation belts, and their interaction with the sun, the solar wind and satellites • Small bodies, dust and rings, including asteroids, comets and zodiacal light and their interaction with the solar radiation and the solar wind • Exobiology, including origin of life, detection of planetary ecosystems and pre-biological phenomena in the solar system and laboratory simulations • Extrasolar systems, including the detection and/or the detectability of exoplanets and planetary systems, their formation and evolution, the physical and chemical properties of the exoplanets • History of planetary and space research