Papers Published

1. Schuler, A. and Xiao, Y., Predicted distributed state effects on EBPR in a 5-stage Bardenpho wastewater treatment configuration, Water Env. Res., (In press),
2. Lautenschlager, S.R., F.A. DiGiano, A.J. Schuler and S.S.F. Filho, Net water production model for ultrafiltration including flow direction reversal and chemically assisted backwashing, Water Environ. Res., (2007), 877-886,
3. Schuler, A.J. and D. Jassb, Distributed state simulation of endogenous processes in biological wastewater treatment, Biotechnol. Bioeng., (2007), 1087-1097,
4. Schuler, A.J., and H. Jang, Microsphere addition for the study of biomass properties and density effects on settleability in biological wastewater treatment systems, Water Res., (2007), 2163-2170,
5. Schuler, A.J., H. Jang, Causes of variable biomass density and effects on settling in full scale biological wastewater treatment systems, Environ. Sci. Technol., (2007), 1675-1681,
6. Schuler, A.J., and H. Jang, Density effects on activated sludge zone settling velocities, Water Res., (2007), 1814-1822,
7. Schuler, A.J. and Jassby, D., The filament threshold effect on activated sludge bulking: Artifact or reality?, Water Res., (2007), 4349-4356,
8. Jang, H., A.J. Schuler, The case for variable density: A new perspective on activated sludge settling, Water Environ. Res., (2007), 2298-2303,
9. Schuler, A.J., Distributed microbial state effects on competition in enhanced biological phosphorus removal systems, Water Science and Technology, (2006), 199 - 207, [388], [abs]
10. Schuler, A.J., Process hydraulics, distributed bacterial states, and biological wastewater treatment system performance, Biotechnol. Bioeng., (2006), 909-920,
11. Schuler, A.J., Diversity matters: Dynamic simulation of distributed bacterial states in suspended growth biological wastewater treatment systems, Biotechnol. Bioeng., (2005), 62-74,
12. Schuler, Andrew J. and Jenkins, David, Enhanced biological phosphorus removal from wastewater by biomass with different phosphorus contents, part II: Anaerobic adenosine triphosphate utilization and acetate uptake rates, Water Environment Research, (2003), 499 - 511, [abs]
13. Schuler, Andrew J. and Jenkins, David, Enhanced biological phosphorus removal from wastewater by biomass with different phosphorus contents, part I: Experimental results and comparison with metabolic models, Water Environment Research, (2003), 485 - 498, [abs]
14. Schuler, Andrew J. and Jenkins, David, Enhanced biological phosphorus removal from wastewater by biomass with different phosphorus contents, part III: Anaerobic sources of reducing equivalents, Water Environment Research, (2003), 512 - 522, [abs]
15. Schuler, A.J. and Onuki, M. and Satoh, H. and Mino, T., Density separation and molecular methods to characterize enhanced biological phosphorus removal system populations, Water Science and Technology, (2002), 195 - 198, [abs]
16. Schuler, A.J. and Jenkins, D., Effects of pH on enhanced biological phosphorus removal metabolisms, Water Science and Technology, (2002), 171 - 178, [abs]
17. Schuler, A.J., D. Jenkins, and P. Ronen, Microbial storage products, biomass density, and settling properties of enhanced biological phosphorus removal activated sludge, Water Sci. Technol., (2001), 173-180,
18. Crocetti, G.R., P. Hugenholtz, P.L. Bond, A.J. Schuler, J. Keller, D. Jenkins, and L.L. Blackall, Identification of polyphosphate accumulating organisms and the design of 16S rRNA-directed probes for their detection and quantitation, Appl. Environ. Microbiol., (2000), 1175-1182,
19. Pramanik, J. and Trelstad, P.L. and Schuler, A.J. and Jenkins, D. and Keasling, J.D., Development and validation of a flux-based stoichiometric model for enhanced biological phosphorus removal metabolism, Water Research, (1999), 462 - 476, [S0043-1354(98)00225-5], [abs]