Catálogo de publicaciones - libros
Modelling water and nutrient dynamics in soil-crop systems: Proceedings of the workshop on"Modelling water and nutrient dynamics in soil-crop systems" held on 14-16 June 2004 in Müncheberg, Germany
Kurt Christian Kersebaum ; Jens-Martin Hecker ; Wilfried Mirschel ; Martin Wegehenkel (eds.)
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| Institución detectada | Año de publicación | Navegá | Descargá | Solicitá |
|---|---|---|---|---|
| No detectada | 2007 | SpringerLink |
Información
Tipo de recurso:
libros
ISBN impreso
978-1-4020-4478-6
ISBN electrónico
978-1-4020-4479-3
Editor responsable
Springer Nature
País de edición
Reino Unido
Fecha de publicación
2007
Información sobre derechos de publicación
© Springer 2007
Tabla de contenidos
Modelling water and nutrient dynamics in soil–crop systems: a comparison of simulation models applied on common data sets
Kurt Christian Kersebaum; Jens-Martin Hecker; Wilfried Mirschel; Martin Wegehenkel
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 1-17
The performance of the model AMBAV for evapotranspiration and soil moisture on Müncheberg data
Hans Friesland; Franz-Josef Löpmeier
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 19-26
Performance of the model SIMWASER in two contrasting case studies on soil water movement
Elmar Stenitzer; Heiko Diestel; Uwe Franko; Reinhild Schwartengräber; Thomas Zenker
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 27-36
Application and validation of the models and with two field experimental data sets
Martin Wegehenkel; Wilfried Mirschel
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 37-49
Integrating a spatial micrometeorological model into the risk assessment for arable crops in hilly terrain
Marco Acutis; Gianfranco Rana; Patrizia Trevisiol; Luca Bechini; Mario Laudato; R. Ferrara; Goetz Michael Richter
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 51-57
Modelling soil–crop interactions with AGROSIM model family
Wilfried Mirschel; Karl-Otto Wenkel
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 59-73
Crop simulation model of the second and the third productivity levels
Ratmir Aleksandrovich Poluektov; Vitaly Viktorovich Terleev
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 75-89
The NDICEA model, a tool to improve nitrogen use efficiency in cropping systems
Geert Jan H. M. van der Burgt; Gerard J. M. Oomen; A. S. J. Habets; Walter A. H. Rossing
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 91-110
Simulation of water and nitrogen flows on field scale; application of the SWAP–ANIMO model for the Müncheberg data set
Joop Kroes; Jan Roelsma
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 111-128
Evaluation of water and nutrient dynamics in soil–crop systems using the eco-hydrological catchment model SWIM
Joachim Post; Anja Habeck; Fred Hattermann; Valentina Krysanova; Frank Wechsung; Felicitas Suckow
Textile dyeing effluents containing recalcitrant dyes are polluting waters due to their color and by the formation of toxic or carcinogenic intermediates such as aromatic amines from azo dyes. Since conventional treatment systems based on chemical or physical methods are quite expensive and consume high amounts of chemicals and energy, alternative biotechnologies for this purpose have recently been studied. A number of anaerobic and aerobic processes have been developed at laboratory scale to treat dyestuff. Some industrial pilot scale plants have even been set up. Additionally, biosorption shows very promising results for decolorizing textile effluents. In this contribution, we review fundamental and applied aspects of biological treatment of textile dyes.
Pp. 129-146