Interpretation of three-dimensional morphology from
cross sections of phycosiphoniform burrows

Bridging the gap from the two-dimensional cross sections commonly seen in core and slabbed material to a three-dimensional interpretation of morphology is a significant challenge for applied ichnologists (McIlroy 2004a, 2008; Bromley and Pedersen 2008). The starting point for this process has to be reliable three-dimensional reconstructions of known taxa; preferably type material. To address the issue of identifying phycosiphoniform burrows from cross-sectional views, we will review and update the model for Phycosiphon incertum for comparison with our phycosiphoniform material from Mexico.

Interpreting "Frogspawn Texture" as Phycosiphon-Generated Ichnofabrics

Phycosiphon is a morphologically complex trace fossil in three dimensions; consequently it has a diverse range of expressions in vertical cross section. These vertical cross sections can closely resemble other phycosiphoniform burrows (e.g., Helminthoidichnites cf. Chamberlain 1978; Nereites cf. Wetzel 2002). The characteristic frogspawn fabric (Bromley 1996) is produced by cross sections of the marginal tube ("embryo") and the spreite or mantle ("jelly"). A number of vertical cross sections of bedding parallel Phycosiphon have been figured by Bromley (1996), and are supplemented by our digitally dissected deterministic model (Figure 5.1-5.3). Since the emendation of the ichnogeneric diagnosis for Phycosiphon (Wetzel and Bromley 1994) includes the possibility of non-bedding parallel lobes, we have created a 3D digital model of Phycosiphon inclined 17^o from the vertical and created virtual vertical cross sections from it (Figure 5.4). The resultant cross- sections include the comma-shaped cross sections so common in outcrop material but not explained by pre-existing hypothetical models (Bromley 1996). The vertically stacked, bent paired marginal tubes not linked to a cross section by Bromley (1996) can also be explained by our model (Figure 5.5).

Comparison of our three-dimensional model, and cross sections obtained from it (Figure 3 and Figure 5), with published cross sections of Phycosiphon (Goldring et al.1991; Wetzel and Bromley 1994; Bromley 1996; Naruse and Nifuku 2008) allows us to confidently state that the model of Bromley (1996) has the potential to produce the full range of Phycosiphon cross sections seen in vertical sections from core. It is thus entirely possible that the Phycosiphon trace maker deposit fed in vertical, oblique or bedding parallel orientations as well as the horizontal orientation seen in the type material. Not encompassed by our three-dimensional model, are twisted lobes, though it is inferred that those would produce broadly similar vertical cross sections to those in Figure 5.4-5.5.