Erika L. Patenaude scite author profile

Erika L. Patenaude

4Publications

46Citation Statements Received

70Citation Statements Given

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Affiliations

University of Rhode Island, Kingston University

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Potential Nitrate Leaching Under Common Landscaping Plants

Amador

Hull

Patenaude

et al. 2007

Water Air Soil Pollut

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Studies on N losses from ornamental plantings -other than turf -are scant despite the ubiquity of these landscaping elements. We compared pore water NO 3 and extractable soil NO 3 and NH 4 in areas with turf, areas with seven different types of ornamental landscape plantings, and a native woodland. Turf areas received annual N inputs of~48 kg ha −1 and annual flowers received~24 kg N ha −1 at the time of planting. None of the other areas were fertilized during the course of the study. Data were collected on 23 occasions between June 2002 and November 2003. Pore water NO 3 concentrations at a 60-cm depthbased on pooled data -were highest (1.4 to 7.8 mg NO 3 -N l −1 ) under ground covers, unplanted-mulched areas, turf, deciduous trees, and evergreen trees, with no differences among these vegetation types. Lower values were observed under woodlands, annual and perennial flowers, and evergreen and deciduous shrubs. Pore water NO 3 concentrations exceeded the drinking water regulatory limit of 10 mg NO 3 -N l −1 under ground covers, turf and unplanted-mulched areas in 39, 20 and 10% of samples, respectively. Leaching losses of NO 3 -N over 18 months ranged from 0.17 kg N ha −1 in the woodlands to 34.97 kg N ha −1 under ground covers. Annual NO 3 losses under unplantedmulched areas and ground covers were approximately twice the average N input (10 kg N ha −1 year −1 ) from atmospheric deposition. Extractable NO 3 in woodland soils (0.5 μg NO 3 -N g −1 ) was lower than for all other vegetation types (3.1-7.8 μg NO 3 -N g −1 ). Extractable NH 4 levels were highest in woodlands, deciduous trees, and annual flowers (6.7-10.1 μg NH 4 -N g −1 ). Most vegetation types appear to act as net N sinks relative to atmospheric inputs, whereas unplantedmulched areas and areas planted with ground covers act as net sources of NO 3 to groundwater.

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Effects of Sand Depth on Domestic Wastewater Renovation in Intermittently Aerated Leachfield Mesocosms

et al. 2008

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The depth of soil below the absorption trench of a septic system is considered an important factor in protection of groundwater. We examined the effects of depth on the ability of intermittently aerated sand-filled leachfield mesocosms to renovate domestic wastewater. Mesocosms ͑n =3͒ consisted of lysimeters with a headspace O 2 concentration maintained at 0.21 mol/ mol and containing 7.5, 15, or 30 cm of sand that were dosed with septic tank effluent every 6 h for 328 days ͑12 cm/ d͒. Sand depth had no effect on pH, dissolved O 2 , PO 4 , NH 4 , or BOD 5 levels in percolate water. Nitrate levels in percolate water were higher for 30 cm than for 7.5 and 15 cm during the first 70 d of the experiment, after which no differences were observed. Time-averaged removal rates of N, P, fecal coliform bacteria, and BOD 5 were 22-28, 13-18, 81-92, and 81-99%, respectively, and were unaffected by depth. Wastewater renovation in intermittently aerated leachfield mesocosms appears to take place in a narrow zone ͑Յ7.5 cm͒ below the infiltrative surface, with the medium below contributing little to renovation.

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Effects of tetracycline on water quality, soil and gases in aerated and unaerated leachfield mesocosms

Patenaude

Atoyan

Potts

et al. 2008

Journal of Environmental Science and Health, Part A

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We examined the effects of tetracycline (TET) addition on the function of mesocosms representing aerated and unaerated septic system leachfields. Replicate mesocosms (n = 3) were filled with soil and either vented to a leachfield (LEACH) or aerated intermittently to maintain an O(2) level of approximately 0.21 mol mol(-1) (AIR). All mesocosms were dosed every 6 h for 10 d with 3 cm of domestic wastewater amended with 5 mg TET L(-1). Water quality parameters, headspace gas composition, and soil properties were measured prior to and during the dosing period, and for 42 days after the last antibiotic dose. No significant effect of TET was observed on the pH, level of dissolved O(2) or dissolved organic carbon (DOC) in drainage water from either treatment. In contrast, levels of Fe(2+) and SO(4) in drainage water from LEACH mesocosms decreased in response to TET dosing, with lower levels persisting until Day 52. Persistent increases were observed in the level of NO(3) in drainage water from AIR lysimeters and in NH(4) in LEACH mesocosms in response to TET additions. Removal of total P and DOC were unaffected by TET dosing in either treatment. Nitrogen removal in AIR mesocosms decreased during the TET dosing period, returning to pre-dosing values by Day 52. In contrast, TN removal in LEACH mesocosms increased during TET dosing, returning to pre-dosing values by Day 52. The composition of headspace gases in AIR mesocosms was not affected by tetracycline dosing. TET dosing resulted in significant increases in soil NH(4) concentration in LEACH mesocosms, whereas significant decreases were apparent in AIR mesocosms. Elevated levels of H(2)S and CH(4) in the headspace of LEACH mesocosms coincided with TET dosing and returned to pre-dosing levels when antibiotic dosing ceased. The effects of tetracycline on leachfield mesocosms differed as a function of aeration. Although most effects were transient, with values returning to pre-dosing levels after a 6-week recovery period in both treatments, persistent effects were observed in LEACH mesocosms.

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Effects of tetracycline on antibiotic resistance and removal of fecal indicator bacteria in aerated and unaerated leachfield mesocosms

Atoyan

Patenaude

Potts

et al. 2007

Journal of Environmental Science and Health, Part A

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Antibiotics can be present in low concentrations in domestic wastewater, but little is known about their effect on bacteria in onsite wastewater treatment systems. Mesocosms, consisting of soil-filled lysimeters representing the leachfield of a septic system under aerated (AIR) and unaerated (LEACH) conditions, were used to study the effects of tetracycline addition (5 mg L(-1)) to septic tank effluent on tetracycline resistance in the fecal indicator bacteria Escherichia coli and fecal streptococci, and on their removal. The mesocosms were dosed with antibiotic for 10 days, and effects monitored for 52 days. The fraction of resistant bacteria in mesocosm drainage water relative to that in septic tank effluent, GammaRes, for E. coli ranged from 0 to 0.66 in the AIR treatment and from 0 to 3.32 in the LEACH treatment. For fecal streptococci, GammaRes ranged from 0 to 0.41 and from 0.63 to 1.06 in the AIR and LEACH treatments, respectively. No significant differences in antibiotic resistance of fecal indicator bacteria were observed among sampling dates in soil or water from either treatment. Tetracycline had no significant effect on removal of fecal indicator bacteria, which ranged from 99.9 to 100% for E. coli and from 95.9 to 100% for fecal streptococci. Our results suggest that short-term addition of tetracycline at environmentally-relevant concentrations is likely to have minimal consequences on pathogen removal from wastewater and development of antibiotic resistance among pathogenic bacteria in leachfield soil.

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