The effect of changes in natural and anthropogenic deposition on modelling recovery from acidification.
(2003) In Hydrology and Earth System Sciences 7(5). p.766-776- Abstract
- The mufti-layer dynamic soil chemistry SAFE model was used to study the dynamics of recovery in the F1 catchment at Lake Gardsjon, Sweden. The influence of (F) sulphate adsorption, and (2) changes in marine deposition, oil model predictions of recovery was studied. Sulphate adsorption/desorption in SAFE is modeled by all isotherm in which sulphate adsorption is dependent oil both the sulphate concentration and the pH in the soil solution. This isotherm was parameterised for the B-horizon of F1 for the sulphate concentration range 10-260 mumol(-1) and the pH range 3.8-5.0. Sulphate adsorption/desorption as the only soil process involving sulphate is adequate to predict sulphate in run-off at F1. Adding the process caused time-delays in... (More)
- The mufti-layer dynamic soil chemistry SAFE model was used to study the dynamics of recovery in the F1 catchment at Lake Gardsjon, Sweden. The influence of (F) sulphate adsorption, and (2) changes in marine deposition, oil model predictions of recovery was studied. Sulphate adsorption/desorption in SAFE is modeled by all isotherm in which sulphate adsorption is dependent oil both the sulphate concentration and the pH in the soil solution. This isotherm was parameterised for the B-horizon of F1 for the sulphate concentration range 10-260 mumol(-1) and the pH range 3.8-5.0. Sulphate adsorption/desorption as the only soil process involving sulphate is adequate to predict sulphate in run-off at F1. Adding the process caused time-delays in sulphate concentration in run-off of only 1-2 years. which was Much shorter than previously seen in the adjacent G1 catchment. The location of Lake Gardsjon. approximately 15 km inland from the Swedish west coast, ensures that the marine deposition to the area is high. Model Output showed that the temporal variation in marine deposition has a considerable impact oil the run-off-chemistry. Such changes in marine deposition are difficult to foresee and their influence on modelled run-off-chemistry, can be large when soils start to recover as the previously high concentrations of anthropogenic sulphate in the soil solution decrease. (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/129342
- author
- Fransson, Liisa LU ; Alveteg, Mattias LU ; Mörth, C-M and Warfvinge, Per LU
- organization
- publishing date
- 2003
- type
- Contribution to journal
- publication status
- published
- subject
- in
- Hydrology and Earth System Sciences
- volume
- 7
- issue
- 5
- pages
- 766 - 776
- publisher
- European Geophysical Society
- external identifiers
-
- wos:000220736200011
- scopus:1642406512
- ISSN
- 1607-7938
- language
- English
- LU publication?
- yes
- id
- 7fa18655-4911-428c-82ce-3b724ccfd618 (old id 129342)
- alternative location
- http://www.hydrol-earth-syst-sci.net/7/766/2003/hess-7-766-2003.pdf
- date added to LUP
- 2016-04-01 12:24:59
- date last changed
- 2023-09-02 06:55:15
@article{7fa18655-4911-428c-82ce-3b724ccfd618, abstract = {{The mufti-layer dynamic soil chemistry SAFE model was used to study the dynamics of recovery in the F1 catchment at Lake Gardsjon, Sweden. The influence of (F) sulphate adsorption, and (2) changes in marine deposition, oil model predictions of recovery was studied. Sulphate adsorption/desorption in SAFE is modeled by all isotherm in which sulphate adsorption is dependent oil both the sulphate concentration and the pH in the soil solution. This isotherm was parameterised for the B-horizon of F1 for the sulphate concentration range 10-260 mumol(-1) and the pH range 3.8-5.0. Sulphate adsorption/desorption as the only soil process involving sulphate is adequate to predict sulphate in run-off at F1. Adding the process caused time-delays in sulphate concentration in run-off of only 1-2 years. which was Much shorter than previously seen in the adjacent G1 catchment. The location of Lake Gardsjon. approximately 15 km inland from the Swedish west coast, ensures that the marine deposition to the area is high. Model Output showed that the temporal variation in marine deposition has a considerable impact oil the run-off-chemistry. Such changes in marine deposition are difficult to foresee and their influence on modelled run-off-chemistry, can be large when soils start to recover as the previously high concentrations of anthropogenic sulphate in the soil solution decrease.}}, author = {{Fransson, Liisa and Alveteg, Mattias and Mörth, C-M and Warfvinge, Per}}, issn = {{1607-7938}}, language = {{eng}}, number = {{5}}, pages = {{766--776}}, publisher = {{European Geophysical Society}}, series = {{Hydrology and Earth System Sciences}}, title = {{The effect of changes in natural and anthropogenic deposition on modelling recovery from acidification.}}, url = {{http://www.hydrol-earth-syst-sci.net/7/766/2003/hess-7-766-2003.pdf}}, volume = {{7}}, year = {{2003}}, }