Modern space/time geostatistics using river distances: data integration of turbidity and E. coli measurements to assess fecal contamination along the Raritan River in New Jersey.

Escherichia coli (E. coli) is a widely used indicator of fecal contamination in water bodies. External contact and subsequent ingestion of bacteria coming from fecal contamination can lead to harmful health effects. Since E. coli data are sometimes limited, the objective of this study is to use secondary information in the form of turbidity to improve the assessment of E. coli at unmonitored locations. We obtained all E. coli and turbidity monitoring data available from existing monitoring networks for the 2000-2006 time period for the Raritan River Basin, New Jersey. Using collocated measurements, we developed a predictive model of E. coli from turbidity data. Using this model, soft data are constructed for E. coli given turbidity measurements at 739 space/time locations where only turbidity was measured. Finally, the Bayesian Maximum Entropy (BME) method of modern space/time geostatistics was used for the data integration of monitored and predicted E. coli data to produce maps showing E. coli concentration estimated daily across the river basin. The addition of soft data in conjunction with the use of river distances reduced estimation error by about 30%. Furthermore, based on these maps, up to 35% of river miles in the Raritan Basin had a probability of E coli impairment greater than 90% on the most polluted day of the study period.

[1]  George Christakos,et al.  Bayesian Maximum Entropy Analysis and Mapping: A Farewell to Kriging Estimators? , 1998 .

[2]  Patrick Bogaert,et al.  Temporal GIS: Advanced Functions for Field-Based Applications , 2002 .

[3]  N. Cressie The origins of kriging , 1990 .

[5]  G. Sayler,et al.  Distribution and Significance of Fecal Indicator Organisms in the Upper Chesapeake Bay , 1975, Applied and environmental microbiology.

[6]  Keith E. Schilling,et al.  Cokriging estimation of daily suspended sediment loads , 2006 .

[7]  C. Fouquet,et al.  Modèles géostatistiques de concentrations ou de débits le long des cours d'eau , 2006 .

[8]  D. Washington,et al.  Standard Methods for the Examination of Water and Wastewater , 1971 .

[9]  George Christakos,et al.  Modern Spatiotemporal Geostatistics , 2000 .

[10]  M. Serre,et al.  Covariance models for directed tree river networks , 2008 .

[11]  S. Weisberg,et al.  Comparison and Verification of Bacterial Water Quality Indicator Measurement Methods Using Ambient Coastal Water Samples , 2006, Environmental monitoring and assessment.

[12]  Michael J. Sale,et al.  Cokriging to assess regional stream quality in the Southern Blue Ridge Province , 1990 .

[13]  Witold F. Krajewski,et al.  Stochastic interpolation of rainfall data from rain gages and radar using Cokriging: 2. Results , 1990 .

[14]  J. Hoef,et al.  Spatial statistical models that use flow and stream distance , 2006, Environmental and Ecological Statistics.

[15]  Stephen B. Weisberg,et al.  Comparison of Beach Bacterial Water Quality Indicator Measurement Methods , 2003, Environmental monitoring and assessment.

[16]  Roger Woodard,et al.  Interpolation of Spatial Data: Some Theory for Kriging , 1999, Technometrics.

[17]  Joseph N. LoBuglio,et al.  Cost‐effective water quality assessment through the integration of monitoring data and modeling results , 2007 .

[18]  Pierre Payment,et al.  Pathogen and indicator variability in a heavily impacted watershed. , 2007, Journal of water and health.

[19]  Marc L. Serre,et al.  Modern geostatistics: computational BME analysis in the light of uncertain physical knowledge – the Equus Beds study , 1999 .

[20]  G. Christakos,et al.  Computational investigations of Bayesian maximum entropy spatiotemporal mapping , 1998 .

[21]  Marc L Serre,et al.  Spatiotemporal nonattainment assessment of surface water tetrachloroethylene in New Jersey. , 2007, Journal of environmental quality.

[22]  N. Cressie,et al.  Spatial prediction on a river network , 2006 .

[23]  Stanley B Grant,et al.  Scaling and management of fecal indicator bacteria in runoff from a coastal urban watershed in southern California. , 2004, Environmental science & technology.

[24]  G. Christakos A Bayesian/maximum-entropy view to the spatial estimation problem , 1990 .

[25]  Marc L Serre,et al.  Using river distances in the space/time estimation of dissolved oxygen along two impaired river networks in New Jersey. , 2009, Water research.

[26]  M. Mallin,et al.  EFFECT OF HUMAN DEVELOPMENT ON BACTERIOLOGICAL WATER QUALITY IN COASTAL WATERSHEDS , 2000 .

[27]  J. Delhomme Kriging in the hydrosciences , 1978 .

[28]  L. Tedesco,et al.  Direct and indirect hydrological controls on E. coli concentration and loading in midwestern streams. , 2008, Journal of environmental quality.

[29]  Timothy C. Coburn,et al.  Geostatistics for Natural Resources Evaluation , 2000, Technometrics.

[30]  N. S. Urquhart,et al.  Predicting Water Quality Impaired Stream Segments using Landscape-Scale Data and a Regional Geostatistical Model: A Case Study in Maryland , 2006, Environmental monitoring and assessment.