@article {999, title = {The persistence of memory: The fate of ancient sedimentary organic carbon in a modern sedimentary system}, journal = {Geochimica Et Cosmochimica Acta}, volume = {67}, year = {2003}, note = {634jvTimes Cited:143Cited References Count:63}, month = {Jan}, pages = {63-73}, abstract = {The cycle of organic carbon burial and exhumation moderates atmospheric chemistry and global climate over geologic timescales. The burial of organic carbon occurs predominantly at sea in association with clay-sized particles derived from the erosion of uplifted continental rocks. It follows that the history of the fine-grained particles on land may bear on the nature of the organic carbon buried. In this study, the evolution of clay-associated organic matter was followed from bedrock source to the seabed in the Eel River sedimentary system of northern California using natural abundance C-13 and C-14 tracers. Approximately half of the fine-grained organic carbon delivered to the shelf is derived from ancient sedimentary organic carbon found in the uplifted Mesozoic-Tertiary Franciscan Complex of the watershed. The short residence time of friable soils on steep hill slopes, coupled with rapid sediment accumulation rates on the shelf-slope, act to preserve the ancient organic carbon. A comparable quantity of modem organic carbon is added to particles in the watershed and on the shelf and slope. The bimodal mixture of ancient and modem C in soils and sediments may be characteristic of many short, mountainous rivers. If the Eel River chemistry is typical of such rivers, more than 40 Tg of ancient organic C may be delivered to the world{\textquoteright}s oceans each year. A flux of that magnitude would have a significant influence on marine and global C-cycles. Copyright (C) 2003 Elsevier Science Ltd.}, issn = {0016-7037}, doi = {10.1016/S0016-7037(02)01043-8}, author = {Blair, N. E. and Leithold, E. L. and Ford, S. T. and Peeler, K. A. and Holmes, J. C. and Perkey, D. W.} }