SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2802085918> ?p ?o ?g. }

Showing items 1 to 100 of ±136 with 100 items per page.

W2802085918 endingPage "289" @default.
W2802085918 startingPage "281" @default.
W2802085918 abstract "Thermal infrared (TIR) imaging has been previously applied to survey relatively large thermal footprints in coastal zones, lakes, reservoirs and rivers. In freshwater systems, the buoyancy of relatively warm groundwater during the winter months allows for the surface identification of groundwater discharge or thermal pollution using TIR imaging. However, information regarding the performance of TIR for resolving this warm groundwater upwelling is limited, particularly at fine spatial scales and variable discharge rates. In order to evaluate the suitability of TIR to trace warm groundwater upwelling at the water surface of lakes, ponds and reservoirs (e.g. lacustrine groundwater discharge (LGD) in shallow near-shore zones) we conducted a mesocosm experiment with a TIR camera situated 4 m above the water surface to capture thermal patterns in response to different groundwater discharge rates, weather conditions and the diurnal cycle. A fiber optic distributed temperature sensing system (FO-DTS) installed at 2 cm below the water surface was used to ground-truth spatial patterns observed in TIR images. Results show the impacts of both the diurnal cycle of net radiation and prevailing weather conditions on the accuracy of TIR imaging for resolving warm groundwater discharge. Most reliable results were obtained under overcast weather conditions and during the night. The results of our study provide guidance for those looking to use TIR for conducting thermal tracing of LGD at the surface of freshwater bodies during winter." @default.
W2802085918 created "2018-05-17" @default.
W2802085918 creator A5000825345 @default.
W2802085918 creator A5016463030 @default.
W2802085918 creator A5031817348 @default.
W2802085918 creator A5063661784 @default.
W2802085918 creator A5071071443 @default.
W2802085918 date "2018-07-01" @default.
W2802085918 modified "2023-09-27" @default.
W2802085918 title "Thermal infrared imaging for the detection of relatively warm lacustrine groundwater discharge at the surface of freshwater bodies" @default.
W2802085918 cites W1486077568 @default.
W2802085918 cites W1497300469 @default.
W2802085918 cites W1524542799 @default.
W2802085918 cites W1554925870 @default.
W2802085918 cites W1826885782 @default.
W2802085918 cites W1989213109 @default.
W2802085918 cites W1992102586 @default.
W2802085918 cites W1993300744 @default.
W2802085918 cites W1997456222 @default.
W2802085918 cites W2009416084 @default.
W2802085918 cites W2009865789 @default.
W2802085918 cites W2013922780 @default.
W2802085918 cites W2014242989 @default.
W2802085918 cites W2021463696 @default.
W2802085918 cites W2028220976 @default.
W2802085918 cites W2033084253 @default.
W2802085918 cites W2034947559 @default.
W2802085918 cites W2040688381 @default.
W2802085918 cites W2045297017 @default.
W2802085918 cites W2046184099 @default.
W2802085918 cites W2050344631 @default.
W2802085918 cites W2068241769 @default.
W2802085918 cites W2071882289 @default.
W2802085918 cites W2074184327 @default.
W2802085918 cites W2075642436 @default.
W2802085918 cites W2078383212 @default.
W2802085918 cites W2089925989 @default.
W2802085918 cites W2090157291 @default.
W2802085918 cites W2095765637 @default.
W2802085918 cites W2096834760 @default.
W2802085918 cites W2100266608 @default.
W2802085918 cites W2108582485 @default.
W2802085918 cites W2115466908 @default.
W2802085918 cites W2118898434 @default.
W2802085918 cites W2122348296 @default.
W2802085918 cites W2129910327 @default.
W2802085918 cites W2135857637 @default.
W2802085918 cites W2139851675 @default.
W2802085918 cites W2147735603 @default.
W2802085918 cites W2148512223 @default.
W2802085918 cites W2149570690 @default.
W2802085918 cites W2162631619 @default.
W2802085918 cites W2191961049 @default.
W2802085918 cites W2238730062 @default.
W2802085918 cites W2255050781 @default.
W2802085918 cites W2276177538 @default.
W2802085918 cites W2313938314 @default.
W2802085918 cites W2316572668 @default.
W2802085918 cites W2340299037 @default.
W2802085918 cites W2477125215 @default.
W2802085918 cites W2485057948 @default.
W2802085918 cites W2509037287 @default.
W2802085918 cites W2546505481 @default.
W2802085918 cites W2769956326 @default.
W2802085918 cites W2072322836 @default.
W2802085918 doi "https://doi.org/10.1016/j.jhydrol.2018.05.004" @default.
W2802085918 hasPublicationYear "2018" @default.
W2802085918 type Work @default.
W2802085918 sameAs 2802085918 @default.
W2802085918 citedByCount "7" @default.
W2802085918 countsByYear W28020859182019 @default.
W2802085918 countsByYear W28020859182020 @default.
W2802085918 countsByYear W28020859182021 @default.
W2802085918 countsByYear W28020859182022 @default.
W2802085918 countsByYear W28020859182023 @default.
W2802085918 crossrefType "journal-article" @default.
W2802085918 hasAuthorship W2802085918A5000825345 @default.
W2802085918 hasAuthorship W2802085918A5016463030 @default.
W2802085918 hasAuthorship W2802085918A5031817348 @default.
W2802085918 hasAuthorship W2802085918A5063661784 @default.
W2802085918 hasAuthorship W2802085918A5071071443 @default.
W2802085918 hasBestOaLocation W28020859182 @default.
W2802085918 hasConcept C111368507 @default.
W2802085918 hasConcept C12129029 @default.
W2802085918 hasConcept C127313418 @default.
W2802085918 hasConcept C131227075 @default.
W2802085918 hasConcept C149348798 @default.
W2802085918 hasConcept C152382732 @default.
W2802085918 hasConcept C187320778 @default.
W2802085918 hasConcept C2777493711 @default.
W2802085918 hasConcept C39432304 @default.
W2802085918 hasConcept C63991900 @default.
W2802085918 hasConcept C75622301 @default.
W2802085918 hasConcept C76177295 @default.
W2802085918 hasConcept C76886044 @default.
W2802085918 hasConcept C8625798 @default.
W2802085918 hasConcept C87717796 @default.
W2802085918 hasConcept C91586092 @default.