The uplifted Ethiopian plateau region encompasses amagmatic rift basins and basins with nascent seafloor spreading. Rift segments in the Main Ethiopian rift and southern Afar show a distinct structural segmentation, with a south to north reduction in the length, width, and spacing of fault zones; rift segments in northern Afar, where extension exceeds 100%, show a magmatic segmentation. The objectives of remote sensing, gravity, and modeling studies of the Ethiopian plateau area are (1) to summarize morphological patterns along the length of the rift system and (2) to relate variations in effective elastic thickness of the lithosphere within the Ethiopian plateau region to tectonics. Inverse models of new and existing Bouguer gravity data from the rifted regions of the uplifted plateau constrained by seismic data are used to relate the variations in the geometry of the along-axis structural and magmatic segmentation to variations in flexural rigidity. We use the wavelength dependence of the coherence between gravity and topography to estimate the flexural rigidity, or, equivalently, the effective elastic plate thickness (Te), of the lithosphere. Estimates of T e range from 17 + 2 km to 5 + 3/-2 km within the 300-km-wide Afar Depression. These estimates of T e within the rift are considerably less than values found beneath the uplifted but largely unfaulted plateau to the west (T e > 56 km). These results show that the transition from a "continental segmentation" to "oceanic segmentation" corresponds to a decrease in rift basin segment length and the separation of faults and magmatic centers, an increase in magmatic construction, and a marked decrease in effective elastic thickness. We suggest that the length scales of extensional segments prior to the onset of seafloor spreading are controlled primarily by plate strength, at least in rift areas affected by mantle plumes. Introduction Continental rifts and slow spreading oceanic ridges show a number of first-order morphological similarities, despite their distinct differences in crustal/lithospheric thickness, rheology, and magma supply. Both exhibit fault-bounded depressions flanked by escarpments that may rise over 2 km above the valley floor. The faulted rift valleys and flanks show an along-axis structural segmentation, with discrete structural, morphological, and magmatic segments 30-100 km in length in both settings [e.g., Sempere et al., 1993]. Continental segments are separated along their length by oblique-slip faults or magmatic ridges that crosscut the rift valley (accommodation zones), and are analogous kinematically to non-transform offsets of oceanic segments [e.g., Bosworth, 1992; Grindlay and Fox, 1993]. The similarities in structural and magmatic styles, and the similar length scales of the extensional segments suggest that the continental and oceanic lithospheres are responding in similar ways to rifting processes, or that the oceanic segmentation initiates prior to the onset of seafloor spreading. The relationship between continental or oceanic ...
