Publikationer av Jan-Olof Selroos
Refereegranskade
Artiklar
[1]
S. Libby et al., "Exploring the impact of fracture interaction on connectivity and flow channelling using grown fracture networks," Quarterly journal of engineering geology and hydrogeology, vol. 57, no. 1, 2024.
[2]
J. Sanglas et al., "Significance of Low-Velocity Zones on Solute Retention in Rough Fractures," Water resources research, vol. 60, no. 4, 2024.
[3]
P. Davy et al., "Structural and hydrodynamic controls on fluid travel time distributions across fracture networks," Proceedings of the National Academy of Sciences of the United States of America, vol. 121, no. 47, 2024.
[4]
D. Doolaeghe et al., "Controls on fracture openness and reactivation in Forsmark, Sweden," Scientific Reports, vol. 13, no. 1, 2023.
[5]
J.-O. Selroos och B. Gylling, "How Findings from a Multi-Annual International Modeling Initiative Are Implemented in a Nuclear Waste Management Organization," Energies, vol. 16, no. 2, 2023.
[6]
L. Zou et al., "Parameterization of a channel network model for groundwater flow in crystalline rock using geological and hydraulic test data," Engineering Geology, vol. 317, 2023.
[7]
P. Davy et al., "Scaling of fractured rock flow. Proposition of indicators for selection of DFN based flow models," Comptes rendus Geoscience, vol. 355, 2023.
[8]
J. Molron et al., "GPR-inferred fracture aperture widening in response to a high-pressure tracer injection test at the Äspö Hard Rock Laboratory, Sweden," Engineering Geology, vol. 292, 2021.
[9]
E. Jutebring Sterte et al., "Hydrological control of water quality – Modelling base cation weathering and dynamics across heterogeneous boreal catchments," Science of the Total Environment, vol. 799, s. 149101-149101, 2021.
[10]
L. Zou et al., "Impact of shear displacement on advective transport in a laboratory-scale fracture," Geomechanics for Energy and the Environment, s. 100278, 2021.
[11]
T. Williams et al., "Recovering the Effects of Subgrid Heterogeneity in Simulations of Radionuclide Transport Through Fractured Media," Frontiers in Earth Science, vol. 8, 2021.
[12]
P. Trinchero et al., "A Particle-Based Conditional Sampling Scheme for the Simulation of Transport in Fractured Rock With Diffusion Into Stagnant Water and Rock Matrix," Water resources research, vol. 56, no. 4, 2020.
[13]
V. Cvetkovic et al., "Inference of Retention Time From Tracer Tests in Crystalline Rock," Water resources research, vol. 56, no. 2, 2020.
[14]
P. Trinchero et al., "Modelling the water phase diffusion experiment at Onkalo (Finland) : Insights into the effect of channeling on radionuclide transport and retention," Journal of Hydrology, vol. 590, 2020.
[15]
P. Trinchero et al., "Upscaling of radionuclide transport and retention in crystalline rocks exhibiting micro-scale heterogeneity of the rock matrix," Advances in Water Resources, vol. 142, 2020.
[16]
J. Molron et al., "Which fractures are imaged with Ground Penetrating Radar? : Results from an experiment in the Äspö Hardrock Laboratory, Sweden," Engineering Geology, vol. 273, s. 105674, 2020.
[17]
M. Voutilainen et al., "Characterization of spatial porosity and mineral distribution of crystalline rock using X-ray micro computed tomography, C-14-PMMA autoradiography and scanning electron microscopy," Applied Geochemistry, vol. 101, s. 50-61, 2019.
[18]
U. Svensson et al., "Grains, grids and mineral surfaces : approaches to grain-scale matrix modeling based on X-ray micro-computed tomography data," SN Applied Sciences, vol. 1, no. 10, 2019.
[19]
J.-O. Selroos et al., "Permafrost Thaw with Thermokarst Wetland-Lake and Societal-Health Risks : Dependence on Local Soil Conditions under Large-Scale Warming," Water, vol. 11, no. 3, s. 574, 2019.
[20]
C. Grenier et al., "Groundwater flow and heat transport for systems undergoing freeze-thaw : Intercomparison of numerical simulators for 2D test cases," Advances in Water Resources, vol. 114, s. 196-218, 2018.
[21]
U. Svensson et al., "Modelling the diffusion-available pore space of an unaltered granitic rock matrix using a micro-DFN approach," Journal of Hydrology, vol. 559, s. 182-191, 2018.
[22]
A. Iraola et al., "Microtomography-based Inter-Granular Network for the simulation of radionuclide diffusion and sorption in a granitic rock," Journal of Contaminant Hydrology, vol. 207, s. 8-16, 2017.
[23]
P. Trinchero et al., "Modelling radionuclide transport in fractured media with a dynamic update of Kd values," Computers & Geosciences, vol. 86, s. 55-63, 2016.
[24]
E. Johansson et al., "Data evaluation and numerical modeling of hydrological interactions between active layer, lake and talik in a permafrost catchment, Western Greenland," Journal of Hydrology, vol. 527, s. 688-703, 2015.
[25]
J.-O. Selroos och G. Destouni, "Influence of spatial and temporal flow variability on solute transport in catchments," Hydrological Processes, vol. 29, no. 16, s. 3592-3603, 2015.
[26]
P. Trinchero et al., "FASTREACT : An efficient numerical framework for the solution of reactive transport problems," Applied Geochemistry, vol. 49, s. 159-167, 2014.
[27]
P. Vidstrand et al., "Groundwater flow modeling of periods with periglacial and glacial climate conditions for the safety assessment of the proposed high-level nuclear waste repository site at Forsmark, Sweden," Hydrogeology Journal, vol. 22, no. 6, s. 1251-1267, 2014.
[28]
J.-O. Selroos och S. Follin, "Overview of hydrogeological safety assessment modeling conducted for the proposed high-level nuclear waste repository site at Forsmark, Sweden," Hydrogeology Journal, vol. 22, no. 6, s. 1229-1232, 2014.
[29]
J.-O. Selroos och S. Follin, "Overview of hydrogeological site-descriptive modeling conducted for the proposed high-level nuclear waste repository site at Forsmark, Sweden," Hydrogeology Journal, vol. 22, no. 2, s. 295-298, 2014.
[30]
E. Bosson et al., "Exchange and pathways of deep and shallow groundwater in different climate and permafrost conditions using the Forsmark site, Sweden, as an example catchment," Hydrogeology Journal, vol. 21, no. 1, s. 225-237, 2013.
[31]
S. Berglund et al., "Identification and Characterization of Potential Discharge Areas for Radionuclide Transport by Groundwater from a Nuclear Waste Repository in Sweden," Ambio, vol. 42, no. 4, s. 435-446, 2013.
[32]
J.-O. Selroos et al., "Radionuclide transport during glacial cycles : Comparison of two approaches for representing flow transients," Physics and Chemistry of the Earth, vol. 64, s. 32-45, 2013.
[33]
S. L. Painter och J.-O. Selroos, "Effect of transport-pathway simplifications on projected releases of radionuclides from a nuclear waste repository (Sweden)," Hydrogeology Journal, vol. 20, no. 8, s. 1467-1481, 2012.
[34]
P. Vidstrand et al., "Modeling of groundwater flow at depth in crystalline rock beneath a moving ice-sheet margin, exemplified by the Fennoscandian Shield, Sweden," Hydrogeology Journal, vol. 21, no. 1, s. 239-255, 2012.
[35]
V. Cvetkovic et al., "Water and solute transport along hydrological pathways," Water resources research, vol. 48, no. 6, s. W06537, 2012.
[36]
V. Cvetkovic et al., "Stochastic simulation of radionuclide migration in discretely fractured rock near the Aspo Hard Rock Laboratory," Water resources research, vol. 40, no. 2, s. W02404, 2004.
[37]
V. Cvetkovic, S. Painter och J.-O. Selroos, "Comparative measures of radionuclide containment in the crystalline geosphere," Nuclear science and engineering, vol. 142, no. 3, s. 292-304, 2002.
[38]
S. Painter, V. Cvetkovic och J.-O. Selroos, "Power-law velocity distributions in fracture networks : Numerical evidence and implications for tracer transport," Geophysical Research Letters, vol. 29, no. 14, 2002.
Konferensbidrag
[39]
B. Gylling et al., "SKB Task Force GWFTS : Lessons Learned from Modeling Field Tracer Experiments in Finland and Sweden," i AGU Fall meeting 2021, 2022.
Senaste synkning med DiVA:
2024-12-22 00:13:02