M. Papoutsis, I. E. Papadakis, C. Panagiotou, M. Dovčiak, E. Kammoun
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Our primary objective is to\ninvestigate whether, in addition to time lags, the X-ray reverberation model\ncan also explain the UV/optical variability amplitude of nearby Seyferts. To do\nthis, we measured the excess variance of four sources (namely Mrk 509, NGC\n4151, NGC 2617, and Mrk 142) as a function of wavelength using data from\narchival long, multi-wavelength campaigns with Swift, and ground-based\ntelescopes. We also computed the model excess variance in the case of the X-ray\nreverberation model by determining the disc's transfer function and assuming a\nbending power law for the X-ray power spectrum. We tested the validity of the\nmodel by comparing the measured and model variances for a range of accretion\nrates and X-ray source heights. We conclude that the X-ray thermal\nreverberation model can fit both the continuum, UV/optical time lags, as well\nas the variance in these AGNs, for the same physical parameters. Our results\nsuggest that the accretion disc is constant and that all the observed\nUV/optical variations, on timescales of days and up to a few weeks, can be\nfully explained by the variable X-rays as they illuminate the accretion disc.","PeriodicalId":501343,"journal":{"name":"arXiv - PHYS - High Energy Astrophysical Phenomena","volume":"35 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"X-ray reverberation as an explanation for UV/optical variability in nearby Seyferts\",\"authors\":\"M. Papoutsis, I. E. Papadakis, C. Panagiotou, M. Dovčiak, E. Kammoun\",\"doi\":\"arxiv-2409.10417\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Active galactic nuclei (AGNs) are known to be variable across all\\nwavelengths. 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引用次数: 0
摘要
众所周知,活动星系核(AGN)在所有波长上都是可变的。在过去的十年里,人们投入了大量的观测力量来研究它们的紫外线(UV)和光学变异性。为了确定 X 射线/紫外/光学连续时滞,对许多赛弗星系进行了长时间和密集采样的多波长监测活动。时滞研究可用于约束理论模型。观测到的时滞可以用照射吸积盘的 X 射线的热再处理来解释(称为 X 射线混响模型)。然而,观测到的光变曲线包含更多信息,可以用来进一步约束物理模型。我们的主要目的是研究除了时滞之外,X射线混响模型是否还能解释附近赛弗星的紫外/光学变率振幅。为此,我们利用 Swift 和地基望远镜的长波长、多波长活动的存档数据,测量了四个源(即 Mrk 509、NGC4151、NGC 2617 和 Mrk 142)的超变异与波长的函数关系。我们还通过确定圆盘的传递函数和假定 X 射线功率谱的阶跃幂律,计算了 X 射线反褶模型的模型超方差。我们通过比较一系列增殖速度和 X 射线源高度的测量方差和模型方差,检验了模型的有效性。我们得出的结论是,在相同物理参数下,X射线热反响模型可以同时拟合连续波、紫外/光学时滞以及这些AGN的方差。我们的研究结果表明,吸积盘是恒定的,所有观测到的紫外/光学变化,从几天到几周的时间尺度,都可以用可变的 X 射线照亮吸积盘来解释。
X-ray reverberation as an explanation for UV/optical variability in nearby Seyferts
Active galactic nuclei (AGNs) are known to be variable across all
wavelengths. Significant observational efforts have been invested in the last
decade in studying their ultraviolet (UV) and optical variability. Long and
densely sampled, multi-wavelength monitoring campaigns of numerous Seyfert
galaxies have been conducted with the aim of determining the X-ray/UV/optical
continuum time lags. Time-lag studies can be used to constrain theoretical
models. The observed time lags can be explained by thermal reprocessing of the
X-rays illuminating the accretion disc (known as the X-ray reverberation
model). However, the observed light curves contain more information that can be
used to further constrain physical models. Our primary objective is to
investigate whether, in addition to time lags, the X-ray reverberation model
can also explain the UV/optical variability amplitude of nearby Seyferts. To do
this, we measured the excess variance of four sources (namely Mrk 509, NGC
4151, NGC 2617, and Mrk 142) as a function of wavelength using data from
archival long, multi-wavelength campaigns with Swift, and ground-based
telescopes. We also computed the model excess variance in the case of the X-ray
reverberation model by determining the disc's transfer function and assuming a
bending power law for the X-ray power spectrum. We tested the validity of the
model by comparing the measured and model variances for a range of accretion
rates and X-ray source heights. We conclude that the X-ray thermal
reverberation model can fit both the continuum, UV/optical time lags, as well
as the variance in these AGNs, for the same physical parameters. Our results
suggest that the accretion disc is constant and that all the observed
UV/optical variations, on timescales of days and up to a few weeks, can be
fully explained by the variable X-rays as they illuminate the accretion disc.