Publications

Peer-reviewed contributions in scientific journals

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  1. [PDF] [DOI] Bring, A., Shiklomanov, A., & Lammers, R. B.. (2017). Pan-Arctic river discharge: prioritizing monitoring of future climate change hot spots. Earth’s Future.
    [Bibtex]
    @article{bring_pan-arctic_2017,
    title = {Pan-{Arctic} river discharge: prioritizing monitoring of future climate change hot spots},
    issn = {2328-4277},
    shorttitle = {Pan-{Arctic} river discharge},
    url = {http://onlinelibrary.wiley.com/doi/10.1002/2016EF000434/abstract},
    doi = {10.1002/2016EF000434},
    abstract = {The Arctic freshwater cycle is changing rapidly, which will require adequate monitoring of river flows to detect, observe and understand changes and provide adaptation information. There has however been little detail about where the greatest flow changes are projected, and where monitoring therefore may need to be strengthened. In this study, we used a set of recent climate model runs and an advanced macro-scale hydrological model to analyze how flows across the continental pan-Arctic are projected to change, and where the climate models agree on significant changes. We also developed a method to identify where monitoring stations should be placed to observe these significant changes, and compared this set of suggested locations with the existing network of monitoring stations. Overall, our results reinforce earlier indications of large increases in flow over much of the Arctic, but we also identify some areas where projections agree on significant changes but disagree on the sign of change. For monitoring, central and eastern Siberia, Alaska and central Canada are hot spots for the highest changes. To take advantage of existing networks, a number of stations across central Canada and western and central Siberia could form a prioritized set. Further development of model representation of high-latitude hydrology would improve confidence in the areas we identify here. Nevertheless, ongoing observation programs may consider these suggested locations in efforts to improve monitoring of the rapidly changing Arctic freshwater cycle.},
    language = {en},
    urldate = {2016-12-15},
    journal = {Earth's Future},
    author = {Bring, Arvid and Shiklomanov, Alexander and Lammers, Richard B.},
    year = {2017},
    keywords = {1630 Impacts of global change, 1655 Water cycles, 1848 Monitoring networks, 1880 Water management, 1930 Data and information governance, climate projections, Hydrological monitoring, Pan-Arctic Drainage Basin, Pan-Arctic river discharge},
    }
  2. [DOI] Fischer, S., Pietroń, J., Bring, A., Thorslund, J., & Jarsjö, J.. (2016). Present to future sediment transport of the Brahmaputra River: reducing uncertainty in predictions and management. Regional Environmental Change, 1-12.
    [Bibtex]
    @article{fischer_present_2016,
    title = {Present to future sediment transport of the {Brahmaputra} {River}: reducing uncertainty in predictions and management},
    shorttitle = {Present to future sediment transport of the {Brahmaputra} {River}},
    url = {http://link.springer.com/article/10.1007/s10113-016-1039-7},
    doi = {10.1007/s10113-016-1039-7},
    urldate = {2016-09-07},
    journal = {Regional Environmental Change},
    author = {Fischer, Sandra and Pietroń, Jan and Bring, Arvid and Thorslund, Josefin and Jarsjö, Jerker},
    year = {2016},
    pages = {1--12},
    }
  3. [PDF] [DOI] Bring, A., Fedorova, I., Dibike, Y., Hinzman, L., Mård, J., Mernild, S. H., Prowse, T. D., Semenova, O., Stuefer, S., & Woo, M.. (2016). Arctic terrestrial hydrology: A synthesis of processes, regional effects and research challenges. Journal of Geophysical Research: Biogeosciences.
    [Bibtex]
    @article{bring_arctic_2016,
    title = {Arctic terrestrial hydrology: {A} synthesis of processes, regional effects and research challenges},
    doi = {10.1002/2015JG003131},
    journal = {Journal of Geophysical Research: Biogeosciences},
    author = {Bring, A. and Fedorova, I. and Dibike, Y. and Hinzman, L. and Mård, J. and Mernild, S. H. and Prowse, T. D and Semenova, O. and Stuefer, Sveta and Woo, Ming-Ko},
    year = {2016}
    }
  4. [DOI] Asokan, S. M., Rogberg, P., Bring, A., Jarsjö, J., & Destouni, G.. (2016). Climate model performance and change projection for freshwater fluxes: Comparison for irrigated areas in Central and South Asia. Journal of Hydrology: Regional Studies, 5, 48-65.
    [Bibtex]
    @article{asokan_climate_2016,
    title = {Climate model performance and change projection for freshwater fluxes: {Comparison} for irrigated areas in {Central} and {South} {Asia}},
    volume = {5},
    issn = {2214-5818},
    shorttitle = {Climate model performance and change projection for freshwater fluxes},
    url = {http://www.sciencedirect.com/science/article/pii/S2214581815001329},
    doi = {10.1016/j.ejrh.2015.11.017},
    abstract = {Study region
    The large semi-arid Aral Region in Central Asia and the smaller tropical Mahanadi River Basin (MRB) in India.
    Study focus
    Few studies have so far evaluated the performance of the latest generation of global climate models on hydrological basin scales. We here investigate the performance and projections of the global climate models in the Coupled Model Intercomparison Project, Phase 5 (CMIP5) for freshwater fluxes and their changes in two regional hydrological basins, which are both irrigated but of different scale and with different climate.
    New hydrological insights for the region
    For precipitation in both regions, model accuracy relative to observations has remained the same or decreased in successive climate model generations until and including CMIP5. No single climate model out-performs other models across all key freshwater variables in any of the investigated basins. Scale effects are not evident from global model application directly to freshwater assessment for the two basins of widely different size. Overall, model results are less accurate and more uncertain for freshwater fluxes than for temperature, and particularly so for model-implied water storage changes. Also, the monsoon-driven runoff seasonality in MRB is not accurately reproduced. Model projections agree on evapotranspiration increase in both regions until the climatic period 2070–2099. This increase is fed by precipitation increase in MRB and by runoff water (thereby decreasing runoff) in the Aral Region.},
    urldate = {2015-12-11},
    journal = {Journal of Hydrology: Regional Studies},
    author = {Asokan, Shilpa M. and Rogberg, Peter and Bring, Arvid and Jarsjö, Jerker and Destouni, Georgia},
    month = mar,
    year = {2016},
    keywords = {Central Asia, CMIP5 global climate models, Freshwater change, Hydro-climate, Monsoon driven seasonality, South Asia},
    pages = {48--65},
    file = {ScienceDirect Full Text PDF:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/UAUP9DP9/Asokan m. fl. - 2016 - Climate model performance and change projection fo.pdf:application/pdf;ScienceDirect Snapshot:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/GH48XZ9T/S2214581815001329.html:text/html}
    }
  5. [DOI] Prowse, T., Bring, A., Mård, J., & Carmack, E.. (2015). Arctic freshwater synthesis: Introduction. Journal of Geophysical Research: Biogeosciences, 120, 2121-2131.
    [Bibtex]
    @article{prowse_arctic_2015,
    title = {Arctic freshwater synthesis: {Introduction}},
    volume = {120},
    issn = {2169-8961},
    shorttitle = {Arctic freshwater synthesis},
    url = {http://onlinelibrary.wiley.com/doi/10.1002/2015JG003127/abstract},
    doi = {10.1002/2015JG003127},
    abstract = {In response to a joint request from the World Climate Research Program's Climate and Cryosphere Project, the International Arctic Science Committee, and the Arctic Council's Arctic Monitoring and Assessment Program, an updated scientific assessment has been conducted of the Arctic Freshwater System (AFS), entitled the Arctic Freshwater Synthesis (AFSΣ). The major reason for joint request was an increasing concern that changes to the AFS have produced, and could produce even greater, changes to biogeophysical and socioeconomic systems of special importance to northern residents and also produce extra-Arctic climatic effects that will have global consequences. Hence, the key objective of the AFSΣ was to produce an updated, comprehensive, and integrated review of the structure and function of the entire AFS. The AFSΣ was organized around six key thematic areas: atmosphere, oceans, terrestrial hydrology, terrestrial ecology, resources and modeling, and the review of each coauthored by an international group of scientists and published as separate manuscripts in this special issue of Journal of Geophysical Research-Biogeosciences. This AFSΣ—Introduction reviews the motivations for, and foci of, previous studies of the AFS, discusses criteria used to define the domain of the AFS, and details key characteristics of the definition adopted for the AFSΣ.},
    language = {en},
    urldate = {2015-12-01},
    journal = {Journal of Geophysical Research: Biogeosciences},
    author = {Prowse, T. and Bring, A. and Mård, J. and Carmack, E.},
    year = {2015},
    keywords = {0475 Permafrost, cryosphere, and high-latitude processes, 1223 Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, 1621 Cryospheric change, 1655 Water cycles, 1836 Hydrological cycles and budgets, arctic, Ecology, FRESHWATER, Hydrology, oceans, resources},
    pages = {2121--2131},
    file = {Full Text PDF:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/S4NS9JXK/Prowse m. fl. - 2015 - Arctic freshwater synthesis Introduction.pdf:application/pdf;Snapshot:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/AWDBPEG8/abstract.html:text/html}
    }
  6. [DOI] Prowse, T., Bring, A., Karlsson, J. M., Carmack, E., Holland, M., Instanes, A., Vihma, T., & Wrona, F. J.. (2015). Arctic freshwater synthesis: Summary of key emerging issues. Journal of Geophysical Research: Biogeosciences, 120, 1887-1893.
    [Bibtex]
    @article{prowse_arctic_2015-1,
    title = {Arctic freshwater synthesis: {Summary} of key emerging issues},
    volume = {120},
    shorttitle = {Arctic freshwater synthesis},
    url = {http://onlinelibrary.wiley.com/doi/10.1002/2015JG003128/full},
    doi = {10.1002/2015JG003128},
    urldate = {2015-09-28},
    journal = {Journal of Geophysical Research: Biogeosciences},
    author = {Prowse, T. and Bring, A. and Karlsson, J. M. and Carmack, E. and Holland, M. and Instanes, A. and Vihma, T. and Wrona, F. J.},
    year = {2015},
    pages = {1887--1893},
    file = {Snapshot:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/3TTD5DFD/full\;jsessionid=E9E4DA108E8F5C5F4DC68DF963AC967B.html:text/html}
    }
  7. [PDF] [DOI] Bring, A., Rogberg, P., & Destouni, G.. (2015). Variability in climate change simulations affects needed long-term riverine nutrient reductions for the Baltic Sea. AMBIO, 44(3), 381-391.
    [Bibtex]
    @article{bring_variability_2015,
    title = {Variability in climate change simulations affects needed long-term riverine nutrient reductions for the {Baltic} {Sea}},
    volume = {44},
    issn = {0044-7447, 1654-7209},
    url = {http://link.springer.com/article/10.1007/s13280-015-0657-5},
    doi = {10.1007/s13280-015-0657-5},
    abstract = {Changes to runoff due to climate change may influence management of nutrient loading to the sea. Assuming unchanged river nutrient concentrations, we evaluate the effects of changing runoff on commitments to nutrient reductions under the Baltic Sea Action Plan. For several countries, climate projections point to large variability in load changes in relation to reduction targets. These changes either increase loads, making the target more difficult to reach, or decrease them, leading instead to a full achievement of the target. The impact of variability in climate projections varies with the size of the reduction target and is larger for countries with more limited commitments. In the end, a number of focused actions are needed to manage the effects of climate change on nutrient loads: reducing uncertainty in climate projections, deciding on frameworks to identify best performing models with respect to land surface hydrology, and increasing efforts at sustained monitoring of water flow changes.},
    language = {en},
    number = {3},
    urldate = {2015-05-29},
    journal = {AMBIO},
    author = {Bring, Arvid and Rogberg, Peter and Destouni, Georgia},
    month = may,
    year = {2015},
    keywords = {Atmospheric Sciences, Baltic Sea Action Plan, Baltic Sea drainage basin, Climate change, CMIP5 general circulation models, Ecology, Environmental Engineering/Biotechnology, Environmental Management, Environment, general, Physical Geography, Runoff projections, Waterborne nutrient transport},
    pages = {381--391},
    file = {Full Text PDF:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/J84NUA2M/Bring m. fl. - 2015 - Variability in climate change simulations affects .pdf:application/pdf;Snapshot:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/92872UI4/s13280-015-0657-5.html:text/html}
    }
  8. [PDF] [DOI] Bring, A., Asokan, S. M., Jaramillo, F., Jarsjö, J., Levi, L., Pietron, J., Prieto, C., Rogberg, P., & Destouni, G.. (2015). Implications of freshwater flux data from the CMIP5 multi-model output across a set of Northern Hemisphere drainage basins. Earth’s Future, 3(6), 206-217.
    [Bibtex]
    @article{bring_implications_2015,
    title = {Implications of freshwater flux data from the {CMIP}5 multi-model output across a set of {Northern} {Hemisphere} drainage basins},
    volume = {3},
    url = {http://onlinelibrary.wiley.com/doi/10.1002/2014EF000296/abstract},
    doi = {10.1002/2014EF000296},
    number = {6},
    journal = {Earth's Future},
    author = {Bring, Arvid and Asokan, Shilpa M. and Jaramillo, Fernando and Jarsjö, Jerker and Levi, Lea and Pietron, Jan and Prieto, Carmen and Rogberg, Peter and Destouni, Georgia},
    year = {2015},
    pages = {206--217}
    }
  9. [DOI] Strandmark, A., Bring, A., Cousins, S. A. O., Destouni, G., Kautsky, H., Kolb, G., de la Torre Castro, M., & Hambäck, P. A.. (2015). Climate change effects in the borderland between land and sea: an overseen issue. AMBIO, 44 (Suppl. 1), 28-38.
    [Bibtex]
    @article{strandmark_climate_2015,
    title = {Climate change effects in the borderland between land and sea: an overseen issue},
    volume = {44 (Suppl. 1)},
    doi = {10.1007/s13280-014-0586-8},
    journal = {AMBIO},
    author = {Strandmark, Alma and Bring, Arvid and Cousins, Sara A. O. and Destouni, Georgia and Kautsky, Hans and Kolb, Gundula and de la Torre Castro, Marciela and Hambäck, Peter A.},
    month = jan,
    year = {2015},
    pages = {28--38},
    file = {Strandmark et al 2015.pdf:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/NP7MEGKP/Strandmark et al 2015.pdf:application/pdf}
    }
  10. [DOI] Törnqvist, R., Jarsjö, J., Pietroń, J., Bring, A., Rogberg, P., Asokan, S. M., & Destouni, G.. (2014). Evolution of the hydro-climate system in the Lake Baikal basin. Journal of Hydrology, 519, 1953-1962.
    [Bibtex]
    @article{tornqvist_evolution_2014,
    title = {Evolution of the hydro-climate system in the {Lake} {Baikal} basin},
    volume = {519},
    issn = {0022-1694},
    url = {http://www.sciencedirect.com/science/article/pii/S0022169414007665},
    doi = {10.1016/j.jhydrol.2014.09.074},
    abstract = {Summary
    Climatic changes can profoundly alter hydrological conditions in river basins. Lake Baikal is the deepest and largest freshwater reservoir on Earth, and has a unique ecosystem with numerous endemic animal and plant species. We here identify long-term historical (1938–2009) and projected future hydro-climatic trends in the Selenga River Basin, which is the largest sub-basin (\>60\% inflow) of Lake Baikal. Our analysis is based on long-term river monitoring and historical hydro-climatic observation data, as well as ensemble mean and 22 individual model results of the Coupled Model Intercomparison Project, Phase 5 (CMIP5). Study of the latter considers a historical period (from 1961) and projections for 2010–2039 and 2070–2099. Observations show almost twice as fast warming as the global average during the period 1938–2009. Decreased intra-annual variability of river discharge over this period indicates basin-scale permafrost degradation. CMIP5 ensemble projections show further future warming, implying continued permafrost thaw. Modelling of runoff change, however, is highly uncertain, with many models (64\%) and their ensemble mean failing to reproduce historical behaviour, and with indicated future increase being small relative to the large differences among individual model results.},
    urldate = {2014-12-16},
    journal = {Journal of Hydrology},
    author = {Törnqvist, Rebecka and Jarsjö, Jerker and Pietroń, Jan and Bring, Arvid and Rogberg, Peter and Asokan, Shilpa M. and Destouni, Georgia},
    month = nov,
    year = {2014},
    keywords = {Climate change, CMIP5, Hydrology, Lake Baikal, Permafrost, Selenga River Basin},
    pages = {1953--1962},
    file = {ScienceDirect Full Text PDF:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/RIIF4R89/Törnqvist m. fl. - 2014 - Evolution of the hydro-climate system in the Lake .pdf:application/pdf;ScienceDirect Snapshot:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/RK5EW4EZ/S0022169414007665.html:text/html}
    }
  11. [PDF] [DOI] Bring, A., & Destouni, G.. (2014). Arctic climate and water change: Model and observation relevance for assessment and adaptation. Surveys in Geophysics, 35, 853-877.
    [Bibtex]
    @article{bring_arctic_2014,
    title = {Arctic climate and water change: {Model} and observation relevance for assessment and adaptation},
    volume = {35},
    doi = {10.1007/s10712-013-9267-6},
    journal = {Surveys in Geophysics},
    author = {Bring, Arvid and Destouni, Georgia},
    year = {2014},
    pages = {853--877},
    file = {BringDestouni-SurvGeophysics.pdf:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/ZUJK4SU6/BringDestouni-SurvGeophysics.pdf:application/pdf}
    }
  12. [PDF] [DOI] Azcárate, J., Balfors, B., Bring, A., & Destouni, G.. (2013). Strategic environmental assessment and monitoring: Arctic key gaps and bridging pathways. Environmental Research Letters, 8(4), 44033.
    [Bibtex]
    @article{azcarate_strategic_2013,
    title = {Strategic environmental assessment and monitoring: {Arctic} key gaps and bridging pathways},
    volume = {8},
    issn = {1748-9326},
    shorttitle = {Strategic environmental assessment and monitoring},
    url = {http://iopscience.iop.org/1748-9326/8/4/044033},
    doi = {10.1088/1748-9326/8/4/044033},
    abstract = {The Arctic region undergoes rapid and unprecedented environmental change. Environmental assessment and monitoring is needed to understand and decide how to mitigate and/or adapt to the changes and their impacts on society and ecosystems. This letter analyzes the application of strategic environmental assessment (SEA) and the monitoring, based on environmental observations, that should be part of SEA, elucidates main gaps in both, and proposes an overarching SEA framework to systematically link and improve both with focus on the rapidly changing Arctic region. Shortcomings in the monitoring of environmental change are concretized by examples of main gaps in the observations of Arctic hydroclimatic changes. For relevant identification and efficient reduction of such gaps and remaining uncertainties under typical conditions of limited monitoring resources, the proposed overarching framework for SEA application includes components for explicit gap/uncertainty handling and monitoring, systematically integrated within all steps of the SEA process. The framework further links to adaptive governance, which should explicitly consider key knowledge and information gaps that are identified through and must be handled in the SEA process, and accordingly (re)formulate and promote necessary new or modified monitoring objectives for bridging these gaps.},
    language = {en},
    number = {4},
    urldate = {2013-11-22},
    journal = {Environmental Research Letters},
    author = {Azcárate, Juan and Balfors, Berit and Bring, Arvid and Destouni, Georgia},
    month = nov,
    year = {2013},
    pages = {044033},
    file = {AzcarateEtAl2013.pdf:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/8SZ4EPW9/AzcarateEtAl2013.pdf:application/pdf;Snapshot:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/CVDWIIDT/article.html:text/html}
    }
  13. [PDF] [DOI] Bring, A., & Destouni, G.. (2013). Hydro-climatic changes and their monitoring in the Arctic: Observation-model comparisons and prioritization options for monitoring development. Journal of Hydrology, 492, 273-280.
    [Bibtex]
    @article{bring_hydro-climatic_2013,
    title = {Hydro-climatic changes and their monitoring in the {Arctic}: {Observation}-model comparisons and prioritization options for monitoring development},
    volume = {492},
    issn = {0022-1694},
    shorttitle = {Hydro-climatic changes and their monitoring in the {Arctic}},
    url = {http://www.sciencedirect.com/science/article/pii/S0022169413002631},
    doi = {10.1016/j.jhydrol.2013.04.003},
    abstract = {The Arctic undergoes particularly large and rapid hydro-climatic changes, and information on hydrological responses to these changes is crucial to plan for societal adaptation. We investigate hydro-climatic change severity and monitoring in 14 major hydrological basins across the pan-Arctic, in view of different possible strategies for their monitoring prioritization. Results show that the current distribution of monitoring density in these basins is more relevant for so far observed precipitation changes than for observed temperature changes, or for projected future temperature and precipitation changes. Furthermore, present and projected future hot-spots of greatest hydro-climatic change differ spatially, so that major spatial shifts must occur in the future among the different Arctic basins in order for observations and climate model projections to converge with regard to hydro-climatic change severity. Also temporally, observation-model convergence requires that important change direction shifts occur in major Arctic basins, which have currently decreasing precipitation while model projections imply future increasing precipitation within them. Different prioritization options for rational development of hydro-climatic monitoring can be argued for based on the present results. The divergent prioritization options imply a need for an explicit strategy for achieving certain information goals, which must be selected from a larger set of different possible goals based on societal importance.},
    urldate = {2013-05-03},
    journal = {Journal of Hydrology},
    author = {Bring, Arvid and Destouni, Georgia},
    year = {2013},
    keywords = {Adaptation, arctic, Climate change, Hydrology, Monitoring},
    pages = {273--280},
    file = {BringDestouni2013.pdf:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/5CD5GJA3/BringDestouni2013.pdf:application/pdf;ScienceDirect Full Text PDF:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/5XNM46KI/Bring and Destouni - Hydro-climatic changes and their monitoring in the.pdf:application/pdf;ScienceDirect Snapshot:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/AFM5CH4Z/S0022169413002631.html:text/html}
    }
  14. [DOI] Rennermalm, A. K., Bring, A., & Mote, T. L.. (2012). Spatial and Scale-Dependent Controls on North American Pan-Arctic Minimum River Discharge. Geographical Analysis, 44(3), 202-218.
    [Bibtex]
    @article{rennermalm_spatial_2012,
    title = {Spatial and {Scale}-{Dependent} {Controls} on {North} {American} {Pan}-{Arctic} {Minimum} {River} {Discharge}},
    volume = {44},
    copyright = {© 2012 The Ohio State University},
    issn = {1538-4632},
    url = {http://www04.sub.su.se:2079/doi/10.1111/j.1538-4632.2012.00849.x/abstract},
    doi = {10.1111/j.1538-4632.2012.00849.x},
    abstract = {Spatial patterns of minimum monthly river discharge in the North American Pan-Arctic and its potential controls are explored with geographically weighted regression (GWR). Minimum discharge is indicative of soil water conditions; therefore, understanding spatial variability of its controls may provide insights into patterns of hydrologic change. Here, GWR models are applied to determine a suitable combination of independent variables selected from a set of eight variables. A model specification with annual mean river discharge, temperature at time of minimum discharge, and biome describes well the spatial patterns in minimum discharge. However, minimum discharge in larger watersheds is influenced more by temperature and biome distributions than it is in small basins, suggesting that scale is critical for understanding minimum river discharge. This study is the first to apply GWR to explore spatial variation in Pan-Arctic hydrology.Factores de control espaciales y dependientes de escala en las descargas fluviales mínimas de ríos Pan-Articos en Norteamérica.El artículo explora los patrones espaciales de caudales fluviales mínimos mensuales la región pan-ártica de Norteamérica y sus posibles factores de control haciendo uso de una regresión ponderada geográficamente (geographically weigted regression-GWR). Los caudales mínimos son indicadores de las condiciones del agua en el suelo, y por lo tanto el entendimiento de la variabilidad espacial de los factores que los controlan puede ayudar a comprender los patrones de cambio hidrológico. En el presente estudio, varios modelos de tipo GWR son aplicados para determinar una combinación adecuada de variables independientes seleccionadas a partir de un conjunto de ocho variables. El modelo que utiliza la media anual media de descarga fluvial, la temperatura en el momento de caudal mínimo, y el bioma, proporciona una buena descripción de los patrones espaciales en la descarga mínima. Sin embargo, en las cuencas hidrográficas grandes, la descarga mínima está más influenciada por la temperatura y la distribución de los biomas que en el caso de cuencas más pequeñas, lo que sugiere que la escala es fundamental para entender la descarga mínima fluvial. Este estudio es el primero en aplicar GWR para comprender la variación espacial en la hidrología de la región pan-ártica.基于GWR(地理加权回归模型)对北美泛北极地区月份最小河流流量的空间模式和潜在控制进行研究。最小流量暗示水土条件;因此,理解空间分异及控制可深刻理解水文变化的模式。GWR可从8个变量中提取一组独立变量的适当组合。通过年均河流流量、最小流量时的温度和生物群落,来描述最小下泄流量的空间格局。在大范围流域中,最小流量受到温度和生物群落分布的影响大于在小规模的流域,揭示出在河流最小流量分析中尺度是非常重要的。本文首次将GWR应用于泛北极水文空间异质性分析。},
    language = {en},
    number = {3},
    urldate = {2012-09-13},
    journal = {Geographical Analysis},
    author = {Rennermalm, Asa K. and Bring, Arvid and Mote, Thomas L.},
    year = {2012},
    pages = {202--218},
    file = {Full Text PDF:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/ZU62S2N4/Rennermalm et al. - 2012 - Spatial and Scale-Dependent Controls on North Amer.pdf:application/pdf;Snapshot:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/PH3CHWCZ/abstract.html:text/html}
    }
  15. [DOI] Jarsjö, J., Asokan, S. M., Prieto, C., Bring, A., & Destouni, G.. (2012). Hydrological responses to climate change conditioned by historic alterations of land-use and water-use. Hydrology and Earth System Sciences, 16(5), 1335-1347.
    [Bibtex]
    @article{jarsjo_hydrological_2012,
    title = {Hydrological responses to climate change conditioned by historic alterations of land-use and water-use},
    volume = {16},
    issn = {1607-7938},
    url = {http://www.hydrol-earth-syst-sci.net/16/1335/2012/},
    doi = {10.5194/hess-16-1335-2012},
    number = {5},
    urldate = {2012-09-12},
    journal = {Hydrology and Earth System Sciences},
    author = {Jarsjö, J. and Asokan, S. M. and Prieto, C. and Bring, A. and Destouni, G.},
    year = {2012},
    pages = {1335--1347},
    file = {Hydrol. Earth Syst. Sci. PDF:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/HIV4ZZ7T/Jarsjö et al. - 2012 - Hydrological responses to climate change condition.pdf:application/pdf;Hydrol. Earth Syst. Sci. Snapshot:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/7J83FDT2/2012.html:text/html}
    }
  16. [PDF] [DOI] Karlsson, J. M., Bring, A., Peterson, G. D., Gordon, L. J., & Destouni, G.. (2011). Opportunities and limitations to detect climate-related regime shifts in inland Arctic ecosystems through eco-hydrological monitoring. Environmental Research Letters, 6(1), 14015.
    [Bibtex]
    @article{karlsson_opportunities_2011,
    title = {Opportunities and limitations to detect climate-related regime shifts in inland {Arctic} ecosystems through eco-hydrological monitoring},
    volume = {6},
    issn = {1748-9326},
    url = {http://iopscience.iop.org/1748-9326/6/1/014015},
    doi = {10.1088/1748-9326/6/1/014015},
    number = {1},
    urldate = {2011-03-21},
    journal = {Environmental Research Letters},
    author = {Karlsson, Johanna Mård and Bring, Arvid and Peterson, Garry D and Gordon, Line J and Destouni, Georgia},
    year = {2011},
    pages = {014015},
    file = {MardKarlsson2011.pdf:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/C6MTRGDJ/MardKarlsson2011.pdf:application/pdf;Opportunities and limitations to detect climate-related regime shifts in inland Arctic ecosystems through eco-hydrological monitoring:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/U8BPWRNE/014015.html:text/html}
    }
  17. [PDF] [DOI] Dyurgerov, M. B., Bring, A., & Destouni, G.. (2010). Integrated assessment of changes in freshwater inflow to the Arctic Ocean. Journal of Geophysical Research. D. Atmospheres, 115, D12116.
    [Bibtex]
    @article{dyurgerov_integrated_2010,
    title = {Integrated assessment of changes in freshwater inflow to the {Arctic} {Ocean}},
    volume = {115},
    doi = {10.1029/2009JD013060},
    journal = {Journal of Geophysical Research. D. Atmospheres},
    author = {Dyurgerov, Mark B. and Bring, Arvid and Destouni, Georgia},
    year = {2010},
    pages = {D12116},
    file = {2009JD013060.pdf:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/B4TJR634/2009JD013060.pdf:application/pdf}
    }
  18. [PDF] [DOI] Bring, A., & Destouni, G.. (2011). Relevance of hydro-climatic change projection and monitoring for assessment of water cycle changes in the Arctic. AMBIO, 40(4), 361-369.
    [Bibtex]
    @article{bring_relevance_2011,
    title = {Relevance of hydro-climatic change projection and monitoring for assessment of water cycle changes in the {Arctic}},
    volume = {40},
    doi = {10.1007/s13280-010-0109-1},
    number = {4},
    journal = {AMBIO},
    author = {Bring, Arvid and Destouni, Georgia},
    year = {2011},
    pages = {361--369},
    file = {BringDestouni2010.pdf:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/TAJVCSCA/BringDestouni2010.pdf:application/pdf}
    }
  19. [PDF] [DOI] Bring, A., & Destouni, G.. (2009). Hydrological and hydrochemical observation status in the pan-Arctic drainage basin. Polar Research, 28, 327-338.
    [Bibtex]
    @article{bring_hydrological_2009,
    title = {Hydrological and hydrochemical observation status in the pan-{Arctic} drainage basin},
    volume = {28},
    issn = {0800-0395},
    url = {http://onlinelibrary.wiley.com/doi/10.1111/j.1751-8369.2009.00126.x/abstract},
    doi = {10.1111/j.1751-8369.2009.00126.x},
    abstract = {In order to identify and understand the ongoing changes in the Arctic hydrological cycle, and the impacts on the Arctic Ocean, timely and open access to water and water-chemistry data is essential. By synthesizing and analysing all openly accessible water-discharge and water-quality data, we present an updated, quantitative picture of the status of observational data on hydrological and hydrochemical fluxes from the pan-Arctic drainage basin (PADB) to the ocean. We identify and compare the characteristics of monitored and unmonitored areas, and the differences between them, across the continents in the PADB. Results indicate significant gaps in monitoring data for water chemistry, in particular for high-latitude near-coastal areas. The differences in characteristics between monitored and unmonitored areas may bias assessments of hydrological and hydrochemical fluxes to the Arctic Ocean. The reliable identification and understanding of important biogeochemical processes in the PADB require extended monitoring, particularly in high-latitude permafrost ground, and more ready access to harmonized and integrated hydrochemical data.},
    journal = {Polar Research},
    author = {Bring, Arvid and Destouni, Georgia},
    year = {2009},
    pages = {327--338},
    file = {BringDestouni2009.pdf:/Users/arvidbr/Documents/unison-root/su/misc/zotero/db/storage/57U8EEHG/BringDestouni2009.pdf:application/pdf}
    }

Conference papers and presentations

  1. Bring, A., Asokan, S. M., Jaramillo, F., Jarsjö, J., Levi, L., Pietron, J., Prieto, C., Rogberg, P., & Destouni, G.. (2016). Implications of freshwater flux data from the CMIP5 multi-model output across a set of Northern Hemisphere drainage basins. Paper presented at the International Conference on Regional Climate-CORDEX 2016 (ICRC-CORDEX 2016), Stockholm, Sweden.
    [Bibtex]
    @inproceedings{bring_implications_2016,
    address = {Stockholm, Sweden},
    booktitle = {International Conference on Regional Climate-CORDEX 2016 (ICRC-CORDEX 2016)},
    title = {Implications of freshwater flux data from the {CMIP}5 multi-model output across a set of {Northern} {Hemisphere} drainage basins},
    author = {Bring, Arvid and Asokan, Shilpa M. and Jaramillo, Fernando and Jarsjö, Jerker and Levi, Lea and Pietron, Jan and Prieto, Carmen and Rogberg, Peter and Destouni, Georgia},
    year = {2016},
    }
  2. Prowse, T., Bring, A., Carmack, E., Hinzman, L., & Karlsson, J. M.. (2015). Arctic freshwater synthesis: Sources, fluxes, storage and effects. Paper presented at the Fourth International Symposium on Arctic Research (ISAR-4), Arctic Science Summit Week, Toyama, Japan.
    [Bibtex]
    @inproceedings{prowse_arctic_2015,
    address = {Toyama, Japan},
    title = {Arctic freshwater synthesis: {Sources}, fluxes, storage and effects},
    booktitle = {Fourth {International} {Symposium} on {Arctic} {Research} ({ISAR}-4), {Arctic} {Science} {Summit} {Week}},
    author = {Prowse, Terry and Bring, Arvid and Carmack, Eddy and Hinzman, Larry and Karlsson, Johanna Mård},
    month = apr,
    year = {2015}
    }
  3. Bring, A., Fedorova, I., Dibike, Y., Hinzman, L., Mernild, S. H., Prowse, T., Semenova, O., Stuefer, S., & Woo, M.. (2015). Arctic terrestrial hydrology: A synthesis of processes, change drivers and research challenges. Paper presented at the Fourth International Symposium on Arctic Research (ISAR-4), Arctic Science Summit Week, Toyama, Japan.
    [Bibtex]
    @inproceedings{bring_arctic_2015,
    address = {Toyama, Japan},
    title = {Arctic terrestrial hydrology: {A} synthesis of processes, change drivers and research challenges},
    booktitle = {Fourth {International} {Symposium} on {Arctic} {Research} ({ISAR}-4), {Arctic} {Science} {Summit} {Week}},
    author = {Bring, Arvid and Fedorova, Irina and Dibike, Yonas and Hinzman, Larry and Mernild, Sebastian H. and Prowse, Terry and Semenova, Olga and Stuefer, Sveta and Woo, Ming-Ko},
    month = apr,
    year = {2015}
    }
  4. Bring, A., & Lammers, R. B.. (2015). Identifying aquatic sensor locations to monitor changes to river flows. Paper presented at the EPSCoR New Hampshire all-hands meeting, Durham, NH, USA.
    [Bibtex]
    @inproceedings{bring_identifying_2015,
    address = {Durham, NH, USA},
    title = {Identifying aquatic sensor locations to monitor changes to river flows},
    booktitle = {{EPSCoR} {New} {Hampshire} all-hands meeting},
    author = {Bring, Arvid and Lammers, Richard B.},
    month = mar,
    year = {2015}
    }
  5. Destouni, G., Asokan, S. M., Augustsson, A., Balfors, B., Bring, A., Jaramillo, F., Jarsjö, J., Johansson, E., Juston, J. M., Levi, L., Olofsson, B., Prieto, C., Quin, A., Åström, M. E., & Cvetkovic, V.. (2014). Biogeochemical Transformation Pathways through the Land-water Geosphere.. Paper presented at the AGU Fall Meeting, San Francisco, CA, USA.
    [Bibtex]
    @inproceedings{destouni_biogeochemical_2014,
    address = {San Francisco, CA, USA},
    title = {Biogeochemical {Transformation} {Pathways} through the {Land}-water {Geosphere}.},
    booktitle = {{AGU} {Fall} {Meeting}},
    author = {Destouni, Georgia and Asokan, Shilpa M. and Augustsson, Anna and Balfors, Berit and Bring, Arvid and Jaramillo, Fernando and Jarsjö, Jerker and Johansson, Emma and Juston, John M. and Levi, Lea and Olofsson, Bo and Prieto, Carmen and Quin, Andrew and Åström, M.E. and Cvetkovic, Vladimir},
    month = dec,
    year = {2014},
    note = {Abstract ID: 4955}
    }
  6. Levi, L., Andricevic, R., Bring, A., Jaramillo, F., Pietron, J., Rogberg, P., & Destouni, G.. (2014). CMIP5 multi-model ensemble results applied to hydro-climatic change in the Sava River Basin. Paper presented at the EGU General Assembly, Vienna, Austria.
    [Bibtex]
    @inproceedings{levi_cmip5_2014,
    address = {Vienna, Austria},
    title = {{CMIP}5 multi-model ensemble results applied to hydro-climatic change in the {Sava} {River} {Basin}},
    booktitle = {{EGU} {General} {Assembly}},
    author = {Levi, Lea and Andricevic, Roko and Bring, Arvid and Jaramillo, Fernando and Pietron, Jan and Rogberg, Peter and Destouni, Georgia},
    month = apr,
    year = {2014}
    }
  7. Bring, A., & Destouni, G.. (2013). Information relevance for scenarios of Arctic climate and water change. Paper presented at the Arctic Science Summit Week, Krakow, Poland.
    [Bibtex]
    @inproceedings{bring_information_2013,
    address = {Krakow, Poland},
    title = {Information relevance for scenarios of {Arctic} climate and water change},
    booktitle = {Arctic {Science} {Summit} {Week}},
    author = {Bring, A. and Destouni, Georgia},
    year = {2013}
    }
  8. Azcárate, J., Balfors, B., Destouni, G., & Bring, A.. (2013). Scenario-based Transboundary Approach to Shape Arctic Futures. Paper presented at the Arctic Science Summit Week, Krakow, Poland.
    [Bibtex]
    @inproceedings{azcarate_scenario-based_2013,
    address = {Krakow, Poland},
    title = {Scenario-based {Transboundary} {Approach} to {Shape} {Arctic} {Futures}},
    booktitle = {Arctic {Science} {Summit} {Week}},
    author = {Azcárate, Juan and Balfors, Berit and Destouni, Georgia and Bring, Arvid},
    year = {2013}
    }
  9. Bring, A., & Destouni, G.. (2012). Hydro-climatic change indications of Arctic permafrost thawing. Paper presented at the Tenth International Conference on Permafrost (TICOP), Salekhard, Russia.
    [Bibtex]
    @inproceedings{bring_hydro-climatic_2012,
    address = {Salekhard, Russia},
    title = {Hydro-climatic change indications of {Arctic} permafrost thawing},
    booktitle = {Tenth {International} {Conference} on {Permafrost} ({TICOP})},
    author = {Bring, Arvid and Destouni, Georgia},
    year = {2012}
    }
  10. Bring, A., & Destouni, G.. (2012). Divergent relevance and prioritization basis for hydro-climatic change monitoring in the Arctic. Paper presented at the AGU Fall Meeting, San Francisco, CA, USA.
    [Bibtex]
    @inproceedings{bring_divergent_2012,
    address = {San Francisco, CA, USA},
    title = {Divergent relevance and prioritization basis for hydro-climatic change monitoring in the {Arctic}},
    booktitle = {{AGU} {Fall} {Meeting}},
    author = {Bring, Arvid and Destouni, Georgia},
    year = {2012}
    }
  11. Bring, A., & Destouni, G.. (2011). Relevance of hydro-climatic change projection and monitoring for assessment of water cycle changes in the Arctic. Paper presented at the EGU General Assembly, Vienna, Austria.
    [Bibtex]
    @inproceedings{bring_relevance_2011x,
    address = {Vienna, Austria},
    title = {Relevance of hydro-climatic change projection and monitoring for assessment of water cycle changes in the {Arctic}},
    booktitle = {{EGU} {General} {Assembly}},
    author = {Bring, Arvid and Destouni, Georgia},
    year = {2011}
    }
  12. Azcárate, J., Balfors, B., Bring, A., Destouni, G., & Mörtberg, U.. (2011). Shaping a sustainability strategy for the Arctic. Paper presented at the 31st Annual Meeting of the International Association for Impact Assessment, Puebla, Mexico.
    [Bibtex]
    @inproceedings{azcarate_shaping_2011,
    address = {Puebla, Mexico},
    title = {Shaping a sustainability strategy for the {Arctic}},
    booktitle = {31st {Annual} {Meeting} of the {International} {Association} for {Impact} {Assessment}},
    author = {Azcárate, Juan and Balfors, Berit and Bring, Arvid and Destouni, Georgia and Mörtberg, Ulla},
    year = {2011}
    }
  13. Mård Karlsson, J., Bring, A., & Destouni, G.. (2010). Ecohydrological monitoring blindness to Arctic ecosystem regime shifts. Paper presented at the AGU Fall Meeting, San Francisco, CA, USA.
    [Bibtex]
    @inproceedings{mard_karlsson_ecohydrological_2010,
    address = {San Francisco, CA, USA},
    title = {Ecohydrological monitoring blindness to {Arctic} ecosystem regime shifts},
    booktitle = {{AGU} {Fall} {Meeting}},
    author = {Mård Karlsson, Johanna and Bring, Arvid and Destouni, Georgia},
    year = {2010}
    }
  14. Bring, A., & Destouni, G.. (2008). Spatial patterns of decline in Pan-Arctic drainage basin monitoring: a vulnerability map. Paper presented at the XXV Nordic Hydrological Conference, Reykjavík, Iceland.
    [Bibtex]
    @inproceedings{bring_spatial_2008,
    address = {Reykjavík, Iceland},
    title = {Spatial patterns of decline in {Pan}-{Arctic} drainage basin monitoring: a vulnerability map},
    booktitle = {{XXV} {Nordic} {Hydrological} {Conference}},
    author = {Bring, Arvid and Destouni, Georgia},
    year = {2008}
    }
  15. Bring, A., Destouni, G., & Hannerz, F.. (2007). Pan-Arctic drainage basin monitoring: current status and potential significance for assessment of climate change impacts. Paper presented at the ARCUS Arctic Forum, Washington, DC, USA.
    [Bibtex]
    @inproceedings{bring_pan-arctic_2007,
    address = {Washington, DC, USA},
    title = {Pan-{Arctic} drainage basin monitoring: current status and potential significance for assessment of climate change impacts},
    booktitle = {{ARCUS} {Arctic} {Forum}},
    author = {Bring, Arvid and Destouni, Georgia and Hannerz, Fredrik},
    year = {2007}
    }
  16. Bring, A., Destouni, G., & Hannerz, F.. (2007). Pan-Arctic drainage basin monitoring: current status and potential significance for assessment of climate change effects and feedbacks. Paper presented at the Third International Conference on Climate & Water, Helsinki, Finland.
    [Bibtex]
    @inproceedings{bring_pan-arctic_2007-1,
    address = {Helsinki, Finland},
    title = {Pan-{Arctic} drainage basin monitoring: current status and potential significance for assessment of climate change effects and feedbacks},
    booktitle = {Third {International} {Conference} on {Climate} \& {Water}},
    author = {Bring, Arvid and Destouni, Georgia and Hannerz, Fredrik},
    year = {2007}
    }

Book chapter

  1. Bring, A., Jarsjö, J., & Destouni, G.. (2015). Water Information and Water Security in the Arctic. In Evengård, B., Nymand Larsen, J., & Paasche, Ø. (Eds.), In The New Arctic Cham, Switzerland: Springer International Publishing.
    [Bibtex]
    @incollection{bring_water_2015,
    address = {Cham, Switzerland},
    title = {Water {Information} and {Water} {Security} in the {Arctic}},
    isbn = {978-3-319-17601-7},
    booktitle = {The {New} {Arctic}},
    publisher = {Springer International Publishing},
    author = {Bring, Arvid and Jarsjö, Jerker and Destouni, Georgia},
    editor = {Evengård, Birgitta and Nymand Larsen, Joan and Paasche, Øyvind},
    year = {2015},
    note = {Chapter DOI from e-book: 10.1007/978-3-319-17602-4\_17
    Total pages 380.}
    }

Reports and working papers

  1. [PDF] Bring, A., & Sjoberg, E.. (2017). Complex climate effects on cooperation and disputes in transboundary river basins (No. 2017-02). University of Utah working paper.
    [Bibtex]
    @techreport{bring_sjoberg_2017,
    title = {Complex climate effects on cooperation and disputes in transboundary river basins},
    url = {http://econ.utah.edu/research/publications/2017_02.pdf},
    number = {2017-02},
    institution = {University of Utah working paper},
    author = {Bring, Arvid and Sjoberg, Eric},
    year = {2017}
    }
  2. Destouni, G., Asokan, S. M., Augustsson, A., Balfors, B., Bring, A., Jaramillo, F., Jarsjö, J., Johansson, E., Juston, J. M., Levi, L., Olofsson, B., Prieto, C., Quin, A., Åström, M., & Cvetkovic, V.. (2015). Needs and means to advance science, policy and management understanding of the freshwater system – A synthesis report (Research project: Climate-land-water changes and integrated water resource management in coastal regions (KLIV)). Stockholm University, KTH Royal Institute of Technology, and Linneaus University.
    [Bibtex]
    @techreport{destouni_needs_2015,
    type = {Research project: Climate-land-water changes and integrated water resource management in coastal regions (KLIV)},
    title = {Needs and means to advance science, policy and management understanding of the freshwater system – {A} synthesis report},
    url = {http://urn.kb.se/resolve?urn=urn:nbn:se:su:diva-117549},
    institution = {Stockholm University, KTH Royal Institute of Technology, and Linneaus University},
    author = {Destouni, Georgia and Asokan, Shilpa M. and Augustsson, Anna and Balfors, Berit and Bring, Arvid and Jaramillo, Fernando and Jarsjö, Jerker and Johansson, Emma and Juston, John M. and Levi, Lea and Olofsson, Bo and Prieto, Carmen and Quin, Andrew and Åström, Mats and Cvetkovic, Vladimir},
    year = {2015}
    }
  3. [PDF] Baraibar, M., & Bring, A.. (2011). Tvärvetenskapliga doktorandgruppen inom miljöforskning, 2000-2010 [Interdisciplinary environmental research PhD group, 2000-2010; in Swedish with English Summary] Stockholm, Sweden: Stockholm Resilience Centre.
    [Bibtex]
    @techreport{baraibar_tvarvetenskapliga_2011,
    address = {Stockholm, Sweden},
    title = {Tvärvetenskapliga doktorandgruppen inom miljöforskning, 2000-2010 [{Interdisciplinary} environmental research {PhD} group, 2000-2010; in {Swedish} with {English} {Summary}]},
    institution = {Stockholm Resilience Centre},
    author = {Baraibar, Matilda and Bring, Arvid},
    year = {2011},
    pages = {20}
    }

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Researcher in water, climate, and water information