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[1]
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Phosphorus removal by steel slag from tile drainage water: Lab and field evaluations
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Chemosphere,
2022 |
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[2]
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Phosphate and Nitrate Removal from Impacted Waters by Combined Physical-Chemical and Microbiological Transformations
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2022 |
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[3]
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Thou shall not flow: assessing magnitudes and processes of dissolved reactive phosphorus (P) removal by P-sorbing materials
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2021 |
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[4]
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Applying a Statistical Approach to Develop a Sustainable Technology for Capturing Phosphorous from an Agricultural Tile Drainage System Using By-Product …
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2021 |
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[5]
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Introduction to P‐TRAP software for designing phosphorus removal structures
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2021 |
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[6]
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Balancing Hydraulic Control and Phosphorus Removal in Bioretention Media Amended with Drinking Water Treatment Residuals
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2021 |
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[7]
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Estimating the variability of steel slag properties and their influence in phosphorus removal ability
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2021 |
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[8]
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Nitrate and Phosphate Removal from Denitrification Bioreactors Using Woodchips, Steel Chips and Agricultural Residue Media
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2021 |
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[9]
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Utilization of Steel Slag in Blind Inlets for Dissolved Phosphorus Removal
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2020 |
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[10]
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Performance of field-scale phosphorus removal structures utilizing steel slag for treatment of subsurface drainage
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2020 |
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[11]
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THE USE AND BEHAVIOR OF SORPTION MEDIA IN MITIGATING EXCESSIVE DISSOLVED PHOSPHORUS IN SURFACE WATERS
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2020 |
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[12]
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Performance of Field-Scale Phosphorus Removal Structures Utilizing Steel Slag for Treatment of Surface and Subsurface Drainage
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2020 |
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[13]
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Using Steel Slag for Dissolved Phosphorus Removal: Insights from a Designed Flow-Through Laboratory Experimental Structure
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2020 |
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[14]
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Performance of a Ditch-Style Phosphorus Removal Structure for Treating Agricultural Drainage Water with Aluminum-Treated Steel Slag
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2020 |
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[15]
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Aerated and unaerated steel slag filter systems as polishing unit for phosphorus removal from textile industrial effluent
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2020 |
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[16]
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Pilot Scale Evaluation of E. Coli Filtration Removal From Stormwater Using Recycled Steel
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2019 |
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[17]
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The past, present, and future of blind inlets as a surface water best management practice
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2019 |
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[18]
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A Novel Coating Method for Create Filter MediaCapable to Remove Phosphate fromWastewater Effectively: A Novel Coating Method for Create Filter MediaCapable to …
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2019 |
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[19]
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A novel method to rapidly assess the suitability of water treatment residual and crushed concrete for the mitigation of point and nonpoint source nutrient …
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2019 |
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[20]
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Soil phosphorus dynamics following land application of unsaturated and partially saturated red mud and water treatment residuals
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2019 |
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[21]
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Optimal regulation of N/P in horizontal sub-surface flow constructed wetland through quantitative phosphorus removal by steel slag fed
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2019 |
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[22]
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Mechanisms of Phosphorus Removal by Phosphorus Sorbing Materials
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Journal of Environmental Quality,
2018 |
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[23]
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The Challenges of Managing Legacy Phosphorus Losses from Manure-Impacted Agricultural Soils
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Current Pollution Reports,
2018 |
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[24]
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CHEMICAL INTERACTIONS OF CITRATE, CALCIUM AND PHOSPHATE IN A CALCAREOUS SASKATCHEWAN SUBSOIL
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2018 |
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[25]
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Phosphorus Removal Structures as a Short-Term Solution for the Problem of Dissolved Phosphorus Transport to Surface Waters
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Design and Construction of Phosphorus Removal Structures for Improving Water Quality,
2018 |
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[26]
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REVERSIBLE SORPTION OF PHOSPHORUS ON ZIRCONIA AND DESIGN OF ADSORPTION UNIT FOR PHOSPHORUS POLLUTION ABATEMENT
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2018 |
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[27]
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Denitrifying woodchip bioreactor and phosphorus filter pairing to minimize pollution swapping
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Water Research,
2017 |
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[28]
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A feasibility study in the use of domestic water treatment residuals to remove phosphorus from wastewater
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2017 |
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[29]
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A Review of Phosphorus Removal Structures: How to Assess and Compare Their Performance
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Water,
2017 |
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[30]
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Elements of precision manure management
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Precision Conservation: Geospatial Techniques for Agricultural and Natural Resources Conservation,
2017 |
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[31]
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Phosphorus Retention and Regeneration of EAF Steel Slag and a Synthetic Iron Oxyhydroxide
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Dissertation, Ohio State University,
2017 |
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[32]
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Removal of Water-Extractable Phosphorus from Dairy Manure
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Dissertation, Ohio State University,
2017 |
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[33]
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An Experimental Investigation Into the Efficiency of Filter Materials for Phosphate Removal from Wastewater
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2017 |
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[34]
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Reuse of Steel Stag for Resourc
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2017 |
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[35]
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Phosphorus and Metal Sorption in Aged Bioretention Cells with Fly-ash Amended Filter Media
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ProQuest Dissertations Publishing,
2016 |
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[36]
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Filtration curtains for phosphorus harvesting from small water bodies
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Ecological Engineering,
2016 |
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[37]
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Evaluation of a universal flow-through model for predicting and designing phosphorus removal structures
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Chemosphere,
2016 |
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[38]
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Production and applications of electric-arc-furnace slag as solid waste in environmental technologies: a review
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Environmental Technology Reviews,
2016 |
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[39]
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Agricultural Drainage Filters. II. Phosphorus Retention and Release at Different Flow Rates
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Water, Air, & Soil Pollution,
2016 |
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[40]
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Evaluating Steel Byproducts and Natural Minerals for Phosphate Adsorption from Agricultural Subsurface Drainage
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2016 |
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[41]
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Appropriate technology for domestic wastewater management in under-resourced regions of the world
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Applied Water Science,
2016 |
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[42]
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Design, quantification, and demonstration of large scale phosphorus removal structures in Oklahoma
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ProQuest Dissertations Publishing,
2015 |
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[43]
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Evaluation of sorption behavior of two reactive filter materials using dual column laboratory investigation.
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Thesis,
2015 |
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[44]
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Modelling of phosphate retention by Ca-and Fe-rich filter materials under flow-through conditions
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Ecological Engineering,
2015 |
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[45]
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Use of Industrial Wastes as Media in Constructed Wetlands and Filter Beds–Prospects for Removal of Phosphate and Metals from Wastewater Streams
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Critical Reviews in Environmental Science and Technology,
2014 |
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[46]
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Chemistry and Application of Industrial By-products to Animal Manure for Reducing Phosphorus Losses to Surface Waters
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Applied Manure and Nutrient Chemistry for Sustainable Agriculture and Environment. Springer Netherlands,
2014 |
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[47]
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A simplified transfer function for estimating saturated hydraulic conductivity of porous drainage filters
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Water, Air, & Soil Pollution,
2014 |
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[48]
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Phosphorus removal structures: A management option for legacy phosphorus
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Journal of Soil and Water Conservation,
2014 |
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[49]
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Application of Isothermal Calorimetry to Phosphorus Sorption onto Soils in a Flow-through System
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Soil Science Society of America Journal,
2014 |
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[50]
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A three-step test of phosphate sorption efficiency of potential agricultural drainage filter materials
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Water research,
2014 |
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[51]
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Removing phosphorus with Ca-Fe oxide granules–a possible wetlands filter material
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Hydrology Research,
2014 |
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[52]
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Application of isothermal calorimetry to phosphorus sorption onto soils in a flow‐through system
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2014 |
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[53]
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Effectiveness of filtering materials for reducing phosphorus losses from drained agricultural fields in Flanders, Belgium
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Thesis,
2014 |
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[54]
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A modelling approach to the design of in situ agricultural drainage filters
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Soil Use and Management,
2013 |
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[55]
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Phosphorus Removal From Stormwater Using Electric Arc Furnace Steel Slag
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NULL
2013 |
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[56]
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Application of isothermal calorimetry to the study of phosphorus sorption onto soils in a flow-through system
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2013 Kansas City, Missouri, July 21-July 24, 2013,
2013 |
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[57]
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Phosphorus Reduction in Runoff Using a Steel Slag Trench Filter System
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NULL
2012 |
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[58]
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Removing phosphorus from surface and drainage waters through use of industrial by-products
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US Patent App. 13/447,956,
2012 |
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[59]
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Effect of land application of phosphorus-saturated gypsum on soil phosphorus in a laboratory incubation
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Applied and Environmental Soil Science,
2012 |
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[60]
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Trapping phosphorus in runoff with a phosphorus removal structure
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Journal of environmental quality,
2012 |
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[61]
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Emerging technologies for removing nonpoint phosphorus from surface water and groundwater: Introduction
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Journal of environmental quality,
2012 |
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[62]
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Phosphorus removal with by-products in a flow-through setting
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Journal of environmental quality,
2012 |
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[63]
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Potential and limitations of phosphate retention media in water protection: A process-based review of laboratory and field-scale tests
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Agricultural and Food Science,
2012 |
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[64]
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Phosphorus removal with by‐products in a flow‐through setting
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2012 |
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[65]
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Phosphate removal in water by mesostructure based on titanium and silica
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2011 |
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[66]
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Chemical Amendment of Dairy Slurry For The Control of
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2011 |
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[67]
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Chemical Amendment of Dairy Slurry For The Control of Phosphorus in Runoff From Grassland
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NULL
2011 |
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[68]
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Correll, DL 1998. The role of phosphorus in the eutrophication of receiving waters: a review. J. Environ. Qual. 27: 261-266.
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INDUSTRIAL BY-PRODUCT CHARACTERIZATION FOR PHOSPHORUS REMOVAL IN ENVIRONMENTAL CONTAMINANT FILTERS,
2011 |
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