As part of the astrometric and phase-referenced astronomy (ASTRA) project, three new science modes are being developed for the Keck Interferometer that extend the science capabilities of this instrument to include higher spectral resolution, fainter magnitudes, and astrometry. We report on the successful implementation of the first of these science modes, the self-phase-referencing mode, which provides a K-band (λ = 2:2 μm) spectral resolution of R ~ 1000 on targets as faint as 7.8 mag with spatial resolution as fine as λ/B = 5 mas in the K band, with the 85 m interferometer baseline. This level of spectral resolution would not have been possible without a phase-referencing implementation extending the integration time limit imposed by atmospheric turbulence. For narrow spectral features, we demonstrate a precision of ±0:01 on the differential V ~2(λ), and ±1:7 mrad on the differential phase Φ(λ), equivalent to a differential astrometry precision of ±1:45 μas. This new Keck Interferometer instrument is typically used to study the geometry and location of narrow spectral features at high angular resolution, referenced to a continuum. By simultaneously providing spectral and spatial information, the geometry of velocity fields (e.g., rotating disks, inflows, outflows, etc.) larger than 150 km s ~(-1) can also be explored.
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机译:作为天文和相位参考天文学(ASTRA)项目的一部分,正在为凯克干涉仪开发三种新的科学模式,这些新模式将这种仪器的科学功能扩展到更高的光谱分辨率,微弱的幅度和天文测量。我们报告了第一种科学模式的成功实施,即自相位参考模式,该模式可在目标微弱至7.8 mag的目标上提供R〜1000的K波段(λ= 2:2μm)光谱分辨率。在85 m干涉仪基线的情况下,K波段的空间分辨率高达λ/ B = 5 mas。如果没有相位参考实现来延长由大气湍流施加的积分时间限制,则不可能达到这种水平的光谱分辨率。对于窄谱特征,我们证明差分V〜2(λ)的精度为±0:01,差分相位Φ(λ)的精度为±1:7 mrad,相当于差分天文测量精度为±1:45 μas。这种新的Keck干涉仪仪器通常用于研究以连续角为参考的高角度分辨率下窄光谱特征的几何形状和位置。通过同时提供频谱和空间信息,还可以探索大于150 km s〜(-1)的速度场的几何形状(例如,旋转圆盘,流入,流出等)。
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