Changes

On November 1, 2024 at 3:38:55 PM MDT, ahmed_shalaby:
Renamed resource https://journals.ametsoc.org/view/journals/hydr/20/2/jhm-d-18-0187_1.xml?rskey=sFT3fn&result=8 to Impact of Future Climate on Arctic Headwater in Impact of Future Climate and Vegetation on the Hydrology of an Arctic Headwater Basin at the Tundra–Taiga Transition
              
    
          
          
        
        
            f 1 { f 1 {
            2   "Creator": "Journal of Hydrometeorology", 2   "Creator": "Journal of Hydrometeorology",
            3   "author": null, 3   "author": null,
            4   "author_email": null, 4   "author_email": null,
            5   "creator_user_id": "80a5dcde-1c45-4f36-9a1d-46db676c889d", 5   "creator_user_id": "80a5dcde-1c45-4f36-9a1d-46db676c889d",
            6   "description": "", 6   "description": "",
            7   "funding_program": "", 7   "funding_program": "",
            8   "geographic_range": [ 8   "geographic_range": [
            9     "NWT" 9     "NWT"
            10   ], 10   ],
            11   "groups": [], 11   "groups": [],
            12   "id": "92f5163e-da99-4d97-a2e2-a2a7a6b9ca47", 12   "id": "92f5163e-da99-4d97-a2e2-a2a7a6b9ca47",
            13   "isopen": false, 13   "isopen": false,
            14   "license_id": "notspecified", 14   "license_id": "notspecified",
            15   "license_title": "License Not Specified", 15   "license_title": "License Not Specified",
            16   "local_relevance": "This study modelled the impacts of climate  16   "local_relevance": "This study modelled the impacts of climate 
            17 change and vegetation shifts on hydrology of Havikpak Creek in NWT.   17 change and vegetation shifts on hydrology of Havikpak Creek in NWT.  
            18 Projections under the RCP8.5 scenario show significant warming,  18 Projections under the RCP8.5 scenario show significant warming, 
            19 increased precipitation, and changes in snow and water processes.", 19 increased precipitation, and changes in snow and water processes.",
            20   "maintainer": null, 20   "maintainer": null,
            21   "maintainer_email": null, 21   "maintainer_email": null,
            22   "metadata_created": "2024-10-16T17:39:16.985517", 22   "metadata_created": "2024-10-16T17:39:16.985517",
            n 23   "metadata_modified": "2024-11-01T21:32:07.541454", n 23   "metadata_modified": "2024-11-01T21:38:55.707670",
            24   "metatags": "Arctic,Watershed,Climate models,Hydrologic models", 24   "metatags": "Arctic,Watershed,Climate models,Hydrologic models",
            25   "modified_date": "2019-02-01", 25   "modified_date": "2019-02-01",
            26   "name":  26   "name": 
            27 "impact-of-future-climate-on-the-hydrology-of-an-arctic-headwater", 27 "impact-of-future-climate-on-the-hydrology-of-an-arctic-headwater",
            28   "notes": "This study explores the impacts of climate change and  28   "notes": "This study explores the impacts of climate change and 
            29 vegetation shifts on hydrology in an Arctic headwater basin in  29 vegetation shifts on hydrology in an Arctic headwater basin in 
            30 northwestern Canada, using atmospheric and hydrological models.", 30 northwestern Canada, using atmospheric and hydrological models.",
            31   "num_resources": 1, 31   "num_resources": 1,
            32   "num_tags": 4, 32   "num_tags": 4,
            33   "organization": { 33   "organization": {
            34     "approval_status": "approved", 34     "approval_status": "approved",
            35     "created": "2023-11-30T14:30:44.490751", 35     "created": "2023-11-30T14:30:44.490751",
            36     "description": "The AMS is a global community committed to  36     "description": "The AMS is a global community committed to 
            37 advancing weather, water, and climate science and service.", 37 advancing weather, water, and climate science and service.",
            38     "id": "d4b3fa25-b87c-4bc3-9bca-83ad827f9f2e", 38     "id": "d4b3fa25-b87c-4bc3-9bca-83ad827f9f2e",
            39     "image_url": "2024-01-22-171329.375793download.jfif", 39     "image_url": "2024-01-22-171329.375793download.jfif",
            40     "is_organization": true, 40     "is_organization": true,
            41     "name": "american-meteorological-society", 41     "name": "american-meteorological-society",
            42     "state": "active", 42     "state": "active",
            43     "title": "American Meteorological Society", 43     "title": "American Meteorological Society",
            44     "type": "organization" 44     "type": "organization"
            45   }, 45   },
            46   "owner_org": "d4b3fa25-b87c-4bc3-9bca-83ad827f9f2e", 46   "owner_org": "d4b3fa25-b87c-4bc3-9bca-83ad827f9f2e",
            47   "private": false, 47   "private": false,
            48   "relationships_as_object": [], 48   "relationships_as_object": [],
            49   "relationships_as_subject": [], 49   "relationships_as_subject": [],
            50   "release_date": "2019-02-01", 50   "release_date": "2019-02-01",
            51   "resources": [ 51   "resources": [
            52     { 52     {
            53       "cache_last_updated": null, 53       "cache_last_updated": null,
            54       "cache_url": null, 54       "cache_url": null,
            55       "created": "2024-10-16T17:39:29.144223", 55       "created": "2024-10-16T17:39:29.144223",
            56       "datastore_active": false, 56       "datastore_active": false,
            57       "datastore_contains_all_records_of_source_file": false, 57       "datastore_contains_all_records_of_source_file": false,
            58       "description": null, 58       "description": null,
            59       "format": "PDF", 59       "format": "PDF",
            60       "hash": "", 60       "hash": "",
            61       "id": "be215e42-854f-41af-bc0b-9c166a38a1e1", 61       "id": "be215e42-854f-41af-bc0b-9c166a38a1e1",
            62       "last_modified": null, 62       "last_modified": null,
            n 63       "metadata_modified": "2024-10-16T17:39:29.246844", n 63       "metadata_modified": "2024-11-01T21:37:24.581360",
            64       "mimetype": null, 64       "mimetype": null,
            65       "mimetype_inner": null, 65       "mimetype_inner": null,
            t 66       "name":  t 66       "name": "Impact of Future Climate on Arctic Headwater ",
            67 rg/view/journals/hydr/20/2/jhm-d-18-0187_1.xml?rskey=sFT3fn&result=8", 
            68       "package_id": "92f5163e-da99-4d97-a2e2-a2a7a6b9ca47", 67       "package_id": "92f5163e-da99-4d97-a2e2-a2a7a6b9ca47",
            69       "position": 0, 68       "position": 0,
            70       "resource_type": null, 69       "resource_type": null,
            71       "size": null, 70       "size": null,
            72       "state": "active", 71       "state": "active",
            73       "url":  72       "url": 
            74 rg/view/journals/hydr/20/2/jhm-d-18-0187_1.xml?rskey=sFT3fn&result=8", 73 rg/view/journals/hydr/20/2/jhm-d-18-0187_1.xml?rskey=sFT3fn&result=8",
            75       "url_type": null 74       "url_type": null
            76     } 75     }
            77   ], 76   ],
            78   "state": "active", 77   "state": "active",
            79   "summary": "The rapidly warming Arctic is experiencing permafrost  78   "summary": "The rapidly warming Arctic is experiencing permafrost 
            80 degradation and shrub expansion. Future climate projections show a  79 degradation and shrub expansion. Future climate projections show a 
            81 clear increase in mean annual temperature and increasing precipitation  80 clear increase in mean annual temperature and increasing precipitation 
            82 in the Arctic; however, the impact of these changes on hydrological  81 in the Arctic; however, the impact of these changes on hydrological 
            83 cycling in Arctic headwater basins is poorly understood. This study  82 cycling in Arctic headwater basins is poorly understood. This study 
            84 investigates the impact of climate change, as represented by  83 investigates the impact of climate change, as represented by 
            85 simulations using a high-resolution atmospheric model under a  84 simulations using a high-resolution atmospheric model under a 
            86 pseudo-global-warming configuration, and projected changes in  85 pseudo-global-warming configuration, and projected changes in 
            87 vegetation, using a spatially distributed and physically based Arctic  86 vegetation, using a spatially distributed and physically based Arctic 
            88 hydrological model, on a small headwater basin at the  87 hydrological model, on a small headwater basin at the 
            89 tundra\u2013taiga transition in northwestern Canada. Climate  88 tundra\u2013taiga transition in northwestern Canada. Climate 
            90 projections under the RCP8.5 emission scenario show a 6.1\u00b0C  89 projections under the RCP8.5 emission scenario show a 6.1\u00b0C 
            91 warming, a 38% increase in annual precipitation, and a 19 W m\u22122  90 warming, a 38% increase in annual precipitation, and a 19 W m\u22122 
            92 increase in all-wave annual irradiance over the twenty-first century.  91 increase in all-wave annual irradiance over the twenty-first century. 
            93 Hydrological modeling results suggest a shift in hydrological  92 Hydrological modeling results suggest a shift in hydrological 
            94 processes with maximum peak snow accumulation increasing by 70%,  93 processes with maximum peak snow accumulation increasing by 70%, 
            95 snow-cover duration shortening by 26 days, active layer deepening by  94 snow-cover duration shortening by 26 days, active layer deepening by 
            96 0.25 m, evapotranspiration increasing by 18%, and sublimation  95 0.25 m, evapotranspiration increasing by 18%, and sublimation 
            97 decreasing by 9%. This results in an intensification of the  96 decreasing by 9%. This results in an intensification of the 
            98 hydrological regime by doubling discharge volume, a 130% increase in  97 hydrological regime by doubling discharge volume, a 130% increase in 
            99 spring runoff, and earlier and larger peak streamflow. Most  98 spring runoff, and earlier and larger peak streamflow. Most 
            100 hydrological changes were found to be driven by climate change;  99 hydrological changes were found to be driven by climate change; 
            101 however, increasing vegetation cover and density reduced blowing snow  100 however, increasing vegetation cover and density reduced blowing snow 
            102 redistribution and sublimation, and increased evaporation from  101 redistribution and sublimation, and increased evaporation from 
            103 intercepted rainfall. This study provides the first detailed  102 intercepted rainfall. This study provides the first detailed 
            104 investigation of projected changes in climate and vegetation on the  103 investigation of projected changes in climate and vegetation on the 
            105 hydrology of an Arctic headwater basin, and so it is expected to help  104 hydrology of an Arctic headwater basin, and so it is expected to help 
            106 inform larger-scale climate impact studies in the Arctic.\r\n\r\n", 105 inform larger-scale climate impact studies in the Arctic.\r\n\r\n",
            107   "tags": [ 106   "tags": [
            108     { 107     {
            109       "display_name": "Arctic", 108       "display_name": "Arctic",
            110       "id": "25dee16e-a24a-4238-a428-3617178f21cc", 109       "id": "25dee16e-a24a-4238-a428-3617178f21cc",
            111       "name": "Arctic", 110       "name": "Arctic",
            112       "state": "active", 111       "state": "active",
            113       "vocabulary_id": null 112       "vocabulary_id": null
            114     }, 113     },
            115     { 114     {
            116       "display_name": "Climate models", 115       "display_name": "Climate models",
            117       "id": "5e8d720e-d6ef-457d-a9a7-76d2ac818d6b", 116       "id": "5e8d720e-d6ef-457d-a9a7-76d2ac818d6b",
            118       "name": "Climate models", 117       "name": "Climate models",
            119       "state": "active", 118       "state": "active",
            120       "vocabulary_id": null 119       "vocabulary_id": null
            121     }, 120     },
            122     { 121     {
            123       "display_name": "Hydrologic models", 122       "display_name": "Hydrologic models",
            124       "id": "5b644140-9b28-49cb-8093-5ead41b27d93", 123       "id": "5b644140-9b28-49cb-8093-5ead41b27d93",
            125       "name": "Hydrologic models", 124       "name": "Hydrologic models",
            126       "state": "active", 125       "state": "active",
            127       "vocabulary_id": null 126       "vocabulary_id": null
            128     }, 127     },
            129     { 128     {
            130       "display_name": "Watershed", 129       "display_name": "Watershed",
            131       "id": "a7d35a00-caad-4196-ade6-8d8cb86a67bd", 130       "id": "a7d35a00-caad-4196-ade6-8d8cb86a67bd",
            132       "name": "Watershed", 131       "name": "Watershed",
            133       "state": "active", 132       "state": "active",
            134       "vocabulary_id": null 133       "vocabulary_id": null
            135     } 134     }
            136   ], 135   ],
            137   "title": "Impact of Future Climate and Vegetation on the Hydrology  136   "title": "Impact of Future Climate and Vegetation on the Hydrology 
            138 of an Arctic Headwater Basin at the Tundra\u2013Taiga Transition", 137 of an Arctic Headwater Basin at the Tundra\u2013Taiga Transition",
            139   "type": "dataset", 138   "type": "dataset",
            140   "url": null, 139   "url": null,
            141   "version": null 140   "version": null
            142 } 141 }