“Seismic facies analysis of shallowly buried channels, New Jersey continental shelf:  understanding late Quaternary paleoenvironments during the last transgression” 

Sylvia Nordfjord^1,2, John A. Goff¹, James A. Austin, Jr. ¹, Sean P.S. Gulick¹, Christopher Sommerfield³, Steven Schock⁴

¹University of Texas Institute for Geophysics, John A. and Katherine G. Jackson School of Geosciences, 4412 Spicewood Springs Road, Bldg. 600, Austin, TX 78759-8500

²University of Texas at Austin, Department of Geological Sciences, John A. and Katherine G. Jackson School of Geosciences, 1 University Station C1100, Austin, TX 78712

³College of Marine Studies, University of Delaware, 700 Pilottown Road, Lewes, DE 19958-1298

⁴Department of Ocean Engineering, Florida Atlantic University, 777 Glades Road, Boca Raton, Florida 33431

We are investigating the late Quaternary sedimentary record of the New Jersey mid-outer continental shelf using deep-towed chirp sonar (1-4 kHz and 1-15 kHz) profiles, coupled with lithologic and chronostratigraphic control from long sediment cores collected using the DOSECC AHC-800 drilling system. We have seismically mapped extensive, shallowly buried, dendritic drainage systems; individual channels are typically box-shaped in cross-section, with width-depth ratios of >35, suggesting that these are bed-load channels. Observed seismic facies distributions suggest the complex nature of channel fills, and synthetic seismograms derived from MST logs enable us to correlate the chirp data to changes in lithology and physical properties of the cored samples, including channel fills, confirming that fine-grained material is transparent seismically, while interbedded sand and mud produce laminated reflections. Using our new data, with previous interpretations, we suggest that these channels probably formed subaerially during or after the last lowstand, ~22-20 ka.  Remnants of fluvial coarse-grained deposits may be represented by chaotic acoustic patterns in the bases of many channel fills. We interpret complex re-excavation surfaces within incised valley system-fills as sequential episodes of cut-and-fill, associated with changes in paleo-flow conditions.  A seismic transition upward from chaotic to flat-lying reflections and more transparent facies indicates less depositional energy, suggesting replacement of fluvial systems by tidal/estuarine environments. This has been confirmed by previous vibra-coring of one channel.  Our paleo-flow reconstructions also yield velocities in the range of 0.5-1.5 m/s, which are reasonable estimates for flows in estuarine environments.