Your search keyword '"RIVERS"' showing total 170 results

1. Evaluating the effects of downscaled climate projections on groundwater storage and simulated base-flow contribution to the North Fork Red River and Lake Altus, southwest Oklahoma (USA).

Author

Labriola, Laura G., Ellis, John H., Gangopadhyay, Subhrendu, Pruitt, Tom, Kirstsetter, Pierre-Emmanuel, and Hong, Yang

Subjects

GROUNDWATER flow, CLIMATOLOGY, GROUNDWATER recharge, RIVERS, GROUNDWATER, LAKES

Abstract

Copyright of Hydrogeology Journal is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

2. Uncertainty of annual runoff projections in Lithuanian rivers under a future climate.

Author

Akstinas, V., Jakimavǐius, D., Meilutytė-Lukauskienė, D., Kriaǔiūnienė, J., and Šarauskiene, D.

Subjects

*DOWNSCALING (Climatology), *RIVERS, *UNCERTAINTY, *GRID cells, *CLIMATOLOGY

Abstract

Uncertainties of runoff projections arise from different sources of origin, such as climate scenarios (RCPs), global climate models (GCMs) and statistical downscaling (SD) methods. Assessment of uncertainties related to the mentioned sources was carried out for selected rivers of Lithuania (Minija, Nevėžis and Šventoji). These rivers reflect conditions of different hydrological regions (western, central and southeastern). Using HBV software, hydrological models were created for river runoff projections in the near (2021-2040) and far (2081-2100) future. The runoff projections according to three RCP scenarios, three GCMs and three SD methods were created. In the Western hydrological region represented by the Minija River, the GCMs were the most dominant uncertainty source (41.0-44.5%) in the runoff projections. Meanwhile, uncertainties of runoff projections from central (Nevėžis River) and southeastern (Šventoji River) regions of Lithuania were related to SD methods and the range of uncertainties fluctuates from 39.4% to 60.9%. In western Lithuania, the main source of rivers' supply is precipitation, where projections highly depend on selected GCMs. The rivers from central and southeastern regions are more sensitive to the SD methods, which not always precisely adjust the meteorological variables from a large grid cell of GCM into catchment scale. [ABSTRACT FROM AUTHOR]

Published

2020

3. Extreme climate events can slow down litter breakdown in streams.

Author

Correa-Araneda, Francisco, Tonin, Alan M., Pérez, Javier, Álvarez, Katia, López-Rojo, Naiara, Díaz, Angie, Esse, Carlos, Encina-Montoya, Francisco, Figueroa, Ricardo, Cornejo, Aydeé, and Boyero, Luz

Subjects

*FOREST litter, *RIVERS, *BIOGEOCHEMICAL cycles, *WEATHER, *CLIMATOLOGY

Abstract

Extreme temperatures have increased in intensity, duration and frequency in the last century, with potential consequences on key ecological processes such as organic matter breakdown. Many stream ecosystems are fueled by the breakdown of terrestrial leaf litter, which is exposed to atmospheric conditions for certain periods of time before entering the stream. Thus, extreme warming or freezing events may affect the litter physicochemical structure, which could translate into altered breakdown within the stream. The above prediction was tested by exposing litter of common riparian tree species in southern Chile to freezing (−20 ºC; dry or wet litter) or heating (40 ºC) and comparing breakdown with control litter exposed to room temperature (20 ºC), separating the effects of different breakdown agents (i.e., leaching, microorganisms and detritivores). The greatest effects were found in wet litter subjected to freezing; this treatment significantly increased leaching in the short term (48 h) and slowed down breakdown in the long term (30 days), mostly due to the inhibition of microbial breakdown. Heating also retarded microbial breakdown, but the effect was smaller. Our results suggest that short-term extreme temperatures—particularly cold ones—have the potential to slow down litter breakdown in streams, which will most likely impact global biogeochemical cycles where streams play a key role. [ABSTRACT FROM AUTHOR]

Published

2020

4. Climate change impact on fluvial flooding in the Indian sub-basin: A case study on the Adyar sub-basin.

Author

Ramachandran, Andimuthu, Palanivelu, Kandasamy, Mudgal, B. V., Jeganathan, Anushiya, Guganesh, Sankar, Abinaya, Balu, and Elangovan, Arunbabu

Subjects

*CLIMATE change, *FLOOD risk, *AQUATIC sciences, *ATMOSPHERIC sciences, *ENVIRONMENTAL sciences, *OCEANOGRAPHY

Abstract

Flooding is one of the most disastrous global hazards, which has been occurring more frequently in recent times. It is observed that climate change is likely to increase the intensity and the frequency of floods and river basins have become more vulnerable to fluvial flooding. In this study, the impact of climate change on fluvial flooding was analyzed over the Adyar sub-basin. This study applied statistically downscaled Global Climate Model (GCM) data in a CMIP5 dataset of IPCC Assessment Report 5 (AR5). Based on the performance to simulate the observed climate, four GCMs, namely, cesm1-cam5, mpi-esm-mr, ncar-ccsm4, and bnu-esm, for RCP 4.5 were selected for projections of the future scenario. The Intensity-Duration-Frequency (IDF) curves for the past and future scenarios were derived from the IMD-observed and GCM-projected rainfall data. Integrated flood modeling was performed with hydrologic (HEC-HMS) and hydraulic (HEC-RAS) models. Finally, in order to visualize the inundation areas according to the future climate projection, flood inundation maps were prepared geospatially using the ArcGIS software. For the 100-year return period, the results predict that the peak discharge for the future climate scenario would increase by 34.3%–91.9% as compared to the present climate scenario. Similarly, the future projections show an increase in the flooded area ranging from 12.6% to 26.4% based on GCMs. This simulation helps in understanding the flood risk over the Adyar sub-basin under the changing climate and the requirement for the regulation of developmental activities over the flood-prone areas. [ABSTRACT FROM AUTHOR]

Published

2019

5. Linking atmospheric, terrestrial and aquatic environments: Regime shifts in the Estonian climate over the past 50 years.

Author

Kotta, Jonne, Herkül, Kristjan, Jaagus, Jaak, Kaasik, Ants, Raudsepp, Urmas, Alari, Victor, Arula, Timo, Haberman, Juta, Järvet, Arvo, Kangur, Külli, Kont, Are, Kull, Ain, Laanemets, Jaan, Maljutenko, Ilja, Männik, Aarne, Nõges, Peeter, Nõges, Tiina, Ojaveer, Henn, Peterson, Anneliis, and Reihan, Alvina

Subjects

*AQUATIC ecology, *WELL-being, *CLIMATE change, *ECOLOGICAL regime shifts, *MARINE ecology

Abstract

Climate change in recent decades has been identified as a significant threat to natural environments and human wellbeing. This is because some of the contemporary changes to climate are abrupt and result in persistent changes in the state of natural systems; so called regime shifts (RS). This study aimed to detect and analyse the timing and strength of RS in Estonian climate at the half-century scale (1966−2013). We demonstrate that the extensive winter warming of the Northern Hemisphere in the late 1980s was represented in atmospheric, terrestrial, freshwater and marine systems to an extent not observed before or after the event within the studied time series. In 1989, abiotic variables displayed statistically significant regime shifts in atmospheric, river and marine systems, but not in lake and bog systems. This was followed by regime shifts in the biotic time series of bogs and marine ecosystems in 1990. However, many biotic time series lacked regime shifts, or the shifts were uncoupled from large-scale atmospheric circulation. We suggest that the latter is possibly due to complex and temporally variable interactions between abiotic and biotic elements with ecosystem properties buffering biotic responses to climate change signals, as well as being affected by concurrent anthropogenic impacts on natural environments. [ABSTRACT FROM AUTHOR]

Published

2018

6. Hydrometeorology and flood pulse dynamics drive diarrheal disease outbreaks and increase vulnerability to climate change in surface-water-dependent populations: A retrospective analysis.

Author

Alexander, Kathleen A., Heaney, Alexandra K., and Shaman, Jeffrey

Subjects

*HYDROMETEOROLOGY, *DIARRHEA, *CLIMATE change, *WATER quality, *CLIMATOLOGY, *CLINICAL pathology, *ESCHERICHIA coli

Abstract

Background: The impacts of climate change on surface water, waterborne disease, and human health remain a growing area of concern, particularly in Africa, where diarrheal disease is one of the most important health threats to children under 5 years of age. Little is known about the role of surface water and annual flood dynamics (flood pulse) on waterborne disease and human health nor about the expected impact of climate change on surface-water-dependent populations. Methods and findings: Using the Chobe River in northern Botswana, a flood pulse river—floodplain system, we applied multimodel inference approaches assessing the influence of river height, water quality (bimonthly counts of Escherichia coli and total suspended solids [TSS], 2011–2017), and meteorological variability on weekly diarrheal case reports among children under 5 presenting to health facilities (n = 10 health facilities, January 2007–June 2017). We assessed diarrheal cases by clinical characteristics and season across age groups using monthly outpatient data (January 1998–June 2017). A strong seasonal pattern was identified, with 2 outbreaks occurring regularly in the wet and dry seasons. The timing of outbreaks diverged from that at the level of the country, where surface water is largely absent. Across age groups, the number of diarrheal cases was greater, on average, during the dry season. Demographic and clinical characteristics varied by season, underscoring the importance of environmental drivers. In the wet season, rainfall (8-week lag) had a significant influence on under-5 diarrhea, with a 10-mm increase in rainfall associated with an estimated 6.5% rise in the number of cases. Rainfall, minimum temperature, and river height were predictive of E. coli concentration, and increases in E. coli in the river were positively associated with diarrheal cases. In the dry season, river height (1-week lag) and maximum temperature (1- and 4-week lag) were significantly associated with diarrheal cases. During this period, a 1-meter drop in river height corresponded to an estimated 16.7% and 16.1% increase in reported diarrhea with a 1- and 4-week lag, respectively. In this region, as floodwaters receded from the surrounding floodplains, TSS levels increased and were positively associated with diarrheal cases (0- and 3-week lag). Populations living in this region utilized improved water sources, suggesting that hydrological variability and rapid water quality shifts in surface waters may compromise water treatment processes. Limitations include the potential influence of health beliefs and health seeking behaviors on data obtained through passive surveillance. Conclusions: In flood pulse river—floodplain systems, hydrology and water quality dynamics can be highly variable, potentially impacting conventional water treatment facilities and the production of safe drinking water. In Southern Africa, climate change is predicted to intensify hydrological variability and the frequency of extreme weather events, amplifying the public health threat of waterborne disease in surface-water-dependent populations. Water sector development should be prioritized with urgency, incorporating technologies that are robust to local environmental conditions and expected climate-driven impacts. In populations with high HIV burdens, expansion of diarrheal disease surveillance and intervention strategies may also be needed. As annual flood pulse processes are predominantly influenced by climate controls in distant regions, country-level data may be inadequate to refine predictions of climate—health interactions in these systems. [ABSTRACT FROM AUTHOR]

Published

2018

7. Multiple non-climatic drivers of food insecurity reinforce climate change maladaptation trajectories among Peruvian Indigenous Shawi in the Amazon.

Author

Zavaleta, Carol, Berrang-Ford, Lea, Ford, James, Llanos-Cuentas, Alejandro, Cárcamo, César, Ross, Nancy A., Lancha, Guillermo, Sherman, Mya, Harper, Sherilee L., and null, null

Subjects

*FOOD security, *CLIMATE change, *POPULATION, *DEFICIENCY diseases, *MEDICAL sciences, *SHAWI (South American people)

Abstract

Background: Climate change is affecting food systems globally, with implications for food security, nutrition, and the health of human populations. There are limited data characterizing the current and future consequences of climate change on local food security for populations already experiencing poor nutritional indicators. Indigenous Amazonian populations have a high reported prevalence of nutritional deficiencies. This paper characterizes the food system of the Shawi of the Peruvian Amazon, climatic and non-climatic drivers of their food security vulnerability to climate change, and identifies potential maladaptation trajectories. Methods and findings: Semi-structured interviews with key informants (n = 24), three photovoice workshops (n = 17 individuals), transect walks (n = 2), a food calendar exercise, and two community dissemination meetings (n = 30 individuals), were conducted within two Shawi communities in Balsapuerto District in the Peruvian Loreto region between June and September of 2014. The Shawi food system was based on three main food sub-systems (forest, farming and externally-sourced). Shawi reported collective, gendered, and emotional notions related to their food system activities. Climatic and non-climatic drivers of food security vulnerability among Shawi participants acted at proximal and distal levels, and mutually reinforced key maladaptation trajectories, including: 1) a growing population and natural resource degradation coupled with limited opportunities to increase incomes, and 2) a desire for education and deforestation reinforced by governmental social and food interventions. Conclusion: A series of maladaptive trajectories have the potential to increase social and nutritional inequities for the Shawi. Transformational food security adaptation should include consideration of Indigenous perceptions and priorities, and should be part of Peruvian food and socioeconomic development policies. [ABSTRACT FROM AUTHOR]

Published

2018

8. Forecasting effects of angler harvest and climate change on smallmouth bass abundance at the southern edge of their range.

Author

Middaugh, Christopher R. and Magoulick, Daniel D.

Subjects

*SMALLMOUTH bass, *CLIMATE change, *WEATHER forecasting, *WARMWATER fishes, *SIMULATION methods & models, *ANIMAL behavior

Abstract

Climate change will affect stream systems in numerous ways over the coming century. Globally, streams are expected to experience changes in temperature and flow regime. Previous work has indicated that these changes will likely affect fish distributions, but little work has been conducted examining population level effects of climate change on warmwater fish at the warmest portion of their range. We model several potential climate change-related stressors and the resulting effects on smallmouth bass Micropterus dolomieu populations in the Buffalo National River, Arkansas, USA, located near the southern extent of smallmouth bass range. Smallmouth bass are a popular recreational fish in the region and angler harvest likely contributes substantially to annual mortality. We created a simulation model parameterized with data collected from the Buffalo National River to evaluate the relative importance of climate stressors and angler harvest on smallmouth bass populations. Our simulations suggest that increases in springtime temperature and reductions in river discharge during the spawning period could increase recruitment, resulting in increases in adult abundance (8% higher). However, when increased flooding and drought probabilities are considered, our model indicates the Buffalo National River could experience large reductions in adult smallmouth bass abundance (≥50% decline) and increased probability of extinction compared to present levels. Simulations showed that harvest reduction could be a viable strategy to reduce the negative effects of climate change, but that even with complete closure of harvest, smallmouth bass population levels would still be well below present abundance (46% lower than present). Efforts to reduce flooding and drought effects related to climate change in the Buffalo National River could help offset the predicted reduction in the smallmouth bass population. [ABSTRACT FROM AUTHOR]

Published

2018

9. Dissolved organic carbon in streams within a subarctic catchment analysed using a GIS/remote sensing approach.

Author

Mzobe, Pearl, Berggren, Martin, Pilesjö, Petter, Lundin, Erik, Olefeldt, David, Roulet, Nigel T., and Persson, Andreas

Subjects

*CARBON content of water, *WATERSHEDS, *REMOTE sensing, *CLIMATE change, *METEOROLOGICAL precipitation, *ATMOSPHERIC temperature

Abstract

Climate change projections show that temperature and precipitation increases can alter the exchange of greenhouse gases between the atmosphere and high latitude landscapes, including their freshwaters. Dissolved organic carbon (DOC) plays an important role in greenhouse gas emissions, but the impact of catchment productivity on DOC release to subarctic waters remains poorly known, especially at regional scales. We test the hypothesis that increased terrestrial productivity, as indicated by the normalized difference vegetation index (NDVI), generates higher stream DOC concentrations in the Stordalen catchment in subarctic Sweden. Furthermore, we aimed to determine the degree to which other generic catchment properties (elevation, slope) explain DOC concentration, and whether or not land cover variables representing the local vegetation type (e.g., mire, forest) need to be included to obtain adequate predictive models for DOC delivered into rivers. We show that the land cover type, especially the proportion of mire, played a dominant role in the catchment’s release of DOC, while NDVI, slope, and elevation were supporting predictor variables. The NDVI as a single predictor showed weak and inconsistent relationships to DOC concentrations in recipient waters, yet NDVI was a significant positive regulator of DOC in multiple regression models that included land cover variables. Our study illustrates that vegetation type exerts primary control in DOC regulation in Stordalen, while productivity (NDVI) is of secondary importance. Thus, predictive multiple linear regression models for DOC can be utilized combining these different types of explanatory variables. [ABSTRACT FROM AUTHOR]

Published

2018

10. Runoff response to climate change and human activities in a typical karst watershed, SW China.

Author

Xu, Yan, Wang, Shijie, Bai, Xiaoyong, Shu, Dongcai, and Tian, Yichao

Subjects

*KARST, *RUNOFF, *CLIMATE change, *WATERSHEDS, *SUSTAINABLE development

Abstract

This study aims to reveal the runoff variation characteristics of long time series in a karst region, analyse comprehensively its different driving factors, and estimate quantitatively the contribution rates of climate change and human activities to net runoff variation. Liudong river basin, a typical karst watershed in southwest China, is the study site. Statistical methods, such as linear fitting, the Morlet wavelet analysis, normalized curve and double mass curve, are applied to analyse the runoff of the watershed. Results show that the runoff in the karst watershed during the research period exhibits a three-stage change and the abrupt change points are the years 1981 and 2007: (1) 1968–1980, the runoff initially exhibited a trend of sustained decreasing and then an abrupt fluctuation. The runoff was obviously destroyed through precipitation-producing processes. Improper land utilisation and serious forest and grass destruction intensified the fluctuation variation amplitude of the runoff. (2) 1981–2006, the changing processes of runoff and precipitation exhibited good synchronism. Precipitation significantly affected runoff variation and human activities had a slight interference degree. (3) 2007–2013, the fluctuation range of runoff was considerably smaller than that of precipitation. The significant growth of forest and grassland areas and the increase in water consumption mitigated runoff fluctuation and greatly diminished runoff variation amplitude. According to calculation, the relative contribution rates of precipitation and human activities to net runoff variation with 1981–2007 as the reference period were −81% and 181% in average, respectively, during 1968–1980, and −117% and 217% in average, respectively, during 2007–2013. In general, the analysis of runoff variation trend and of the contribution rate of its main influencing factors in the typical karst watershed for nearly half a century may be significant to solve the drought problem in the karst region and for the sustainable development of the drainage basin. [ABSTRACT FROM AUTHOR]

Published

2018

11. Future changes in hydro-climatic extremes in the Upper Indus, Ganges, and Brahmaputra River basins.

Author

Wijngaard, René R., Lutz, Arthur F., Nepal, Santosh, Khanal, Sonu, Pradhananga, Saurav, Shrestha, Arun B., and Immerzeel, Walter W.

Subjects

*WATERSHEDS, *GENERAL circulation model, *DROUGHTS, *FLOODS & society, SOCIAL aspects

Abstract

Future hydrological extremes, such as floods and droughts, may pose serious threats for the livelihoods in the upstream domains of the Indus, Ganges, Brahmaputra. For this reason, the impacts of climate change on future hydrological extremes is investigated in these river basins. We use a fully-distributed cryospheric-hydrological model to simulate current and future hydrological fluxes and force the model with an ensemble of 8 downscaled General Circulation Models (GCMs) that are selected from the RCP4.5 and RCP8.5 scenarios. The model is calibrated on observed daily discharge and geodetic mass balances. The climate forcing and the outputs of the hydrological model are used to evaluate future changes in climatic extremes, and hydrological extremes by focusing on high and low flows. The outcomes show an increase in the magnitude of climatic means and extremes towards the end of the 21st century where climatic extremes tend to increase stronger than climatic means. Future mean discharge and high flow conditions will very likely increase. These increases might mainly be the result of increasing precipitation extremes. To some extent temperature extremes might also contribute to increasing discharge extremes, although this is highly dependent on magnitude of change in temperature extremes. Low flow conditions may occur less frequently, although the uncertainties in low flow projections can be high. The results of this study may contribute to improved understanding on the implications of climate change for the occurrence of future hydrological extremes in the Hindu Kush–Himalayan region. [ABSTRACT FROM AUTHOR]

Published

2017

12. End-member modelling as a tool for climate reconstruction—An Eastern Mediterranean case study.

Author

Beuscher, Sarah, Krüger, Stefan, Ehrmann, Werner, Schmiedl, Gerhard, Milker, Yvonne, Arz, Helge, and Schulz, Hartmut

Subjects

*TERRIGENOUS sediments, *CLIMATE change, *PARTICLE size distribution, *CLIMATE reconstruction (Research), *SEDIMENT transport

Abstract

The Eastern Mediterranean Sea is a sink for terrigenous sediments from North Africa, Europe and Asia Minor. Its sediments therefore provide valuable information on the climate dynamics in the source areas and the associated transport processes. We present a high-resolution dataset of sediment core M40/4_SL71, which was collected SW of Crete and spans the last ca. 180 kyr. We analysed the clay mineral composition, the grain size distribution within the silt fraction, and the abundance of major and trace elements. We tested the potential of end-member modelling on these sedimentological datasets as a tool for reconstructing the climate variability in the source regions and the associated detrital input. For each dataset, we modelled three end members. All end members were assigned to a specific provenance and sedimentary process. In total, three end members were related to the Saharan dust input, and five were related to the fluvial sediment input. One end member was strongly associated with the sapropel layers. The Saharan dust end members of the grain size and clay mineral datasets generally suggest enhanced dust export into the Eastern Mediterranean Sea during the dry phases with short-term increases during Heinrich events. During the African Humid Periods, dust export was reduced but may not have completely ceased. The loading patterns of two fluvial end members show a strong relationship with the Northern Hemisphere insolation, and all fluvial end members document enhanced input during the African Humid Periods. The sapropel end member most likely reflects the fixation of redox-sensitive elements within the anoxic sapropel layers. Our results exemplify that end-member modelling is a valuable tool for interpreting extensive and multidisciplinary datasets. [ABSTRACT FROM AUTHOR]

Published

2017

13. Potential impact of climate change on streamflow of major Ethiopian rivers.

Author

Gizaw, Mesgana, Biftu, Getu, Gan, Thian, Moges, Semu, and Koivusalo, Harri

Subjects

CLIMATE change, RIVERS, CLIMATOLOGY, BODIES of water, WATERSHEDS

Abstract

In this study, HSPF (Hydrologic Simulation Program-FORTRAN) was used to analyze the potential impact of climate change on the streamflow of four major river basins in Ethiopia: Awash, Baro, Genale, and Tekeze. The calibrated and validated HSPF model was forced with daily climate data of 10 CMIP5 (Coupled Model Intercomparison Project phase 5) Global Climate Models (GCMs) for the 1971-2000 control period and the RCP4.5 and RCP8.5 climate projections of 2041-2070 (2050s) and 2071-2100 (2080s). The ensemble median of these 10 GCMs projects the temperature in the four study areas to increase by about 2.3 °C (3.3 °C) in 2050s (2080s), whereas the mean annual precipitation is projected to increase by about 6% (9%) in 2050s (2080s). This results in about 3% (6%) increase in the projected annual streamflow in Awash, Baro, and Tekeze rivers whereas the annual streamflow of Genale river is projected to increase by about 18% (33%) in the 2050s (2080s). However, such projected increase in the mean annual streamflow due to increasing precipitation over Ethiopia contradicts the decreasing trends in mean annual precipitation observed in recent decades. Regional climate models of high resolutions could provide more realistic climate projections for Ethiopia's complex topography, thus reducing the uncertainties in future streamflow projections. [ABSTRACT FROM AUTHOR]

Published

2017

14. How did rivers in the wet tropics (NE Queensland, Australia) respond to climate changes over the past 30 000 years?

Author

Hughes, Kate and Croke, Jacky

Subjects

RIVERS, BODIES of water, CLIMATOLOGY, CLIMATE change

Abstract

ABSTRACT The nature and timing of fluvial response and coincident changes in climate as inferred from multiple, independent proxies are examined in the wet tropics of north-eastern Australia. Chronostratigraphic data provide evidence for regionally synchronous fluvial aggradation at 30-13 ka, 8-5 ka and again from 1 ka. Terrace incision and removal occurred at 13-8 ka and 5-1 ka. A new synthesis of regional palaeoenvironmental proxy records spanning the last 30 ka highlights key periods of environmental change. Comparison of the records of fluvial and environmental change reveals the relationship is complex with no clear relationship between river aggradation/incision and wetter/drier conditions. The nature and timing of fluvial response in the wet tropics also shows broad similarities with coastal valleys in south-eastern New South Wales, suggesting continental-scale controls on fluvial response to changing climate during the Late Quaternary in Australia. Copyright © 2017 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2017

15. Two sides of a coin: Effects of climate change on the native and non-native distribution of Colossoma macropomum in South America.

Author

Lopes, Taise M., Bailly, Dayani, Almeida, Bia A., Santos, Natália C. L., Gimenez, Barbara C. G., Landgraf, Guilherme O., Sales, Paulo C. L., Lima-Ribeiro, Matheus S., Cassemiro, Fernanda A. S., Rangel, Thiago F., Diniz-Filho, José A. F., Agostinho, Angelo A., and Gomes, Luiz C.

Subjects

*CLIMATE change, *COLOSSOMA, *BIOTIC communities, *WATERSHEDS, *FISH farming

Abstract

Climate change and species invasions interact in nature, disrupting biological communities. Based on this knowledge, we simultaneously assessed the effects of climate change on the native distribution of the Amazonian fish Colossoma macropomum as well as on its invasiveness across river basins of South America, using ecological niche modeling. We used six niche models within the ensemble forecast context to predict the geographical distribution of C. macropomum for the present time, 2050 and 2080. Given that this species has been continuously introduced into non-native South American basins by fish farming activities, we added the locations of C. macropomum farms into the modeling process to obtain a more realistic scenario of its invasive potential. Based on modelling outputs we mapped climate refuge areas at different times. Our results showed that a plenty of climatically suitable areas for the occurrence of C. macropomum occurrence are located outside the original basins at the present time and that its invasive potential is greatly amplified by fish farms. Simulations of future geographic ranges revealed drastic range contraction in the native region, implying concerns not only with respect to the species conservation but also from a socio-economic perspective since the species is a cornerstone of artisanal and commercial fisheries in the Amazon. Although the invasive potential is projected to decrease in the face of climate change, climate refugia will concentrate in Paraná River, Southeast Atlantic and East Atlantic basins, putting intense, negative pressures on the native fish fauna these regions. Our findings show that short and long-term management actions are required for: i) the conservation of natural stocks of C. macropomum in the Amazon, and ii) protecting native fish fauna in the climate refuges of the invaded regions. [ABSTRACT FROM AUTHOR]

Published

2017

16. Aged dissolved organic carbon exported from rivers of the Tibetan Plateau.

Author

Qu, Bin, Sillanpää, Mika, Li, Chaoliu, Kang, Shichang, Stubbins, Aron, Yan, Fangping, Aho, Kelly Sue, Zhou, Feng, and Raymond, Peter A.

Subjects

*CARBON cycle, *CARBON isotopes, *CYCLING, *CARBON compounds

Abstract

The role played by river networks in regional and global carbon cycle is receiving increasing attention. Despite the potential of radiocarbon measurements (14C) to elucidate sources and cycling of different riverine carbon pools, there remain large regions such as the climate-sensitive Tibetan Plateau for which no data are available. Here we provide new 14C data on dissolved organic carbon (DOC) from three large Asian rivers (the Yellow, Yangtze and Yarlung Tsangpo Rivers) running on the Tibetan Plateau and present the carbon transportation pattern in rivers of the plateau versus other river system in the world. Despite higher discharge rates during the high flow season, the DOC yield of Tibetan Plateau rivers (0.41 gC m-2 yr-1) was lower than most other rivers due to lower concentrations. Radiocarbon ages of the DOC were older/more depleted (511±294 years before present, yr BP) in the Tibetan rivers than those in Arctic and tropical rivers. A positive correlation between radiocarbon age and permafrost watershed coverage was observed, indicating that 14C-deplted/old carbon is exported from permafrost regions of the Tibetan Plateau during periods of high flow. This is in sharp contrast to permafrost regions of the Arctic which export 14C-enriched carbon during high discharge periods. [ABSTRACT FROM AUTHOR]

Published

2017

17. Insight into runoff characteristics using hydrological modeling in the data-scarce southern Tibetan Plateau: Past, present, and future.

Author

Cai, Mingyong, Yang, Shengtian, Zhao, Changsen, Zhou, Qiuwen, and Hou, Lipeng

Subjects

*WATER supply, *WATERSHEDS, *RUNOFF, *EVAPOTRANSPIRATION, *COEFFICIENTS (Statistics)

Abstract

Regional hydrological modeling in ungauged regions has attracted growing attention in water resources research. The southern Tibetan Plateau often suffers from data scarcity in watershed hydrological simulation and water resources assessment. This hinders further research characterizing the water cycle and solving international water resource issues in the area. In this study, a multi-spatial data based Distributed Time-Variant Gain Model (MS-DTVGM) is applied to the Yarlung Zangbo River basin, an important international river basin in the southern Tibetan Plateau with limited meteorological data. This model is driven purely by spatial data from multiple sources and is independent of traditional meteorological data. Based on the methods presented in this study, daily snow cover and potential evapotranspiration data in the Yarlung Zangbo River basin in 2050 are obtained. Future (2050) climatic data (precipitation and air temperature) from the Fifth Assessment Report of the Intergovernmental Panel on Climate Change (IPCC-AR5) are used to study the hydrological response to climate change. The result shows that river runoff will increase due to precipitation and air temperature changes by 2050. Few differences are found between daily runoff simulations from different Representative Concentration Pathway (RCP) scenarios (RCP2.6, RCP4.5 and RCP8.5) for 2050. Historical station observations (1960–2000) at Nuxia and model simulations for two periods (2006–2009 and 2050) are combined to study inter-annual and intra-annual runoff distribution and variability. The inter-annual runoff variation is stable and the coefficient of variation (CV) varies from 0.21 to 0.27. In contrast, the intra-annual runoff varies significantly with runoff in summer and autumn accounting for more than 80% of the total amount. Compared to the historical period (1960–2000), the present period (2006–2009) has a slightly uneven intra-annual runoff temporal distribution, and becomes more balanced in the future (2050). [ABSTRACT FROM AUTHOR]

Published

2017

18. Multi-scale response of runoff to climate fluctuation in the headwater region of the Kaidu River in Xinjiang of China.

Author

Liu, Zuhan, Wang, Lili, Yu, Xiang, Wang, Shengqian, Deng, Chengzhi, Xu, Jianhua, Chen, Zhongsheng, and Bai, Ling

Subjects

*RUNOFF & the environment, *CLIMATE change, *RIVERS, *CLIMATOLOGY

Abstract

Based on the climatological-hydrological daily data recorded in the headwater region of the Kaidu River during 1972-2011, the multi-scale characteristics of runoff variability and four climatic factor fluctuations (i.e. temperature, precipitation, relative humidity and evaporation) are analyzed using detrended fluctuation analysis. Furthermore, multi-scale response of runoff to climate fluctuation is investigated using detrended cross-correlation analysis. Main findings are as follows: (1) The temporal scaling behaviors of runoff and four climate factor series all exhibit two different power laws. In shorter temporal scaling, all the series indicate the similar persistence corresponding to the annual cycle. However, in longer temporal scaling, their different trends reflect the different inherent dynamic nature of various hydro-climatic change. (2) In the double logarithm curve log F2( s) ∼ log s, the long-range correlation of runoff and temperature, long-range correlation of runoff and precipitation and long-range correlation of runoff and relative humidity (hereafter referred to as Lrc-R-T, Lrc-R-P and Lrc-R-H, respectively) show two scaling regimes with two different scale indexes and a critical time scale of about 1 year; the long-range correlation of runoff and evaporation (hereafter referred to as Lrc-R-E) presents three scaling regime with three different scale indexes and with two critical time scales of about 1 and 10 years. These results reflect the multi-scale response s of the runoff to climate change on different time scales. [ABSTRACT FROM AUTHOR]

Published

2017

19. Indirect effect of temperature on fish population abundances through phenological changes.

Author

Kuczynski, Lucie, Chevalier, Mathieu, Laffaille, Pascal, Legrand, Marion, and Grenouillet, Gaël

Subjects

*FISH populations, *CLIMATE change, *ECOLOGICAL carrying capacity, *PHENOLOGY, *BIOCLIMATOLOGY

Abstract

In response to climate change, earlier phenological events have been reported for a large range of taxa such that phenological shifts are considered as one of the fingerprints of the effect of climate change on organisms. Evidence further suggests that changes in the timing of phenological events might decouple biotic interactions due to differential phenological adjustment among interacting species, ultimately leading to population declines. Nonetheless, few studies have investigated how climate-driven changes in the timing of phenological events influence population abundances. In this study, we investigated how two environmental variables known to influence the migration timing of freshwater fish (i.e. water discharge and temperature) directly or indirectly influenced abundances of 21 fish species using daily time series gathered at four sites located in France over a period spanning from 9 to 21 years. We found no evidence for long-term trends in migration timing or fish abundances over time. Using piecewise structural equation models, we demonstrate that inter-annual variations in abundances were driven by inter-annual variations in temperature through variations in migration timing. Overall, our results suggest that climate change may concomitantly influence different biological aspects (e.g. phenology, abundance) of fish species. We argue that considering different responses to climate change is paramount if we are to improve our understanding of how organisms and populations are influenced by climate change in order to set-up efficient conservation strategies. [ABSTRACT FROM AUTHOR]

Published

2017

20. Palaeolake isolation and biogeographical process of freshwater fishes in the Yellow River.

Author

Kang, Bin, Huang, Xiaoxia, and Wu, Yunfei

Subjects

*BIOGEOGRAPHY, *GEOGRAPHICAL distribution of fishes, *ENDEMIC fishes, *CLIMATE change, FISH speciation

Abstract

The Yellow River, one of the very few in the Earth, originated from many dispersive palaeolakes. Taking this unique advantage, we examined the roles of palaeolake isolation vs. geological processes vs. climate in determining current fish biogeographic pattern. We reviewed available data on fish species and their geographical distribution in the river, as well as palaeolake development, geological and climatic parameters. The 138 fish species recorded in the river could be divided into 8 biogeographic regions, corresponding to the distribution of palaeolakes and respective endemic species. Through variation partitioning analysis, palaeolake isolation was the most influential factor explaining 43.6% of the total variance on the current fish distribution. The Quaternary Ice Age produced a transitional distribution for fishes from the glacier to warm water, especially for the subfamily Schizothoracinae, which showed various degrees of specialisation along altitudes. We suggested that fish biogeography in the Yellow river was basically shaped by palaeolake isolation, and further carved under serials of geologic events and contemporary climate change. [ABSTRACT FROM AUTHOR]

Published

2017

21. Development and validation of risk profiles of West African rural communities facing multiple natural hazards.

Author

Asare-Kyei, Daniel, Renaud, Fabrice G., Kloos, Julia, Walz, Yvonne, and Rhyner, Jakob

Subjects

*GEOLOGIC hot spots, *CLIMATE change, *RAINSTORMS, *GEOGRAPHIC information systems, *RURAL geography

Abstract

West Africa has been described as a hotspot of climate change. The reliance on rain-fed agriculture by over 65% of the population means that vulnerability to climatic hazards such as droughts, rainstorms and floods will continue. Yet, the vulnerability and risk levels faced by different rural social-ecological systems (SES) affected by multiple hazards are poorly understood. To fill this gap, this study quantifies risk and vulnerability of rural communities to drought and floods. Risk is assessed using an indicator-based approach. A stepwise methodology is followed that combines participatory approaches with statistical, remote sensing and Geographic Information System techniques to develop community level vulnerability indices in three watersheds (Dano, Burkina Faso; Dassari, Benin; Vea, Ghana). The results show varying levels of risk profiles across the three watersheds. Statistically significant high levels of mean risk in the Dano area of Burkina Faso are found whilst communities in the Dassari area of Benin show low mean risk. The high risk in the Dano area results from, among other factors, underlying high exposure to droughts and rainstorms, longer dry season duration, low caloric intake per capita, and poor local institutions. The study introduces the concept of community impact score (CIS) to validate the indicator-based risk and vulnerability modelling. The CIS measures the cumulative impact of the occurrence of multiple hazards over five years. 65.3% of the variance in observed impact of hazards/CIS was explained by the risk models and communities with high simulated disaster risk generally follow areas with high observed disaster impacts. Results from this study will help disaster managers to better understand disaster risk and develop appropriate, inclusive and well integrated mitigation and adaptation plans at the local level. It fulfills the increasing need to balance global/regional assessments with community level assessments where major decisions against risk are actually taken and implemented. [ABSTRACT FROM AUTHOR]

Published

2017

22. Predicting River Macroinvertebrate Communities Distributional Shifts under Future Global Change Scenarios in the Spanish Mediterranean Area.

Author

Alba-Tercedor, Javier, Sáinz-Bariáin, Marta, Poquet, José Manuel, and Rodríguez-López, Roberto

Subjects

*INVERTEBRATES, *COMMUNITIES, *ATMOSPHERIC temperature, *FRESHWATER ecology, *HYDRAULICS

Abstract

Several studies on global change over the next century predict increases in mean air temperatures of between 1°C to 5°C that would affect not only water temperature but also river flow. Climate is the predominant environmental driver of thermal and flow regimes of freshwater ecosystems, determining survival, growth, metabolism, phenology and behaviour as well as biotic interactions of aquatic fauna. Thus, these changes would also have consequences for species phenology, their distribution range, and the composition and dynamics of communities. These effects are expected to be especially severe in the Mediterranean basin due its particular climate conditions, seriously threatening Southern European ecosystems. In addition, species with restricted distributions and narrow ecological requirements, such as those living in the headwaters of rivers, will be severely affected. The study area corresponds to the Spanish Mediterranean and Balearic Islands, delimited by the Köppen climate boundary. With the application of the MEDPACS (MEDiterranean Prediction And Classification System) predictive approach, the macroinvertebrate community was predicted for current conditions and compared with three posible scenarios of watertemperature increase and its associated water flow reductions. The results indicate that the aquatic macroinvertebrate communities will undergo a drastic impact, with reductions in taxa richness for each scenario in relation to simulated current conditions, accompanied by changes in the taxa distribution pattern. Accordingly, the distribution area of most of the taxa (65.96%) inhabiting the mid-high elevations would contract and rise in altitude. Thus, families containing a great number of generalist species will move upstream to colonize new zones with lower water temperatures. By contrast, more vulnerable taxa will undergo reductions in their distribution area. [ABSTRACT FROM AUTHOR]

Published

2017

23. Linking Hydroclimate to Fish Phenology and Habitat Use with Ichthyographs.

Author

Flitcroft, Rebecca L., Lewis, Sarah L., Arismendi, Ivan, LovellFord, Rachel, Santelmann, Mary V., Safeeq, Mohammad, and Grant, Gordon

Subjects

*FISH habitats, *PHENOLOGY, *ICHTHYOLOGY, *WATER temperature, *AQUATIC organisms, FISH & climate

Abstract

Streamflow and water temperature (hydroclimate) influence the life histories of aquatic biota. The relationship between streamflow and temperature varies with climate, hydrogeomorphic setting, and season. Life histories of native fishes reflect, in part, their adaptation to regional hydroclimate (flow and water temperature), local habitats, and natural disturbance regimes, all of which may be affected by water management. Alterations to natural hydroclimates, such as those caused by river regulation or climate change, can modify the suitability and variety of in-stream habitat for fishes throughout the year. Here, we present the ichthyograph, a new empirically-based graphical tool to help visualize relationships between hydroclimate and fish phenology. Generally, this graphical tool can be used to display a variety of phenotypic traits. We used long-term data sets of daily fish passage to examine linkages between hydroclimate and the expression of life-history phenology by native fishes. The ichthyograph may be used to characterize the environmental phenology for fishes across multiple spatio-temporal domains. We illustrate the ichthyograph in two applications to visualize: 1) river use for the community of fishes at a specific location; and 2) stream conditions at multiple locations within the river network for one species at different life-history stages. The novel, yet simple, ichthyograph offers a flexible framework to enable transformations in thinking regarding relationships between hydroclimate and aquatic species across space and time. The potential broad application of this innovative tool promotes synergism between assessments of physical characteristics and the biological needs of aquatic species. [ABSTRACT FROM AUTHOR]

Published

2016

24. Climate Change Impacts on the Upper Indus Hydrology: Sources, Shifts and Extremes.

Author

Lutz, A. F., Immerzeel, W. W., Kraaijenbrink, P. D. A., Shrestha, A. B., and Bierkens, M. F. P.

Subjects

*CLIMATE change, *GENERAL circulation model, *DOWNSCALING (Climatology), *METEOROLOGICAL precipitation

Abstract

The Indus basin heavily depends on its upstream mountainous part for the downstream supply of water while downstream demands are high. Since downstream demands will likely continue to increase, accurate hydrological projections for the future supply are important. We use an ensemble of statistically downscaled CMIP5 General Circulation Model outputs for RCP4.5 and RCP8.5 to force a cryospheric-hydrological model and generate transient hydrological projections for the entire 21st century for the upper Indus basin. Three methodological advances are introduced: (i) A new precipitation dataset that corrects for the underestimation of high-altitude precipitation is used. (ii) The model is calibrated using data on river runoff, snow cover and geodetic glacier mass balance. (iii) An advanced statistical downscaling technique is used that accounts for changes in precipitation extremes. The analysis of the results focuses on changes in sources of runoff, seasonality and hydrological extremes. We conclude that the future of the upper Indus basin’s water availability is highly uncertain in the long run, mainly due to the large spread in the future precipitation projections. Despite large uncertainties in the future climate and long-term water availability, basin-wide patterns and trends of seasonal shifts in water availability are consistent across climate change scenarios. Most prominent is the attenuation of the annual hydrograph and shift from summer peak flow towards the other seasons for most ensemble members. In addition there are distinct spatial patterns in the response that relate to monsoon influence and the importance of meltwater. Analysis of future hydrological extremes reveals that increases in intensity and frequency of extreme discharges are very likely for most of the upper Indus basin and most ensemble members. [ABSTRACT FROM AUTHOR]

Published

2016

25. Projected Impact of Climate Change on Hydrological Regimes in the Philippines.

Author

Tolentino, Pamela Louise M., Poortinga, Ate, Kanamaru, Hideki, Keesstra, Saskia, Maroulis, Jerry, David, Carlos Primo C., and Ritsema, Coen J.

Subjects

*CLIMATE change, *HYDROLOGIC cycle, *WATER supply, *STREAMFLOW

Abstract

The Philippines is one of the most vulnerable countries in the world to the potential impacts of climate change. To fully understand these potential impacts, especially on future hydrological regimes and water resources (2010-2050), 24 river basins located in the major agricultural provinces throughout the Philippines were assessed. Calibrated using existing historical interpolated climate data, the STREAM model was used to assess future river flows derived from three global climate models (BCM2, CNCM3 and MPEH5) under two plausible scenarios (A1B and A2) and then compared with baseline scenarios (20th century). Results predict a general increase in water availability for most parts of the country. For the A1B scenario, CNCM3 and MPEH5 models predict an overall increase in river flows and river flow variability for most basins, with higher flow magnitudes and flow variability, while an increase in peak flow return periods is predicted for the middle and southern parts of the country during the wet season. However, in the north, the prognosis is for an increase in peak flow return periods for both wet and dry seasons. These findings suggest a general increase in water availability for agriculture, however, there is also the increased threat of flooding and enhanced soil erosion throughout the country. [ABSTRACT FROM AUTHOR]

Published

2016

26. Towards Wind Vector and Wave Height Retrievals Over Inland Waters Using CYGNSS

Author

Eric Loria, Cinzia Zuffada, Valery U. Zavorotny, and Andrew O'Brien

Subjects

Space Geodetic Surveys, Abrupt/Rapid Climate Change, Informatics, Astronomy, Surface Waves and Tides, Atmospheric Composition and Structure, Biogeosciences, Volcanic Effects, Wind speed, Volcano Monitoring, Remote Sensing, Global Change from Geodesy, Volcanic Hazards and Risks, Oceans, Sea Level Change, Surface roughness, River Channels, Disaster Risk Analysis and Assessment, Seismology, Climatology, QE1-996.5, Radio Oceanography, Climate and Interannual Variability, Remote Sensing and Disasters, Geology, Gravity and Isostasy, Marine Geology and Geophysics, Physical Modeling, Oceanography: General, Climate Impact, Earthquake Ground Motions and Engineering Seismology, Explosive Volcanism, Surface wave, Earth System Modeling, Atmospheric Processes, Cryosphere, Ocean Monitoring with Geodetic Techniques, Ocean/Atmosphere Interactions, Impacts of Global Change, Atmospheric, Regional Modeling, Oceanography: Physical, Research Article, Risk, Atmospheric Effects, Meteorology, Oceanic, Theoretical Modeling, Climate change, Volcanology, QB1-991, Environmental Science (miscellaneous), Hydrological Cycles and Budgets, Radio Science, Tsunamis and Storm Surges, Decadal Ocean Variability, Land/Atmosphere Interactions, Paleoceanography, Rivers, Wave height, Climate Dynamics, Remote Sensing of Volcanoes, Geodesy and Gravity, Global Change, Air/Sea Interactions, Numerical Modeling, Solid Earth, Numerical Solutions, Climate Change and Variability, Geological, Effusive Volcanism, Ocean/Earth/atmosphere/hydrosphere/cryosphere interactions, Climate Variability, Water Cycles, Modeling, Sediment, Riparian Systems, General Circulation, Policy Sciences, Avalanches, Climate Impacts, Volcano Seismology, Benefit‐cost Analysis, Mud Volcanism, Wind wave model, GNSS reflectometry, Air/Sea Constituent Fluxes, Mass Balance, Ocean influence of Earth rotation, Volcano/Climate Interactions, General Earth and Planetary Sciences, Environmental science, Computational Geophysics, Regional Climate Change, Hydrology, Sea Level: Variations and Mean, Natural Hazards

Abstract

GNSS Reflectometry (GNSS‐R) measurements over inland water bodies, such as lakes, rivers, and wetlands exhibit strong coherent signals. The strength of the coherent reflections is highly sensitive to small‐scale surface roughness. For inland waters, this roughness is primarily due to wind‐driven surface waves. The sensitivity of the coherent reflections to surface roughness can be leveraged to estimate wave height profiles across inland waters. Coupled with a wind wave model, an approach to retrieve a wind vector is described using a forward model, which is potentially able to predict scattered power profiles for different wind speeds and directions and choosing the minimum‐squared error solution. The ability for spaceborne or airborne GNSS‐R to measure an inland water wind vector and wave heights could contribute to scientific applications focused on understanding nearshore ecosystems, monitoring climate change effects on inland waters, sediment resuspension, biomass production, fish habitat, and others. This paper presents a novel approach to potentially retrieve wind vector and wave heights over inland waters using GNSS‐R and discusses the issues with performing such retrievals using simulation and very few available raw signals recorded from CYGNSS satellites., Key Points Global Navigation Satellite Systems (GNSS) signals reflected from inland waters exhibit coherent scattering properties that make them highly sensitive to water surface roughnessWind‐induced roughness will vary across a water body, with a strong dependence on wind speed, wind direction, and the water depthDiscuss potentials of a novel model‐based approach for retrieval a of wind vector and surface wave heights over lakes using CYGNSS data

Published

2021

27. Hydropower's Biogenic Carbon Footprint.

Author

Scherer, Laura and Pfister, Stephan

Subjects

*GLOBAL warming & the environment, *RENEWABLE energy sources, *WATER power, *CLIMATE change, *ENVIRONMENTAL engineering, *OCEAN thermal power plants

Abstract

Global warming is accelerating and the world urgently needs a shift to clean and renewable energy. Hydropower is currently the largest renewable source of electricity, but its contribution to climate change mitigation is not yet fully understood. Hydroelectric reservoirs are a source of biogenic greenhouse gases and in individual cases can reach the same emission rates as thermal power plants. Little is known about the severity of their emissions at the global scale. Here we show that the carbon footprint of hydropower is far higher than previously assumed, with a global average of 173 kg CO2 and 2.95 kg CH4 emitted per MWh of electricity produced. This results in a combined average carbon footprint of 273 kg CO2e/MWh when using the global warming potential over a time horizon of 100 years (GWP100). Nonetheless, this is still below that of fossil energy sources without the use of carbon capture and sequestration technologies. We identified the dams most promising for capturing methane for use as alternative energy source. The spread among the ~1500 hydropower plants analysed in this study is large and highlights the importance of case-by-case examinations. [ABSTRACT FROM AUTHOR]

Published

2016

28. Impacts of Dams and Global Warming on Fish Biodiversity in the Indo-Burma Hotspot.

Author

Kano, Yuichi, Dudgeon, David, Nam, So, Samejima, Hiromitsu, Watanabe, Katsutoshi, Grudpan, Chaiwut, Grudpan, Jarungjit, Magtoon, Wichan, Musikasinthorn, Prachya, Nguyen, Phuong Thanh, Praxaysonbath, Bounthob, Sato, Tomoyuki, Shibukawa, Koichi, Shimatani, Yukihiro, Suvarnaraksha, Apinun, Tanaka, Wataru, Thach, Phanara, Tran, Dac Dinh, Yamashita, Tomomi, and Utsugi, Kenzo

Subjects

*FISH diversity, *FISH ecology, *GLOBAL warming & the environment, *GEOLOGIC hot spots, *FOSSIL fuels, *WATER power

Abstract

Both hydropower dams and global warming pose threats to freshwater fish diversity. While the extent of global warming may be reduced by a shift towards energy generation by large dams in order to reduce fossil-fuel use, such dams profoundly modify riverine habitats. Furthermore, the threats posed by dams and global warming will interact: for example, dams constrain range adjustments by fishes that might compensate for warming temperatures. Evaluation of their combined or synergistic effects is thus essential for adequate assessment of the consequences of planned water-resource developments. We made projections of the responses of 363 fish species within the Indo-Burma global biodiversity hotspot to the separate and joint impacts of dams and global warming. The hotspot encompasses the Lower Mekong Basin, which is the world’s largest freshwater capture fishery. Projections for 81 dam-building scenarios revealed progressive impacts upon projected species richness, habitable area, and the proportion of threatened species as generating capacity increased. Projections from 126 global-warming scenarios included a rise in species richness, a reduction in habitable area, and an increase in the proportion of threatened species; however, there was substantial variation in the extent of these changes among warming projections. Projections from scenarios that combined the effects of dams and global warming were derived either by simply adding the two threats, or by combining them in a synergistic manner that took account of the likelihood that habitat shifts under global warming would be constrained by river fragmentation. Impacts on fish diversity under the synergistic projections were 10–20% higher than those attributable to additive scenarios, and were exacerbated as generating capacity increased—particularly if CO2 emissions remained high. The impacts of dams, especially those on river mainstreams, are likely to be greater, more predictable and more immediately pressing for fishes than the consequences of global warming. Limits upon dam construction should therefore be a priority action for conserving fish biodiversity in the Indo-Burma hotspot. This would minimize synergistic impacts attributable to dams plus global warming, and help ensure the continued provision of ecosystem services represented by the Lower Mekong fishery. [ABSTRACT FROM AUTHOR]

Published

2016

29. Variations of Runoff and Sediment Load in the Middle and Lower Reaches of the Yangtze River, China (1950-2013).

Author

Li, Na, Wang, Lachun, Zeng, Chunfen, Wang, Dong, Liu, Dengfeng, and Wu, Xutong

Subjects

*SEDIMENTS, *RUNOFF, *HYDROLOGICAL stations, *ABRUPT climate change, *SUSTAINABLE development

Abstract

On the basis of monthly runoff series obtained in 1950–2013 and annual sediment load measured in 1956–-2013 at five key hydrological stations in the middle and lower reaches of the Yangtze River basin, this study used the Mann-Kendall methods to identify trend and abrupt changes of runoff and sediment load in relation to human activities. The results were as follows: (1) The annual and flood season runoffs showed significant decreasing trends at Yichang station, and showed slight downward trends at Hankou and Datong stations, while the abrupt changes of dry season runoff at Yichang, Hankou and Datong stations occurred in about 2007 and the change points were followed by significant increasing trends. The construction of the Three Gorges Dam, which began to operate in 2003, influenced the variations of runoff in the mainstream of Yangtze River, but the effect weakened with the distance along the downstream direction from TGD. (2) Since the 1990s, annual sediment loads at Yichang, Hankou, and Datong stations have been decreasing significantly, and after 2002, the annual sediment load at Yichang dropped below that of Hankou and Datong. The dams and deforestation/forestation contributed to the significant decreasing trend of the sediment load. In addition, the Three Gorges Dam aggravated the downward trend and caused the erosion of the riverbed and riverbanks in the middle and lower reaches. (3) The runoff and sediment load flowing from Dongting Lake into the mainstream of the Yangtze River showed significant decreasing trends at Chenglingji station after 1970s, and in contrast, slight increase in the sediment flow from Poyang Lake to the mainstream of the Yangtze River at Hukou station were detected over the post-TGD period (2003–2013). The result of the study will be an important foundation for watershed sustainable development of the Yangtze River under the human activities. [ABSTRACT FROM AUTHOR]

Published

2016

30. Can Recent Global Changes Explain the Dramatic Range Contraction of an Endangered Semi-Aquatic Mammal Species in the French Pyrenees?

Author

Charbonnel, Anaïs, Laffaille, Pascal, Biffi, Marjorie, Blanc, Frédéric, Maire, Anthony, Némoz, Mélanie, Sanchez-Perez, José Miguel, Sauvage, Sabine, and Buisson, Laëtitia

Subjects

*GLOBAL environmental change, *FRESHWATER ecology, *AQUATIC mammals, *HYDROGRAPHIC surveying, *PYRENEAN desman

Abstract

Species distribution models (SDMs) are the main tool to predict global change impacts on species ranges. Climate change alone is frequently considered, but in freshwater ecosystems, hydrology is a key driver of the ecology of aquatic species. At large scale, hydrology is however rarely accounted for, owing to the lack of detailed stream flow data. In this study, we developed an integrated modelling approach to simulate stream flow using the hydrological Soil and Water Assessment Tool (SWAT). Simulated stream flow was subsequently included as an input variable in SDMs along with topographic, hydrographic, climatic and land-cover descriptors. SDMs were applied to two temporally-distinct surveys of the distribution of the endangered Pyrenean desman (Galemys pyrenaicus) in the French Pyrenees: a historical one conducted from 1985 to 1992 and a current one carried out between 2011 and 2013. The model calibrated on historical data was also forecasted onto the current period to assess its ability to describe the distributional change of the Pyrenean desman that has been modelled in the recent years. First, we found that hydrological and climatic variables were the ones influencing the most the distribution of this species for both periods, emphasizing the importance of taking into account hydrology when SDMs are applied to aquatic species. Secondly, our results highlighted a strong range contraction of the Pyrenean desman in the French Pyrenees over the last 25 years. Given that this range contraction was under-estimated when the historical model was forecasted onto current conditions, this finding suggests that other drivers may be interacting with climate, hydrology and land-use changes. Our results imply major concerns for the conservation of this endemic semi-aquatic mammal since changes in climate and hydrology are expected to become more intense in the future. [ABSTRACT FROM AUTHOR]

Published

2016

31. Indian Summer Monsoon Rainfall: Implications of Contrasting Trends in the Spatial Variability of Means and Extremes.

Author

Ghosh, Subimal, Vittal, H., Sharma, Tarul, Karmakar, Subhankar, Kasiviswanathan, K. S., Dhanesh, Y., Sudheer, K. P., and Gunthe, S. S.

Subjects

*RAINFALL, *MONSOONS, *SPATIAL variation, *HYDROLOGY, *WATERSHEDS

Abstract

India’s agricultural output, economy, and societal well-being are strappingly dependent on the stability of summer monsoon rainfall, its variability and extremes. Spatial aggregate of intensity and frequency of extreme rainfall events over Central India are significantly increasing, while at local scale they are spatially non-uniform with increasing spatial variability. The reasons behind such increase in spatial variability of extremes are poorly understood and the trends in mean monsoon rainfall have been greatly overlooked. Here, by using multi-decadal gridded daily rainfall data over entire India, we show that the trend in spatial variability of mean monsoon rainfall is decreasing as exactly opposite to that of extremes. The spatial variability of extremes is attributed to the spatial variability of the convective rainfall component. Contrarily, the decrease in spatial variability of the mean rainfall over India poses a pertinent research question on the applicability of large scale inter-basin water transfer by river inter-linking to address the spatial variability of available water in India. We found a significant decrease in the monsoon rainfall over major water surplus river basins in India. Hydrological simulations using a Variable Infiltration Capacity (VIC) model also revealed that the water yield in surplus river basins is decreasing but it is increasing in deficit basins. These findings contradict the traditional notion of dry areas becoming drier and wet areas becoming wetter in response to climate change in India. This result also calls for a re-evaluation of planning for river inter-linking to supply water from surplus to deficit river basins. [ABSTRACT FROM AUTHOR]

Published

2016

32. Multispecies Fisheries in the Lower Amazon River and Its Relationship with the Regional and Global Climate Variability.

Author

Pinaya, Walter Hugo Diaz, Lobon-Cervia, Francisco Javier, Pita, Pablo, Buss de Souza, Ronald, Freire, Juan, and Isaac, Victoria Judith

Subjects

*FISHERIES, *CLIMATE change, *FISHERY resources, *MULTIPLE regression analysis

Abstract

This paper aims to describe the spatial-temporal variability in catch of the main fishery resources of the Amazon River and floodplain lakes of the Lower Amazon, as well as relating the Catch per Unit of Effort with anomalies of some of the Amazon River, atmosphere and Atlantic Ocean system variables, determining the influence of the environment on the Amazonian fishery resources. Finfish landings data from the towns and villages of the Lower Amazon for the fisheries of three sites (Óbidos, Santarém and Monte Alegre), were obtained for the period between January 1993 and December 2004. Analysis of variance, detrended correspondence analysis, redundancy analysis and multiple regression techniques were used for the statistical analysis of the distinct time series. Fisheries production in the Lower Amazon presents differences between the Amazon River and the floodplain lakes. Production in the Amazon River is approximately half of the one of the floodplain lakes. This variability occurs both along the Lower Amazon River region (longitudinal gradient) and laterally (latitudinal gradient) for every fishing ground studied here. The distinct environmental variables alone or in association act differently on the fishery stocks and the success of catches in each fishery group studied here. Important variables are the flooding events; the soil the sea surface temperatures; the humidity; the wind and the occurence of El Niño-Southern Oscillation events. Fishery productivity presents a large difference in quantity and distribution patterns between the river and floodplain lakes. This variability occurs in the region of the Lower Amazon as well as laterally for each fishery group studied, being dependent on the ecological characteristics and life strategies of each fish group considered here. [ABSTRACT FROM AUTHOR]

Published

2016

33. Tropical Peat and Peatland Development in the Floodplains of the Greater Pamba Basin, South-Western India during the Holocene.

Author

Kumaran, Navnith K. P., Padmalal, Damodaran, Limaye, Ruta B., S., Vishnu Mohan, Jennerjahn, Tim, and Gamre, Pradeep G.

Subjects

*PEATLANDS, *HOLOCENE Epoch, *FLOODPLAINS, *FOREST ecology, *CLIMATE change

Abstract

Holocene sequences in the humid tropical region of Kerala, South-western (SW) India have preserved abundance of organic—rich sediments in the form of peat and its rapid development in a narrow time frame towards Middle Holocene has been found to be significant. The sub—coastal areas and flood plains of the Greater Pamba Basin have provided palaeorecords of peat indicating that the deposits are essentially formed within freshwater. The combination of factors like stabilized sea level and its subsequent fall since the Middle Holocene, topographic relief and climatic conditions led to rapid peat accumulation across the coastal lowlands. The high rainfall and massive floods coupled with a rising sea level must have inundated > 75% of the coastal plain land converting it into a veritable lagoon—lake system that eventually led to abrupt termination of the forest ecosystem and also converted the floodplains into peatland where accumulation of peat almost to 2.0–3.0 m thickness in coastal lowlands and river basins during the shorter interval in the Middle Holocene. Vast areas of the coastal plains of Kerala have been converted into carbon rich peatland during the Middle Holocene and transforming the entire coastal stretch and associated landforms as one of the relatively youngest peatlands in the extreme southern tip of India. Unlike the uninterrupted formation of peatlands of considerable extent during the Holocene in Southeast Asia, the south Peninsular Indian region has restricted and short intervals of peatlands in the floodplains and coastal lowlands. Such a scenario is attributed to the topographic relief of the terrain and the prevailing hydrological regimes and environmental conditions as a consequence of monsoon variability since Middle Holocene in SW India. Considering the tropical coastal lowlands and associated peatlands are excellent repositories of carbon, they are very important for regional carbon cycling and habitat diversity. The alarming rate of land modification and development is destabilizing these carbon pools resulting in large scale carbon emissions to the atmosphere and loss of low-latitude peat palaeorecords. Therefore, these palaeorecords are to be conserved and addressed for better understanding and utilizing the carbon pool for effective climate change adaptation. This communication is the first attempt of addressing the peat formation and peatland development during the Holocene from the tropical region of Peninsular India. [ABSTRACT FROM AUTHOR]

Published

2016

34. Modelling Hydrologic Processes in the Mekong River Basin Using a Distributed Model Driven by Satellite Precipitation and Rain Gauge Observations.

Author

Wang, Wei, Lu, Hui, Yang, Dawen, Sothea, Khem, Jiao, Yang, Gao, Bin, Peng, Xueting, and Pang, Zhiguo

Subjects

*RAIN gauges, *HYDROLOGY, *ECONOMIC development, *CLIMATE change, *GEOMORPHOLOGY

Abstract

The Mekong River is the most important river in Southeast Asia. It has increasingly suffered from water-related problems due to economic development, population growth and climate change in the surrounding areas. In this study, we built a distributed Geomorphology-Based Hydrological Model (GBHM) of the Mekong River using remote sensing data and other publicly available data. Two numerical experiments were conducted using different rainfall data sets as model inputs. The data sets included rain gauge data from the Mekong River Commission (MRC) and remote sensing rainfall data from the Tropic Rainfall Measurement Mission (TRMM 3B42V7). Model calibration and validation were conducted for the two rainfall data sets. Compared to the observed discharge, both the gauge simulation and TRMM simulation performed well during the calibration period (1998–2001). However, the performance of the gauge simulation was worse than that of the TRMM simulation during the validation period (2002–2012). The TRMM simulation is more stable and reliable at different scales. Moreover, the calibration period was changed to 2, 4, and 8 years to test the impact of the calibration period length on the two simulations. The results suggest that longer calibration periods improved the GBHM performance during validation periods. In addition, the TRMM simulation is more stable and less sensitive to the calibration period length than is the gauge simulation. Further analysis reveals that the uneven distribution of rain gauges makes the input rainfall data less representative and more heterogeneous, worsening the simulation performance. Our results indicate that remotely sensed rainfall data may be more suitable for driving distributed hydrologic models, especially in basins with poor data quality or limited gauge availability. [ABSTRACT FROM AUTHOR]

Published

2016

35. Understanding Perceptions of Climate Change, Priorities, and Decision-Making among Municipalities in Lima, Peru to Better Inform Adaptation and Mitigation Planning.

Author

Siña, Mariella, Wood, Rachel C., Saldarriaga, Enrique, Lawler, Joshua, Zunt, Joseph, Garcia, Patricia, and Cárcamo, César

Subjects

*CLIMATE change & health, *SENSORY perception, *MUNICIPAL government, *DECISION making, *EMERGENCY management

Abstract

Climate change poses multiple risks to the population of Lima, the largest city and capital of Peru, located on the Pacific coast in a desert ecosystem. These risks include increased water scarcity, increased heat, and the introduction and emergence of vector-borne and other climate sensitive diseases. To respond to these threats, it is necessary for the government, at every level, to adopt more mitigation and adaptation strategies. Here, focus groups were conducted with representatives from five Lima municipalities to determine priorities, perception of climate change, and decision-making processes for implementing projects within each municipality. These factors can affect the ability and desire of a community to implement climate change adaptation and mitigation strategies. The results show that climate change and other environmental factors are of relatively low priority, whereas public safety and water and sanitation services are of highest concern. Perhaps most importantly, climate change is not well understood among the municipalities. Participants had trouble distinguishing climate change from other environmental issues and did not fully understand its causes and effects. Greater understanding of what climate change is and why it is important is necessary for it to become a priority for the municipalities. Different aspects of increased climate change awareness seem to be connected to having experienced extreme weather events, whether related or not to climate change, and to higher socioeconomic status. [ABSTRACT FROM AUTHOR]

Published

2016

36. Evaluation and Future Projection of Extreme Climate Events in the Yellow River Basin and Yangtze River Basin in China Using Ensembled CMIP5 Models Data

Author

Zigeng Niu, Lan Feng, Xiuping Yi, and Xinxin Chen

Subjects

China, 010504 meteorology & atmospheric sciences, Climate Change, Health, Toxicology and Mutagenesis, 0208 environmental biotechnology, Drainage basin, Climate change, 02 engineering and technology, Structural basin, Spatial distribution, 01 natural sciences, Article, extreme climate events, Rivers, CMIP5, Precipitation, 0105 earth and related environmental sciences, Projections, geography, Coupled model intercomparison project, geography.geographical_feature_category, Plateau, Public Health, Environmental and Occupational Health, Reproducibility of Results, Radiative forcing, Yellow River Basin, 020801 environmental engineering, Yangtze River Basin, Climatology, Environmental science, Medicine, Forecasting

Abstract

The Yellow River Basin (YLRB) and Yangtze River Basin (YZRB) are heavily populated, important grain-producing areas in China, and they are sensitive to climate change. In order to study the temporal and spatial distribution of extreme climate events in the two river basins, seven extreme temperature indices and seven extreme precipitation indices were projected for the periods of 2010–2039, 2040–2069, and 2070–2099 using data from 16 Coupled Model Intercomparison Project Phase 5 (CMIP5) models, and the delta change and reliability ensemble averaging (REA) methods were applied to obtain more robust ensemble values. First, the present evaluation indicated that the simulations satisfactorily reproduced the spatial distribution of temperature extremes, and the spatial distribution of precipitation extremes was generally suitably captured. Next, the REA values were adopted to conduct projections under different representative concentration pathway (RCP) scenarios (i.e., RCP4.5, and RCP8.5) in the 21st century. Warming extremes were projected to increase while cold events were projected to decrease, particularly on the eastern Tibetan Plateau, the Loess Plateau, and the lower reaches of the YZRB. In addition, the number of wet days (CWD) was projected to decrease in most regions of the two basins, but the highest five-day precipitation (Rx5day) and precipitation intensity (SDII) index values were projected to increase in the YZRB. The number of consecutive dry days (CDD) was projected to decrease in the northern and western regions of the two basins. Specifically, the warming trends in the two basins were correlated with altitude and atmospheric circulation patterns, and the wetting trends were related to the atmospheric water vapor content increases in summer and the strength of external radiative forcing. Notably, the magnitude of the changes in the extreme climate events was projected to increase with increasing warming targets, especially under the RCP8.5 scenario.

Published

2021

37. Trends in vegetation productivity related to climate change in China’s Pearl River Delta

Author

Man Sing Wong, Sawaid Abbas, and Janet Elizabeth Nichol

Subjects

Crops, Agricultural, Atmospheric Science, China, Asia, 010504 meteorology & atmospheric sciences, Science, Rain, Climate Change, 0211 other engineering and technologies, Biodiversity, Climate change, Growing season, Crops, 02 engineering and technology, Forests, 01 natural sciences, Normalized Difference Vegetation Index, Ecosystems, Geographical Locations, Meteorology, Rivers, Forest ecology, Ecosystem, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Climatology, Multidisciplinary, Ecology, Ecology and Environmental Sciences, Winter, Biology and Life Sciences, Agriculture, Vegetation, Plants, Terrestrial Environments, Productivity (ecology), People and Places, Earth Sciences, Environmental science, Medicine, Physical geography, Seasons, Climate change in China, Research Article, Crop Science, Environmental Monitoring

Abstract

Climate change will be a powerful stressor on ecosystems and biodiversity in the second half of the 21st century. In this study, we used the satellite-derived Normalized Difference Vegetation Index (NDVI) to examine a 34-year trend along with the response of vegetation to climate indicators surrounding the world’s largest megacity: the Pearl River Delta (PRD) of China. An overall increasing trend is observed in vegetation productivity metrics over the study period 1982 to 2015. Increase in winter productivity in both natural ecosystems and croplands is more related to increasing temperatures (r = 0.5–0.78), than to changes in rainfall. For growing season productivity, negative correlations with temperature were observed in cropland regions, and some forests in the northern part of PRD region, suggesting high-temperature stress on crop production and forest vegetation. However, increased winter and spring temperatures provide higher opportunities for cropping in winter. During the decade 1995–2004, vegetation productivity metrics showed a reversal in the upward trend. The geographical and biological complexity of the region under significant climatic and development impacts suggests causative factors would be synergistic. These include our observed decrease in sunshine hours, increasing cloud cover associated with atmospheric aerosols from industrial and urban development, direct pollution effects on plant growth, and exceedance of high temperature growth thresholds.

Published

2021

38. How did the characteristics of the growing season change during the past 100 years at a steep river basin in Japan?

Author

Taku M. Saitoh, Nagai Shin, and Kenlo Nishida Nasahara

Subjects

0106 biological sciences, Leaves, Atmospheric Science, 010504 meteorology & atmospheric sciences, Drainage basin, Marine and Aquatic Sciences, Plant Science, Forests, 01 natural sciences, Trees, Geographical Locations, Japan, Climatology, Multidisciplinary, geography.geographical_feature_category, Ecology, Phenology, Plant Anatomy, Eukaryota, Plants, Cameras, Terrestrial Environments, Optical Equipment, Engineering and Technology, Medicine, Seasons, Research Article, Freshwater Environments, Asia, Climate Change, Science, Growing season, Climate change, Plant Development, Equipment, Structural basin, 010603 evolutionary biology, Models, Biological, Ecosystems, Latitude, Rivers, Effects of global warming, Autumn, 0105 earth and related environmental sciences, geography, Ecology and Environmental Sciences, Elevation, Organisms, Biology and Life Sciences, Aquatic Environments, Bodies of Water, Plant Leaves, People and Places, Earth Sciences, Environmental science, Physical geography

Abstract

The effects of climate change on plant phenological events such as flowering, leaf flush, and leaf fall may be greater in steep river basins than at the horizontal scale of countries and continents. This possibility is due to the effect of temperature on plant phenology and the difference between vertical and horizontal gradients in temperature sensitivities. We calculated the dates of the start (SGS) and end of the growing season (EGS) in a steep river basin located in a mountainous region of central Japan over a century timescale by using a degree-day phenological model based on long-term, continuous, in situ observations. We assessed the generality and representativeness of the modelled SGS and EGS dates by using phenological events, live camera images taken at multiple points in the basin, and satellite observations made at a fine spatial resolution. The sensitivity of the modelled SGS and EGS dates to elevation changed from 3.29 days (100 m)−1 (−5.48 days °C−1) and −2.89 days (100 m)−1 (4.81 days °C−1), respectively, in 1900 to 2.85 days (100 m)−1 (−4.75 days °C−1) and −2.84 day (100 m)−1 (4.73 day °C−1) in 2019. The long-term trend of the sensitivity of the modelled SGS date to elevation was −0.0037 day year−1 per 100 m, but the analogous trend in the case of the modelled EGS date was not significant. Despite the need for further studies to improve the generality and representativeness of the model, the development of degree-day phenology models in multiple, steep river basins will deepen our ecological understanding of the sensitivity of plant phenology to climate change.

Published

2021

39. New records and modelling the impacts of climate change on the black-tailed marmosets

Author

Odair Diogo da Silva, Jôine Cariele Evangelista-Vale, João Carlos Pires-Oliveira, Adrian Barnett, and Almério Câmara Gusmão

Subjects

Atmospheric Science, Marine and Aquatic Sciences, Forests, Geographical locations, Forest restoration, Mathematical and Statistical Techniques, Conservation Science, Climatology, Mammals, education.field_of_study, Principal Component Analysis, Multidisciplinary, Ecology, Agroforestry, Statistics, Eukaryota, Biodiversity, Habitat, Physical Sciences, Vertebrates, Medicine, Brazil, Research Article, Freshwater Environments, Primates, Conservation of Natural Resources, Climate Change, Science, Population, Climate change, Research and Analysis Methods, Rivers, Deforestation, Animals, Statistical Methods, education, Ecosystem, Ecology and Environmental Sciences, Organisms, Biology and Life Sciences, Aquatic Environments, Models, Theoretical, South America, Bodies of Water, Environmental niche modelling, Callitrichinae, Multivariate Analysis, Amniotes, Earth Sciences, Anthropogenic Climate Change, People and places, Protected area, Animal Distribution, Zoology, Mathematics, Global biodiversity

Abstract

Climate change represents an unprecedented threat to global biodiversity and, for many species, gaps in our knowledge of their biology remain acute. Gaps in baseline knowledge, such as confirmed identifications (Linnean shortfalls) and adequate collections (Wallacean shortfalls), need to be minimized with new studies, since this is often critical for effective conservation. Despite the increase in scientific research on primates in the southwest of the Brazilian Amazon, little is known about the species Mico nigriceps (Ferrari & Lopes, 1992) Primates, Platirryni. In the current study, we sought to reduce the extent of the Wallacean shortfall for M. nigriceps, understand whether climate change represents a threat to the distribution of the species, and identify priority areas for its conservation. Accordingly, we provide 121 new records in 14 locations, obtained directly from the field, and five from the literature. Using this, we carried out ecological niche modeling, to better understand how environmental suitability might limit the area occupied by the species. We then projected a distribution for 2070 with the SSP2-4.5 (more optimistic) and SSP5-8.5 (more pessimistic) scenarios. Our data confirmed the geographic distribution of the species as being restricted to headwaters of the Ji-Paraná/Machado river, but with a 400 km extension to the south. Under the modeled climate change scenarios, the area suitable for the species declines by 21% under the most optimistic, and by 27% in the pessimistic, scenario across the projected 50-year period. Although we have expanded the area of known occurrence for this species, we point out that climate change threatens the stability of this newly-discovered population strongly, and that this danger is intensified by deforestation, fire and hunting. We recommend that further studies be carried out to confirm the presence of the species in adjacent areas, those indicated by generated models as being potential environmentally suitable. In addition, we recommend intensifying forest restoration in currently pastured areas, and protection of the areas forming the current and future habitat of this species through such measures as protected area creation.

Published

2021

40. The gap of water supply-Demand and its driving factors: From water footprint view in Huaihe River Basin

Author

Hailin Wu, Min An, Xiao Wang, Lijuan Fan, Jin Huang, Wenjing Yang, and Ribesh Khanal

Subjects

Atmospheric Science, Economics, Economic Models, Drainage basin, Water supply, Social Sciences, Marine and Aquatic Sciences, Fresh Water, Natural Resources, Climatology, Multidisciplinary, geography.geographical_feature_category, Ecology, Pollution, Carrying Capacity, Water Resources, Medicine, Economic Development, Algorithms, Research Article, Freshwater Environments, China, Conservation of Natural Resources, Ecological Metrics, Climate Change, Science, Water scarcity, Development Economics, Rivers, Population Metrics, Water Supply, Surface Water, Supply and Demand, Carrying capacity, Ecosystem, Driving factors, geography, Ecological footprint, Conservation of Water Resources, Population Biology, business.industry, Urbanization, Water Pollution, Ecology and Environmental Sciences, Aquatic Environments, Biology and Life Sciences, Models, Theoretical, Water resources, Earth Sciences, Environmental science, Anthropogenic Climate Change, Hydrology, business, Water resource management, Water use

Abstract

Climate change, population growth, the development of industrialization and urbanization are increasing the demand for water resources, but the water pollution is reducing the limited water supply. In recent years, the gap between water supply and demand which shows water scarcity situation is becoming more serious. Clear knowing this gap and its main driving factors could help us to put forward water protection measures correctly. We take the data of Huaihe River Basin from 2001 to 2016 as an example and use ecological water footprint to describe the demand, with the water carrying capacity representing the supply. We analyze the water supply-demand situation of Huaihe River Basin and its five provinces from footprint view in time and space. Then we apply the Logarithmic Mean Divisia Index model to analyze the driving factors of the ecological water footprint. The results show that: (1) the supply and demand balance of Huaihe River Basin was only achieved in year 2003 and 2005. There is also a large difference between Jiangsu province and other provinces in Huaihe River basin, most years in Jiangsu province per capital ecological footprint of water is more than 1 hm2/person except the years of 2003, 2015, and 2016. But other provinces are all less than 1 hm2/person. (2) Through the decomposition of water demand drivers, we concluded that economic development is the most important factor, with an annual contribution of more than 60%. Our study provides countermeasures and suggestions for the management and optimal allocation of water resources in Huaihe River Basin, and also provides reference for the formulation of water-saving policies in the world.

Published

2021

41. Climate Change Simulations Predict Altered Biotic Response in a Thermally Heterogeneous Stream System.

Author

Westhoff, Jacob T. and Paukert, Craig P.

Subjects

*CLIMATE change, *LOTIC ecology, *WATER temperature, *GROUNDWATER, *SOIL mapping

Abstract

Climate change is predicted to increase water temperatures in many lotic systems, but little is known about how changes in air temperature affect lotic systems heavily influenced by groundwater. Our objectives were to document spatial variation in temperature for spring-fed Ozark streams in Southern Missouri USA, create a spatially explicit model of mean daily water temperature, and use downscaled climate models to predict the number of days meeting suitable stream temperature for three aquatic species of concern to conservation and management. Longitudinal temperature transects and stationary temperature loggers were used in the Current and Jacks Fork Rivers during 2012 to determine spatial and temporal variability of water temperature. Groundwater spring influence affected river water temperatures in both winter and summer, but springs that contributed less than 5% of the main stem discharge did not affect river temperatures beyond a few hundred meters downstream. A multiple regression model using variables related to season, mean daily air temperature, and a spatial influence factor (metric to account for groundwater influence) was a strong predictor of mean daily water temperature (r2 = 0.98; RMSE = 0.82). Data from two downscaled climate simulations under the A2 emissions scenario were used to predict daily water temperatures for time steps of 1995, 2040, 2060, and 2080. By 2080, peak numbers of optimal growth temperature days for smallmouth bass are expected to shift to areas with more spring influence, largemouth bass are expected to experience more optimal growth days (21 – 317% increase) regardless of spring influence, and Ozark hellbenders may experience a reduction in the number of optimal growth days in areas with the highest spring influence. Our results provide a framework for assessing fine-scale (10 s m) thermal heterogeneity and predict shifts in thermal conditions at the watershed and reach scale. [ABSTRACT FROM AUTHOR]

Published

2014

42. ROCK SNOT AND LAKE MUD: EXPLORING THE HISTORY OF RECENT BLOOMS OF DIDYMOSPHENIA GEMINATA USING INFORMATION CONTAINED IN LAKE SEDIMENTS.

Author

Lavery, J. M., Kurek, J., Rühland, K. M., Gillis, Carole-Anne, Pisaric, Michael F. J., and Smol, J. P.

Subjects

MUD, DIATOMS, NATURE, SEDIMENTS, CLIMATOLOGY

Abstract

Ecosystem managers have often considered the nuisance diatom species, Didymosphenia geminata (didymo) as being introduced to the natural environment through human activities; however, observations from early 20th-century surveys challenge this characterization. We use diatoms preserved in lake sediment cores to investigate the history of didymo blooms from Gaspésie, Quebec. Relative abundances of diatoms were examined from the dated sediments of Lac Humqui and Lac au Saumon (a lake with an inflowing river currently supporting blooms). Didymo was observed throughout the Lac au Saumon core, demonstrating that it has been present in the region well before the first reports of blooms in 2006. Lac Humqui diatom assemblages experienced a shift in composition with declines in benthic taxa (attached to substrates) and increases in planktonic (free floating) diatoms that began ~1970. Strong relationships between this diatom shift, and increases in regional air temperatures and earlier river ice-out dates were consistent with the expected effects of climate warming on aquatic systems. Our paleolimnological evidence shows that climate warming, rather than human introduction, likely plays an important role in triggering didymo blooms. [ABSTRACT FROM AUTHOR]

Published

2014

43. Simulation of historical temperatures using a multi-site, multivariate block resampling algorithm with perturbation.

Author

King, Leanna M., McLeod, A. Ian, and Simonovic, Slobodan P.

Subjects

METEOROLOGICAL databases, TIME series analysis, CLIMATE change, K-nearest neighbor classification, SIMULATION methods & models, RIVERS

Abstract

Stochastic weather generators have evolved as tools for creating long time series of synthetic meteorological data at a site for risk assessments in hydrologic and agricultural applications. Recently, their use has been extended as downscaling tools for climate change impact assessments. Non-parametric weather generators, which typically use a K-nearest neighbour (K-NN) resampling approach, require no statistical assumptions about probability distributions of variables and can be easily applied for multi-site use. Two characteristics of traditional K-NN models result from resampling daily values: (1) temporal correlation structure of daily temperatures may be lost, and (2) no values less than or exceeding historical observations can be simulated. Temporal correlation in simulated temperature data is important for hydrologic applications. Temperature is a major driver of many processes within the hydrologic cycle (for example, evaporation, snow melt, etc.) that may affect flood levels. As such, a new methodology for simulation of climate data using the K-NN approach is presented (named KnnCAD Version 4). A block resampling scheme is introduced along with perturbation of the reshuffled daily temperature data to create 675 years of synthetic historical daily temperatures for the Upper Thames River basin in Ontario, Canada. The updated KnnCAD model is shown to adequately reproduce observed monthly temperature characteristics as well as temporal and spatial correlations while simulating reasonable values which can exceed the range of observations. Copyright © 2012 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2014

44. An Excavation of Place.

Author

Ray, Janisse

Subjects

ACCLIMATIZATION, GLOBAL warming, CLIMATOLOGY, CLIMATE change, RIVERS

Abstract

The article reports that individual start loosing capabilities, and essentialities, as they strive to civilize and technologize and industrialize and sanitize and safeguard their lives. It is mentioned that during the last 100 million years, as global climate change caused the sea to rise and fall across the land, rivers deposited vast loads of sand, silt, and clay at the shore to help form Georgia's Coastal Plain.

Published

2011

45. Vulnerability to climate change: people, place and exposure to hazard.

Author

Hutton, C. W., Kienberger, S., Johnson, F. Amoako, Allan, A., Giannini, V., and Allen, R.

Subjects

*CLIMATE change, *WATERSHEDS, *RIVERS, *CLIMATOLOGY, *INVESTORS

Abstract

The article presents a study that determines the vulnerability of the people to the climate change in upper Brahmaputra and Danube river basins. It cites the Human Dimension of the Twinning European and South Asian River Basins to Enhance Capacity and Implement Adaptive Management Approaches Project (EC-Project BRAHMATWINN) aimed at developing socio-economic tools for the effective inclusion of the assessment. The study uses stakeholder inputs to identify weightings of vulnerability domains.

Published

2011

46. Challenges for water sharing in the Nile basin: changing geo-politics and changing climate.

Author

Swain, Ashok

Subjects

*RIPARIAN areas, *WETLANDS, *RIVERS, *SUPPLY & demand, *CLIMATE change, *CLIMATOLOGY, *RUNOFF, *HYDROLOGIC cycle

Abstract

For most of the 20th century, the Nile River has been the source of political tensions and low-intensity conflicts among three of its major riparian countries (Ethiopia, Sudan and Egypt). However, since the late 1990s, the Nile basin countries-with the encouragement and support of the international community-have made some attempts to establish basin-wide cooperative institutions. This process of engagement and collaboration is presently under severe stress due to increasing demand and decreasing supply of water resources in the basin. This situation may be complicated further by the global climate change, which is anticipated to result in long-term changes in the volume and pattern of runoff in the Nile River system. Moreover, the emergence of China as a major player in the power politics of the Nile basin has facilitated a number of unilateral initiatives for large-scale water development projects. In this context, this paper critically examines the survival and sustainability of water cooperation endeavours in the Nile basin as the river faces challenges from the global climate change and shifting regional geo-politics. Citation Swain, A. (2011) Challenges for water sharing in the Nile basin: changing geo-politics and changing climate. Hydrol. Sci. J. 56(4), 687-702. [ABSTRACT FROM AUTHOR]

Published

2011

47. Long-term trends in hydro-climatology of a major Scottish mountain river

Author

Baggaley, N.J., Langan, S.J., Futter, M.N., Potts, J.M., and Dunn, S.M.

Subjects

*CLIMATOLOGY, *RIVERS, *SNOW, *STREAMFLOW, *CLIMATE change, *METEOROLOGICAL precipitation

Abstract

Abstract: The River Dee, in North East Scotland, is a mountainous river strongly influenced by patterns of snow accumulation and melt from the Cairngorm Mountains. Analysis of this river''s flow record from 1929–2004, the longest in Scotland, supports anecdotal evidence that river extreme flows are increasing. There was no detectable change in the overall annual flow patterns. However, an analysis of seasonal data suggested a shift towards increased flows in spring (March–May) and decreased flows in summer (June–August) over the 75 years of the record. Flows in spring exceeded 29 m3 s−1 for 50% of the time over the earliest part of the record (1930 to 1954), whereas in the last 25 years of the record (1979 to 2004) 50% of the flows exceeded 35 m3 s−1. Precipitation is increasing in the spring and decreasing in July and August. If these trends continue they have important implications for water management in the Dee, with a potential increase in flood risk in spring and the increased possibility of drought in summer. Combined with this increase in flows the river appears to be more responsive to precipitation events in the catchment. In large heterogeneous catchments with a marginal alpine/high latitude climate it is difficult to assess the amount of precipitation falling as snow and its relative accumulation and ablation dynamics on daily to seasonal time scales. Changes in the temporal pattern of coherence between flow and precipitation are thought to be linked to changing snow patterns in the upland part of the catchment. A decreased amount of precipitation occurring as snow has led to higher coherence. We also show that in responsive systems it is important to record river flows at an hourly rather than daily time step in order to characterise peak flow events. [Copyright &y& Elsevier]

Published

2009

48. Projected future runoff of the Breede River under climate change.

Author

Steynor, A. C., Hewitson, B. C., and Tadross, M. A.

Subjects

*RIVERS, *HYDROLOGIC cycle, *CLIMATE change, *WATERSHEDS, *CLIMATOLOGY, *SUSTAINABILITY

Abstract

The Breede River is the largest river in the Western Cape Province of South Africa, and as such, is a key resource for a variety of activities within the region. It is this significance of the river that prompted a study into the impact of climate change on future runoff in the river and hence, the potential impacts a projected change in catchment runoff may have on the future use of the river. Due to the complexities of the catchment only specialised hydrological models can capture the system dynamics of the river adequately. This limitation prompted the use of an alternative approach (self-organising maps (SOMs)) to hydrological modelling and, at the same time, performed an assessment of the appropriateness of this alternative approach for use in such applications. SUMs are a powerful tool in synoptic climatology as they can be used to objectively classify a large number of daily synoptic states into a predetermined number of groups. Each archetypal synoptic pattern is linked to an observed associated runoff in the catchment. With an assessment of the change in frequency of each atmospheric state from control to future comes an assessment of the change in frequency of the associated runoff from control to future. The end result of this is a quantified assessment of the projected change in both high-frequency runoff events and in the projected change in mean annual runoff (MAR) in the catchment from the present to the future under 3 climate models. Not only does this information assist in the process of long-term policy decisions made in relation to water-transfer schemes, but it also allows for an assessment of the future ecological sustainability of the catchment. This is achieved by assessing the projected future level of flow at each runoff gauging station against the current benchmark for ecological sustainability. [ABSTRACT FROM AUTHOR]

Published

2009

49. Simulated nitrogen leaching patterns and adaptation to climate change in two Finnish river basins with contrasting land use and climatic conditions.

Author

Rankinen, Katri, Valpasvuo-Jaatinen, Pirkko, Karhunen, Anni, Kenttämies, Kaarle, Nenonen, Suvi, and Bärlund, Ilona

Subjects

*CLIMATE change, *NITROGEN, *WATERSHEDS, *STREAMFLOW, *STREAM measurements, *PRECIPITATION variability, *CLIMATOLOGY, *RIVERS

Abstract

Inorganic nitrogen (N) loading was simulated by the catchment scale INCA-N model from two large river basins with contrasting land use. The main aim was to analyze the timing and origin of inorganic N loading and the effectiveness of different water protection methods. Predicted changes in precipitation and temperature increases the nutrient load from catchments to water bodies in future climate. The total inorganic N load from the forested Simojoki river basin located in northern Finland was about 5% of that from the Loimijoki river basin in south western Finland. In the Loimijoki river basin agriculture dominated inorganic N loading. When applying realistic water protection methods (limits on manure spreading) the simulated inorganic N load from the river basin decreased by 11%. With more drastic methods (no manure spreading + catch crop) a decrease up to 34% was achieved. In the Simojoki river basin there were several equally significant sources, so suitable combinations of different water protection measures would be the most efficient way to decrease the inorganic N load. As the inorganic N load may be composed of very different sources, depending on land use in the river basin, efficient allocation of water protection measures requires detailed analysis of different sources of loading. [ABSTRACT FROM AUTHOR]

Published

2009

50. Stream Temperature Trends in Turkey.

Author

AIbek, Mine and AIbek, Erdem

Subjects

WATER temperature, RIVERS, WATER analysis, SOLUBILITY, VISCOSITY, SOLAR radiation -- Environmental aspects, CLIMATOLOGY, PROTECTION of fish habitat

Abstract

The article presents a study on the trends of stream temperature in Turkey. It notes that the most essential physical property of the bodies of water is its temperature that affect other properties including density, viscosity, and gas solubility. The stream temperature is influenced by heat exchange that greatly involves the environment. The main temporal variance is made by seasonal changes including air temperature, atmospheric, and solar radiation. The flow and temperature data for the analysis are gathered by the Electrical Power Resources Survey and Development Administration (EIE) on streams throughout Turkey. The result shows that the major effects of rising water temperature include the loss of habitat for fishes, disease susceptibility, and water quality deterioration.

Published

2009