Pio Lombardo scite author profile

Permeable reactive barriers (PRBs) have gained popularity in recent years as a low-cost method for ground water remediation. However, their cost advantage usually requires that these barriers remain maintenance free for a number of years after installation. In this study, sediment cores were retrieved from a pilot-scale PRB consisting of a sand and wood particle (sawdust) mixture that has been in continuous operation for 15 years treating nitrate from a septic system plume in southern Ontario (Long Point site). Reaction rates for the 15-year-old media were measured in dynamic flow column tests and were compared to rates measured in year 1 using the same reactive mixture. Nitrate removal rates in the 15-year-old media varied, as expected, with temperature in the range of 0.22 to 1.1 mg N/L/d at 6°C to 10°C to 3.5 to 6.0 mg N/L/d at 20°C to 22°C. The latter rates remained within about 50% of the year 1 rates (10.2 6 2.7 mg N/L/d at 22°C). Near the end of the year 15 column test, media particles >0.5 mm in diameter, containing most of the wood particles, were removed from the reactive media by sieving. Nitrate removal subsequently declined by about 80%, indicating that the wood particles were the principal energy source for denitrification. This example shows that some denitrifying PRBs can remain maintenance free and be adequately reactive for decades.

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Wood-Based Filter for Nitrate Removal in Septic Systems

Robertson¹,

Ford²,

Lombardo³

2005

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High‐Permeability Layers for Remediation of Ground Water; Go Wide, Not Deep

et al. 2005

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A nitrate-reactive porous media layer comprising wood particles with very high hydraulic conductivity (K approximately 1 cm/s) was used to successfully treat nitrate in a shallow sand-and-gravel aquifer in southern Ontario. Nitrate concentrations of 1.3 to 14 mg/L as N in the aquifer were attenuated to <0.5 mg/L as N in the reactive layer. Borehole dilution testing indicated that ground water velocities in the reactive layer, although variable, averaged five times higher than in the surrounding aquifer, suggesting that the layer was capturing ground water flow from deeper in the aquifer. The use of high-K reactive media opens up the possibility of installing permeable reactive barriers as horizontal layers in the shallow water table zone that do not necessarily have to penetrate the full depth of a contaminant plume to be effective. Model simulations show that the depth of capture of a high-K layer increases as the layer width in the direction of flow increases. Shallower emplacement could decrease barrier costs at some sites.

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Treatment of Wastewater Phosphate by Reductive Dissolution of Iron: Use of Ferric Oxyhydroxide Media

Robertson

Lombardo²

2011

J of Env Quality

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In smaller wastewater treatment systems such as septic systems, there is an interest in the development of passive phosphorus (P) removal methods. This study tested fixed-bed filters containing ferric oxyhydroxide media for wastewater P removal in a laboratory column test and in a full-scale domestic septic system. In the column test, during 30 mo of dosing with domestic wastewater, reductive iron dissolution reactions delivered consistent moderate concentrations of Fe into solution (2.9 ± 1.6 mg L), and influent PO-P of 3.7 ± 1.0 mg L was attenuated to 0.09 + 0.04 mg L in the column effluent (98% removal). Phosphorus breakthrough at successive locations along the column indicated that in addition to sorption, mineral precipitation reactions probably also played an important role in the observed P attenuation. This was supported by electron microprobe analyses, which showed the presence of thick (20 μm) secondary Fe-rich coatings containing P on the primary ferric media grains. Assays of NaHCO-leachable and acid-extractable P on the column solids showed accumulation of up to 5.4 mg g acid-extractable P near the column inlet, but <5% of this amount was easily desorbable, further indicating P attenuation from processes other than sorption. Over 19 mo of operation, the domestic septic system also showed generally consistent increased Fe in the filter effluent (2.6 ± 1.7 mg L) and achieved 99% P removal to 0.03 ± 0.02 mg L when the effluent was subsequently oxidized in a sand filter. Ferric iron filters could be attractive options for P removal in smaller wastewater systems because of their passive nature.

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Decentralized Wastewater Management Planning: Use of Lot-by-Lot Analysis to Develop Comprehensive Community Wastewater Management Plans

Lombardo¹

2001

proc water environ fed

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Decentralized wastewater management provides significant environmental and economic opportunities to many growing communities. Frequently, the existing wastewater infrastructure of on-site septic systems can be an attractive, sustainable, long-term solution for most areas of a community. However, the necessary planning process poses a multidisciplinary array of challenges that can deter communities from embarking down this path or derail their planning efforts. The advent in recent years of computerized Geographic Information Systems (GIS) technology and the increasing availability of GIS information has made a highly detailed, lot-bylot decentralized planning approach an economically viable and attractive option to many communities. The analytical framework discussed herein provides a robust development and implementation strategy that maximizes the potential for a successful decentralized management plan. This framework provides community officials with a very powerful wastewater planning and management tool that has received overwhelming community validation and approval. This lot-by-lot analytical framework coupled with GIS technology enables communities to reap both the short and long term benefits offered by decentralized wastewater management to a degree that was only possible with manual technologies in the past.

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Pio Lombardo

Nitrate Removal Rates in a 15‐Year‐Old Permeable Reactive Barrier Treating Septic System Nitrate

Wood-Based Filter for Nitrate Removal in Septic Systems

High‐Permeability Layers for Remediation of Ground Water; Go Wide, Not Deep

Treatment of Wastewater Phosphate by Reductive Dissolution of Iron: Use of Ferric Oxyhydroxide Media

Decentralized Wastewater Management Planning: Use of Lot-by-Lot Analysis to Develop Comprehensive Community Wastewater Management Plans

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