Integrating electrical resistivity tomography and ground-penetrating radar methods to map archaeological walls near northern Ishtar gate, ancient Babylon city, Iraq

IF 2.1 3区 地球科学 0 ARCHAEOLOGY
Mohammed M. AL-Hameedawi, Jassim M. Thabit, Firas H. AL-Menshed, Lawrence Conyers
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引用次数: 2

Abstract

Electrical resistivity tomography (ERT) and ground-penetrating radar (GPR) were collected on the eastern side of the northern Ishtar gate in ancient Babylon, Iraq, to locate the palace wall and other surrounding walls. Due to the presence of a low resistivity (highly conductive) top layer associated with brick rubble and other debris, the GPR reflection profiles show a high-energy attenuation, but a series of processing and filtering steps produced coherent reflections of about 2 m depth. Profile analysis shows the geometry and layering of the walls and the surrounding matrix. With the ERT, the surface conductive zone produces various distortions in ERT inverse models, making identifying the features' lower boundaries difficult. Here, we suggest that instead of analysing these two data sets independently, the integration of both reveals not just the walls but their composition and defines material in the surrounding units. This integration shows how the interpretation of the shallow features on the 3D ERT maps is improved by comparison and interpretation in conjunction with the reflections visible on both reflection profiles and the 3D GPR amplitude slices. The orientation of these features and reflections emphasizes the existence of one series of buried walls at a depth of 90–150 cm. The thickness of these walls varies between 0.25 and 1 m. Another wall-like feature is visible only on 3D ERT maps and not with the 3D GPR slices at 2 m depth, which indicates a thickness of 11 m. It is interpreted as the palace wall, which is consistent with earlier archaeological excavations. An analysis of the geometry and composition of both wall components, perhaps of different ages, and constructed for different reasons, indicates that some shallower walls may be the remains of rooms built as residences for soldiers, or they may belong to the other ruins of northern Ishtar gate.

结合电阻率层析成像和探地雷达方法绘制伊拉克古巴比伦城北伊什塔尔门附近的考古城墙
电阻率断层扫描(ERT)和探地雷达(GPR)在伊拉克古巴比伦北伊什塔尔门东侧收集,以确定宫殿墙壁和其他周围墙壁的位置。由于低电阻率(高导电性)顶层与砖屑和其他碎屑相关,GPR反射剖面显示出高能量衰减,但一系列处理和滤波步骤产生了约2 m深度的相干反射。剖面分析显示了墙壁和周围基质的几何形状和分层。在ERT反演模型中,表面导电区会产生各种畸变,使得识别特征的下边界变得困难。在这里,我们建议不要单独分析这两个数据集,而是将两者结合起来,不仅揭示了墙壁,还揭示了它们的组成,并定义了周围单元的材料。这一整合显示了如何通过与反射剖面和3D GPR振幅切片上可见的反射进行比较和解释来改进3D ERT地图上浅层特征的解释。这些特征和反射的方向强调了在90-150厘米深度的一系列埋墙的存在。这些壁的厚度在0.25到1米之间。另一个壁状特征仅在3D ERT地图上可见,而在2米深度的3D GPR切片上则不可见,这表明厚度为11米。它被解释为宫殿的城墙,这与早期的考古发掘相一致。对这两堵墙的几何形状和组成的分析,可能是不同的年代,出于不同的原因而建造的,表明一些较浅的墙可能是作为士兵住所建造的房间的遗迹,或者它们可能属于北伊什塔尔门的其他废墟。
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来源期刊
Archaeological Prospection
Archaeological Prospection 地学-地球科学综合
CiteScore
3.90
自引率
11.10%
发文量
31
审稿时长
>12 weeks
期刊介绍: The scope of the Journal will be international, covering urban, rural and marine environments and the full range of underlying geology. The Journal will contain articles relating to the use of a wide range of propecting techniques, including remote sensing (airborne and satellite), geophysical (e.g. resistivity, magnetometry) and geochemical (e.g. organic markers, soil phosphate). Reports and field evaluations of new techniques will be welcomed. Contributions will be encouraged on the application of relevant software, including G.I.S. analysis, to the data derived from prospection techniques and cartographic analysis of early maps. Reports on integrated site evaluations and follow-up site investigations will be particularly encouraged. The Journal will welcome contributions, in the form of short (field) reports, on the application of prospection techniques in support of comprehensive land-use studies. The Journal will, as appropriate, contain book reviews, conference and meeting reviews, and software evaluation. All papers will be subjected to peer review.
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