Performance of deep-rooted phreatophytic trees at a site containing total petroleum hydrocarbons.
Identifieur interne : 002559 ( Main/Exploration ); précédent : 002558; suivant : 002560Performance of deep-rooted phreatophytic trees at a site containing total petroleum hydrocarbons.
Auteurs : Ari M. Ferro [États-Unis] ; Tareq Adham ; Brett Berra ; David TsaoSource :
- International journal of phytoremediation [ 1522-6514 ] ; 2013.
Descripteurs français
- KwdFr :
- Arbres (MeSH), Caroline du Nord (MeSH), Chimère (MeSH), Dépollution biologique de l'environnement (MeSH), Hydrocarbures (métabolisme), Irrigation agricole (MeSH), Modèles biologiques (MeSH), Nappe phréatique (composition chimique), Polluants chimiques de l'eau (métabolisme), Pollution pétrolière (prévention et contrôle), Populus (anatomie et histologie), Populus (croissance et développement), Populus (physiologie), Purification de l'eau (méthodes), Pétrole (métabolisme), Racines de plante (anatomie et histologie), Racines de plante (croissance et développement), Racines de plante (physiologie), Saisons (MeSH), Salix (anatomie et histologie), Salix (croissance et développement), Salix (physiologie), Sol (MeSH), Transpiration des plantes (physiologie).
- MESH :
- anatomie et histologie : Populus, Racines de plante, Salix.
- composition chimique : Nappe phréatique.
- croissance et développement : Populus, Racines de plante, Salix.
- métabolisme : Hydrocarbures, Polluants chimiques de l'eau, Pétrole.
- méthodes : Purification de l'eau.
- physiologie : Populus, Racines de plante, Salix, Transpiration des plantes.
- prévention et contrôle : Pollution pétrolière.
- Arbres, Caroline du Nord, Chimère, Dépollution biologique de l'environnement, Irrigation agricole, Modèles biologiques, Saisons, Sol.
English descriptors
- KwdEn :
- Agricultural Irrigation (MeSH), Biodegradation, Environmental (MeSH), Chimera (MeSH), Groundwater (chemistry), Hydrocarbons (metabolism), Models, Biological (MeSH), North Carolina (MeSH), Petroleum (metabolism), Petroleum Pollution (prevention & control), Plant Roots (anatomy & histology), Plant Roots (growth & development), Plant Roots (physiology), Plant Transpiration (physiology), Populus (anatomy & histology), Populus (growth & development), Populus (physiology), Salix (anatomy & histology), Salix (growth & development), Salix (physiology), Seasons (MeSH), Soil (MeSH), Trees (MeSH), Water Pollutants, Chemical (metabolism), Water Purification (methods).
- MESH :
- chemical , metabolism : Hydrocarbons, Petroleum, Water Pollutants, Chemical.
- anatomy & histology : Plant Roots, Populus, Salix.
- chemistry : Groundwater.
- growth & development : Plant Roots, Populus, Salix.
- methods : Water Purification.
- physiology : Plant Roots, Plant Transpiration, Populus, Salix.
- prevention & control : Petroleum Pollution.
- Agricultural Irrigation, Biodegradation, Environmental, Chimera, Models, Biological, North Carolina, Seasons, Soil, Trees.
Abstract
Poplar and willow tree stands were installed in 2003 at a site in Raleigh, North Carolina containing total petroleum hydrocarbon - contaminated groundwater. The objective was groundwater uptake and plume control. The water table was 5 to 6 m below ground surface (bgs) and therefore methods were used to encourage deep root development. Growth rates, rooting depth and sap flow were measured for trees in Plot A located in the center of the plume and in Plot B peripheral to the plume. The trees were initially sub-irrigated with vertically installed drip-lines and by 2005 had roots 4 to 5 m bgs. Water balance calculations suggested groundwater uptake. In 2007, the average sap flow was higher for Plot B (approximately 59 L per day per tree) than for Plot A (approximately 23 L per day per tree), probably as a result of TPH-induced stress in Plot A. Nevertheless, the estimated rate of groundwater uptake for Plot A was sufficient, relative to the calculated rate of groundwater flux beneath the stand, that a high level of plume control was achieved based on MODFLOW modeling results. Down-gradient groundwater monitoring wells installed in late 2011 should provide quantitative data for plume control.
DOI: 10.1080/15226514.2012.687195
PubMed: 23488009
Affiliations:
Links toward previous steps (curation, corpus...)
Le document en format XML
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<author><name sortKey="Adham, Tareq" sort="Adham, Tareq" uniqKey="Adham T" first="Tareq" last="Adham">Tareq Adham</name>
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<term>Chimera (MeSH)</term>
<term>Groundwater (chemistry)</term>
<term>Hydrocarbons (metabolism)</term>
<term>Models, Biological (MeSH)</term>
<term>North Carolina (MeSH)</term>
<term>Petroleum (metabolism)</term>
<term>Petroleum Pollution (prevention & control)</term>
<term>Plant Roots (anatomy & histology)</term>
<term>Plant Roots (growth & development)</term>
<term>Plant Roots (physiology)</term>
<term>Plant Transpiration (physiology)</term>
<term>Populus (anatomy & histology)</term>
<term>Populus (growth & development)</term>
<term>Populus (physiology)</term>
<term>Salix (anatomy & histology)</term>
<term>Salix (growth & development)</term>
<term>Salix (physiology)</term>
<term>Seasons (MeSH)</term>
<term>Soil (MeSH)</term>
<term>Trees (MeSH)</term>
<term>Water Pollutants, Chemical (metabolism)</term>
<term>Water Purification (methods)</term>
</keywords>
<keywords scheme="KwdFr" xml:lang="fr"><term>Arbres (MeSH)</term>
<term>Caroline du Nord (MeSH)</term>
<term>Chimère (MeSH)</term>
<term>Dépollution biologique de l'environnement (MeSH)</term>
<term>Hydrocarbures (métabolisme)</term>
<term>Irrigation agricole (MeSH)</term>
<term>Modèles biologiques (MeSH)</term>
<term>Nappe phréatique (composition chimique)</term>
<term>Polluants chimiques de l'eau (métabolisme)</term>
<term>Pollution pétrolière (prévention et contrôle)</term>
<term>Populus (anatomie et histologie)</term>
<term>Populus (croissance et développement)</term>
<term>Populus (physiologie)</term>
<term>Purification de l'eau (méthodes)</term>
<term>Pétrole (métabolisme)</term>
<term>Racines de plante (anatomie et histologie)</term>
<term>Racines de plante (croissance et développement)</term>
<term>Racines de plante (physiologie)</term>
<term>Saisons (MeSH)</term>
<term>Salix (anatomie et histologie)</term>
<term>Salix (croissance et développement)</term>
<term>Salix (physiologie)</term>
<term>Sol (MeSH)</term>
<term>Transpiration des plantes (physiologie)</term>
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<term>Salix</term>
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</keywords>
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<term>Racines de plante</term>
<term>Salix</term>
</keywords>
<keywords scheme="MESH" qualifier="growth & development" xml:lang="en"><term>Plant Roots</term>
<term>Populus</term>
<term>Salix</term>
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<keywords scheme="MESH" qualifier="métabolisme" xml:lang="fr"><term>Hydrocarbures</term>
<term>Polluants chimiques de l'eau</term>
<term>Pétrole</term>
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<term>Salix</term>
<term>Transpiration des plantes</term>
</keywords>
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<term>Plant Transpiration</term>
<term>Populus</term>
<term>Salix</term>
</keywords>
<keywords scheme="MESH" qualifier="prevention & control" xml:lang="en"><term>Petroleum Pollution</term>
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<term>North Carolina</term>
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<term>Soil</term>
<term>Trees</term>
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<term>Caroline du Nord</term>
<term>Chimère</term>
<term>Dépollution biologique de l'environnement</term>
<term>Irrigation agricole</term>
<term>Modèles biologiques</term>
<term>Saisons</term>
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<front><div type="abstract" xml:lang="en">Poplar and willow tree stands were installed in 2003 at a site in Raleigh, North Carolina containing total petroleum hydrocarbon - contaminated groundwater. The objective was groundwater uptake and plume control. The water table was 5 to 6 m below ground surface (bgs) and therefore methods were used to encourage deep root development. Growth rates, rooting depth and sap flow were measured for trees in Plot A located in the center of the plume and in Plot B peripheral to the plume. The trees were initially sub-irrigated with vertically installed drip-lines and by 2005 had roots 4 to 5 m bgs. Water balance calculations suggested groundwater uptake. In 2007, the average sap flow was higher for Plot B (approximately 59 L per day per tree) than for Plot A (approximately 23 L per day per tree), probably as a result of TPH-induced stress in Plot A. Nevertheless, the estimated rate of groundwater uptake for Plot A was sufficient, relative to the calculated rate of groundwater flux beneath the stand, that a high level of plume control was achieved based on MODFLOW modeling results. Down-gradient groundwater monitoring wells installed in late 2011 should provide quantitative data for plume control.</div>
</front>
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<Title>International journal of phytoremediation</Title>
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<Abstract><AbstractText>Poplar and willow tree stands were installed in 2003 at a site in Raleigh, North Carolina containing total petroleum hydrocarbon - contaminated groundwater. The objective was groundwater uptake and plume control. The water table was 5 to 6 m below ground surface (bgs) and therefore methods were used to encourage deep root development. Growth rates, rooting depth and sap flow were measured for trees in Plot A located in the center of the plume and in Plot B peripheral to the plume. The trees were initially sub-irrigated with vertically installed drip-lines and by 2005 had roots 4 to 5 m bgs. Water balance calculations suggested groundwater uptake. In 2007, the average sap flow was higher for Plot B (approximately 59 L per day per tree) than for Plot A (approximately 23 L per day per tree), probably as a result of TPH-induced stress in Plot A. Nevertheless, the estimated rate of groundwater uptake for Plot A was sufficient, relative to the calculated rate of groundwater flux beneath the stand, that a high level of plume control was achieved based on MODFLOW modeling results. Down-gradient groundwater monitoring wells installed in late 2011 should provide quantitative data for plume control.</AbstractText>
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<AuthorList CompleteYN="Y"><Author ValidYN="Y"><LastName>Ferro</LastName>
<ForeName>Ari M</ForeName>
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<AffiliationInfo><Affiliation>URS Corporation, Morrisville, North Carolina, USA. ari.ferro@urs.com</Affiliation>
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<Initials>B</Initials>
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