Changes
On May 4, 2023 at 2:05:22 PM CDT, Katelyn Rodgers:
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f | 1 | { | f | 1 | { |
2 | "Author": [ | 2 | "Author": [ | ||
3 | { | 3 | { | ||
4 | "affiliation": "Centre for Earth Observation Science - | 4 | "affiliation": "Centre for Earth Observation Science - | ||
5 | University of Manitoba", | 5 | University of Manitoba", | ||
6 | "creatorName": "Rodgers, Katelyn", | 6 | "creatorName": "Rodgers, Katelyn", | ||
7 | "email": "rodgersk@myumanitoba.ca", | 7 | "email": "rodgersk@myumanitoba.ca", | ||
8 | "nameIdentifier": "0009-0009-4738-9504", | 8 | "nameIdentifier": "0009-0009-4738-9504", | ||
9 | "nameIdentifierScheme": "ORCID", | 9 | "nameIdentifierScheme": "ORCID", | ||
10 | "nameType": "Personal", | 10 | "nameType": "Personal", | ||
11 | "schemeURI": "http://orcid.org/" | 11 | "schemeURI": "http://orcid.org/" | ||
12 | } | 12 | } | ||
13 | ], | 13 | ], | ||
14 | "PublicationYear": "2023", | 14 | "PublicationYear": "2023", | ||
15 | "Publisher": "University of Manitoba MSpace", | 15 | "Publisher": "University of Manitoba MSpace", | ||
16 | "ResourceType": "electronic thesis", | 16 | "ResourceType": "electronic thesis", | ||
17 | "Rights": "Creative Commons Attribution 4.0 International", | 17 | "Rights": "Creative Commons Attribution 4.0 International", | ||
18 | "Version": "1.0", | 18 | "Version": "1.0", | ||
19 | "author": null, | 19 | "author": null, | ||
20 | "author_email": null, | 20 | "author_email": null, | ||
21 | "citation": "", | 21 | "citation": "", | ||
22 | "creator_user_id": "5162d2f8-1c54-49f8-a5e1-037125f30f16", | 22 | "creator_user_id": "5162d2f8-1c54-49f8-a5e1-037125f30f16", | ||
23 | "descriptionType": "Abstract", | 23 | "descriptionType": "Abstract", | ||
24 | "groups": [ | 24 | "groups": [ | ||
25 | { | 25 | { | ||
26 | "description": "Inland water features, drainage systems and | 26 | "description": "Inland water features, drainage systems and | ||
27 | their characteristics. Examples of data you can find here include | 27 | their characteristics. Examples of data you can find here include | ||
28 | river and lake data, water quality data. \r\n\r\nIn CEOS, related | 28 | river and lake data, water quality data. \r\n\r\nIn CEOS, related | ||
29 | research themes include biogeochemistry, Inland lakes and waters, | 29 | research themes include biogeochemistry, Inland lakes and waters, | ||
30 | modelling, remote sensing and technology, trace metals and | 30 | modelling, remote sensing and technology, trace metals and | ||
31 | contaminants.", | 31 | contaminants.", | ||
32 | "display_name": "Freshwater", | 32 | "display_name": "Freshwater", | ||
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34 | "image_display_url": | 34 | "image_display_url": | ||
35 | /data/uploads/group/2021-10-31-211937.658599hyinspirehydrography.svg", | 35 | /data/uploads/group/2021-10-31-211937.658599hyinspirehydrography.svg", | ||
36 | "name": "freshwater", | 36 | "name": "freshwater", | ||
37 | "title": "Freshwater" | 37 | "title": "Freshwater" | ||
38 | } | 38 | } | ||
39 | ], | 39 | ], | ||
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41 | "isopen": false, | 41 | "isopen": false, | ||
42 | "language": "English", | 42 | "language": "English", | ||
43 | "licenceType": "Open", | 43 | "licenceType": "Open", | ||
44 | "license_id": null, | 44 | "license_id": null, | ||
45 | "license_title": null, | 45 | "license_title": null, | ||
46 | "maintainer": null, | 46 | "maintainer": null, | ||
47 | "maintainer_email": null, | 47 | "maintainer_email": null, | ||
48 | "metadata_created": "2023-05-04T19:04:07.111001", | 48 | "metadata_created": "2023-05-04T19:04:07.111001", | ||
n | 49 | "metadata_modified": "2023-05-04T19:05:22.609733", | n | 49 | "metadata_modified": "2023-05-04T19:05:22.887796", |
50 | "name": | 50 | "name": | ||
51 | he-effects-of-climate-change-on-nutrient-loading-and-river-discharge", | 51 | he-effects-of-climate-change-on-nutrient-loading-and-river-discharge", | ||
52 | "notes": "This study was conducted to identify temporal changes in | 52 | "notes": "This study was conducted to identify temporal changes in | ||
53 | nutrient and sediment concentrations and loads (total phosphorus, | 53 | nutrient and sediment concentrations and loads (total phosphorus, | ||
54 | particulate phosphorus, total dissolved phosphorus, total nitrogen, | 54 | particulate phosphorus, total dissolved phosphorus, total nitrogen, | ||
55 | and total suspended solids) in Swan River and Woody River of the Swan | 55 | and total suspended solids) in Swan River and Woody River of the Swan | ||
56 | Lake watershed, Manitoba. Temporal changes in physical hydrology | 56 | Lake watershed, Manitoba. Temporal changes in physical hydrology | ||
57 | (river discharge and precipitation) were also investigated to | 57 | (river discharge and precipitation) were also investigated to | ||
58 | determine if these parameters influenced the changes in water quality | 58 | determine if these parameters influenced the changes in water quality | ||
59 | concentrations and loads across the Swan Lake watershed. Annual and | 59 | concentrations and loads across the Swan Lake watershed. Annual and | ||
60 | seasonal totals of water quality variables, river discharge, and | 60 | seasonal totals of water quality variables, river discharge, and | ||
61 | average watershed total precipitation were examined for change over 30 | 61 | average watershed total precipitation were examined for change over 30 | ||
62 | years. The results showed a statistically significant increase in | 62 | years. The results showed a statistically significant increase in | ||
63 | nutrients and total suspended solids (TSS), and river discharge, | 63 | nutrients and total suspended solids (TSS), and river discharge, | ||
64 | particularly in Swan River. Both rivers experienced statistically | 64 | particularly in Swan River. Both rivers experienced statistically | ||
65 | significant increases during the spring season with changes in median | 65 | significant increases during the spring season with changes in median | ||
66 | values as high as 450% in TSS between 1989 \u2013 2000 and 2010 \u2013 | 66 | values as high as 450% in TSS between 1989 \u2013 2000 and 2010 \u2013 | ||
67 | 2018. Annual river discharge in Swan River and Woody River increased | 67 | 2018. Annual river discharge in Swan River and Woody River increased | ||
68 | by 182% and 103%, respectively, with Swan River experiencing a | 68 | by 182% and 103%, respectively, with Swan River experiencing a | ||
69 | statistically significant increase over the 30-year period. | 69 | statistically significant increase over the 30-year period. | ||
70 | Seasonally, both rivers increased statistically significantly in the | 70 | Seasonally, both rivers increased statistically significantly in the | ||
71 | spring season with an 80% increase. Total precipitation across the | 71 | spring season with an 80% increase. Total precipitation across the | ||
72 | watershed increased 3% annually, including a 6% increase in the | 72 | watershed increased 3% annually, including a 6% increase in the | ||
73 | spring, and summer and fall seasons, and 8% decrease in the winter | 73 | spring, and summer and fall seasons, and 8% decrease in the winter | ||
74 | season between 1995 \u2013 2001 and 2009 \u2013 2015. There were | 74 | season between 1995 \u2013 2001 and 2009 \u2013 2015. There were | ||
75 | correlations between water quality variables and river discharge, and | 75 | correlations between water quality variables and river discharge, and | ||
76 | between river discharge and precipitation. Precipitation in this area | 76 | between river discharge and precipitation. Precipitation in this area | ||
77 | influences river discharge and since nutrients and sediments are | 77 | influences river discharge and since nutrients and sediments are | ||
78 | strongly correlated with river discharge, precipitation indirectly | 78 | strongly correlated with river discharge, precipitation indirectly | ||
79 | influences nutrient and sediment exports.", | 79 | influences nutrient and sediment exports.", | ||
80 | "num_resources": 1, | 80 | "num_resources": 1, | ||
81 | "num_tags": 4, | 81 | "num_tags": 4, | ||
82 | "organization": { | 82 | "organization": { | ||
83 | "approval_status": "approved", | 83 | "approval_status": "approved", | ||
84 | "created": "2017-07-21T13:15:49.935872", | 84 | "created": "2017-07-21T13:15:49.935872", | ||
85 | "description": "The Centre for Earth Observation Science (CEOS) | 85 | "description": "The Centre for Earth Observation Science (CEOS) | ||
86 | was established in 1994 with a mandate to research, preserve and | 86 | was established in 1994 with a mandate to research, preserve and | ||
87 | communicate knowledge of Earth system processes using the technologies | 87 | communicate knowledge of Earth system processes using the technologies | ||
88 | of Earth Observation Science. Research is multidisciplinary and | 88 | of Earth Observation Science. Research is multidisciplinary and | ||
89 | collaborative seeking to understand the complex interrelationships | 89 | collaborative seeking to understand the complex interrelationships | ||
90 | between elements of Earth systems, and how these systems will likely | 90 | between elements of Earth systems, and how these systems will likely | ||
91 | respond to climate change. Although researchers have worked in many | 91 | respond to climate change. Although researchers have worked in many | ||
92 | regions, the Arctic marine system has always been a unifying focus of | 92 | regions, the Arctic marine system has always been a unifying focus of | ||
93 | activity.\r\n\r\nIn 2012, CEOS, along with the Greenland Climate | 93 | activity.\r\n\r\nIn 2012, CEOS, along with the Greenland Climate | ||
94 | Research Centre (GCRC, Nuuk, Greenland) and the Arctic Research Centre | 94 | Research Centre (GCRC, Nuuk, Greenland) and the Arctic Research Centre | ||
95 | (ARC, Aarhus, Denmark) established the Arctic Science Partnership, | 95 | (ARC, Aarhus, Denmark) established the Arctic Science Partnership, | ||
96 | thereby integrating academic and research initiatives.\r\n\r\nAreas of | 96 | thereby integrating academic and research initiatives.\r\n\r\nAreas of | ||
97 | existing research activity are divided among key themes:\r\n\r\nArctic | 97 | existing research activity are divided among key themes:\r\n\r\nArctic | ||
98 | Anthropology/Paleoclimatology: LiDAR scanning and digital site | 98 | Anthropology/Paleoclimatology: LiDAR scanning and digital site | ||
99 | preservation, archaeo-geophysics, permafrost degredation, lithic | 99 | preservation, archaeo-geophysics, permafrost degredation, lithic | ||
100 | morphometrics, zooarchaeology, proxy studies, paleodistribution of sea | 100 | morphometrics, zooarchaeology, proxy studies, paleodistribution of sea | ||
101 | ice, landscape learning, Paleo-Eskimo culture, Thule Inuit culture, | 101 | ice, landscape learning, Paleo-Eskimo culture, Thule Inuit culture, | ||
102 | ethnographic analogy, traditional knowledge, climate change and | 102 | ethnographic analogy, traditional knowledge, climate change and | ||
103 | northern heritage resource management.\r\n\r\nAtmospheric | 103 | northern heritage resource management.\r\n\r\nAtmospheric | ||
104 | Studies/Meteorology: Boundary layer, precipitation, clouds, storms and | 104 | Studies/Meteorology: Boundary layer, precipitation, clouds, storms and | ||
105 | extreme weather, circulation, eddy correlations, polar vortex, | 105 | extreme weather, circulation, eddy correlations, polar vortex, | ||
106 | climate, teleconnections, geophysical fluid dynamics, flux and energy | 106 | climate, teleconnections, geophysical fluid dynamics, flux and energy | ||
107 | budgets, ocean-sea ice-atmosphere interface, radiative transfer, ice | 107 | budgets, ocean-sea ice-atmosphere interface, radiative transfer, ice | ||
108 | albedo feedback, cloud radiative forcing, pCO2. | 108 | albedo feedback, cloud radiative forcing, pCO2. | ||
109 | \r\n\r\nBiogeochemistry: Organic carbon, greenhouse gases, bubbles, | 109 | \r\n\r\nBiogeochemistry: Organic carbon, greenhouse gases, bubbles, | ||
110 | Ikaite, carbonate chemistry, CO2 fluxes, mercury and other trace | 110 | Ikaite, carbonate chemistry, CO2 fluxes, mercury and other trace | ||
111 | metals, minerals, hydrocarbons, brine processes, otolith | 111 | metals, minerals, hydrocarbons, brine processes, otolith | ||
112 | microchemistry, sediments, biomarkers. \r\n\r\nContaminants: Mercury, | 112 | microchemistry, sediments, biomarkers. \r\n\r\nContaminants: Mercury, | ||
113 | trace metals, PAHs, source, transport, transformation, pathways, | 113 | trace metals, PAHs, source, transport, transformation, pathways, | ||
114 | bioaccumulations, marine ecosystems, marine chemistry. \r\nEarth | 114 | bioaccumulations, marine ecosystems, marine chemistry. \r\nEarth | ||
115 | Observation Science: Active and passive microwave, LiDAR, EM | 115 | Observation Science: Active and passive microwave, LiDAR, EM | ||
116 | induction, spatial-temporal analysis, forward and inverse scattering | 116 | induction, spatial-temporal analysis, forward and inverse scattering | ||
117 | models, complex permittivity, ocean colour, ocean surface roughness, | 117 | models, complex permittivity, ocean colour, ocean surface roughness, | ||
118 | NIR, TIR, satellite telemetry, GPS. Ice-Associated Biology: | 118 | NIR, TIR, satellite telemetry, GPS. Ice-Associated Biology: | ||
119 | Biophysical processes, primary production; ice algae, ice | 119 | Biophysical processes, primary production; ice algae, ice | ||
120 | microbiology, bio-optics, under-ice phytoplankton. \r\n\r\nInland | 120 | microbiology, bio-optics, under-ice phytoplankton. \r\n\r\nInland | ||
121 | Lakes and Waters: Hydrologic connectivity, watershed systems, sediment | 121 | Lakes and Waters: Hydrologic connectivity, watershed systems, sediment | ||
122 | transport, nutrient transport, contaminants, landscape processes, | 122 | transport, nutrient transport, contaminants, landscape processes, | ||
123 | remote sensing, freshwater-marine coupling. Marine Mammals: Seals, | 123 | remote sensing, freshwater-marine coupling. Marine Mammals: Seals, | ||
124 | whales, habitat, conservation, satellite telemetry, distribution, | 124 | whales, habitat, conservation, satellite telemetry, distribution, | ||
125 | population studies, prey behaviour, bioacoustics.\r\n\r\nModelling: | 125 | population studies, prey behaviour, bioacoustics.\r\n\r\nModelling: | ||
126 | Simulation of sea ice and oceanic regional processes, Nucleus for | 126 | Simulation of sea ice and oceanic regional processes, Nucleus for | ||
127 | European Modelling of the Ocean (NEMO), ice-ocean modelling and | 127 | European Modelling of the Ocean (NEMO), ice-ocean modelling and | ||
128 | interactions, hind cast simulations and projections for sea ice state | 128 | interactions, hind cast simulations and projections for sea ice state | ||
129 | and ocean variables based on CMIP5 scenarios and MIROC5 forcing, | 129 | and ocean variables based on CMIP5 scenarios and MIROC5 forcing, | ||
130 | validation.\r\n\r\nOceanography: Circulation, temperature, in-flow and | 130 | validation.\r\n\r\nOceanography: Circulation, temperature, in-flow and | ||
131 | out-flow shelves, water dynamics, microturbulence, Beaufort Gyre, eddy | 131 | out-flow shelves, water dynamics, microturbulence, Beaufort Gyre, eddy | ||
132 | correlations.\r\n\r\nSea Ice Geophysics:Thermodynamic and dynamic | 132 | correlations.\r\n\r\nSea Ice Geophysics:Thermodynamic and dynamic | ||
133 | processes, extreme ice features and hazards, snow, ridges, | 133 | processes, extreme ice features and hazards, snow, ridges, | ||
134 | polynyas.\r\n\r\nTraditional and Local Knowledge: Indigenous cultures, | 134 | polynyas.\r\n\r\nTraditional and Local Knowledge: Indigenous cultures, | ||
135 | Inuit, Inuvialuit, oral history, toponomy, mobility and settlement, | 135 | Inuit, Inuvialuit, oral history, toponomy, mobility and settlement, | ||
136 | hunting, food security, sea ice use, community-based research, | 136 | hunting, food security, sea ice use, community-based research, | ||
137 | community-based monitoring, two ways of knowing.", | 137 | community-based monitoring, two ways of knowing.", | ||
138 | "id": "9e21f6b6-d13f-4ba2-a379-fd962f507071", | 138 | "id": "9e21f6b6-d13f-4ba2-a379-fd962f507071", | ||
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140 | "is_organization": true, | 140 | "is_organization": true, | ||
141 | "name": "ceos", | 141 | "name": "ceos", | ||
142 | "state": "active", | 142 | "state": "active", | ||
143 | "title": "Centre for Earth Observation Science", | 143 | "title": "Centre for Earth Observation Science", | ||
144 | "type": "organization" | 144 | "type": "organization" | ||
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147 | "private": false, | 147 | "private": false, | ||
148 | "related_datasets": [], | 148 | "related_datasets": [], | ||
149 | "related_programs": [ | 149 | "related_programs": [ | ||
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156 | "cache_last_updated": null, | 156 | "cache_last_updated": null, | ||
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158 | "created": "2023-05-04T19:05:22.627533", | 158 | "created": "2023-05-04T19:05:22.627533", | ||
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160 | "datastore_contains_all_records_of_source_file": false, | 160 | "datastore_contains_all_records_of_source_file": false, | ||
161 | "description": "Katelyn Rodgers' master thesis from University | 161 | "description": "Katelyn Rodgers' master thesis from University | ||
162 | of Manitoba MSpace", | 162 | of Manitoba MSpace", | ||
163 | "format": "HTML", | 163 | "format": "HTML", | ||
164 | "hash": "", | 164 | "hash": "", | ||
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170 | "name": "The effects of climate change on nutrient loading and | 170 | "name": "The effects of climate change on nutrient loading and | ||
171 | river discharge", | 171 | river discharge", | ||
172 | "package_id": "da01f51f-1d97-4a3f-960d-5c6b17d92c56", | 172 | "package_id": "da01f51f-1d97-4a3f-960d-5c6b17d92c56", | ||
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177 | "state": "active", | 177 | "state": "active", | ||
178 | "url": | 178 | "url": | ||
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190 | "subjectScheme": "Polar Data Catalogue", | 190 | "subjectScheme": "Polar Data Catalogue", | ||
191 | "tags": [ | 191 | "tags": [ | ||
192 | { | 192 | { | ||
193 | "display_name": "Freshwaters", | 193 | "display_name": "Freshwaters", | ||
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204 | "vocabulary_id": null | 204 | "vocabulary_id": null | ||
205 | }, | 205 | }, | ||
206 | { | 206 | { | ||
207 | "display_name": "Rivers", | 207 | "display_name": "Rivers", | ||
208 | "id": "9e507343-6263-49ba-b1a4-e4fd2902d311", | 208 | "id": "9e507343-6263-49ba-b1a4-e4fd2902d311", | ||
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211 | "vocabulary_id": null | 211 | "vocabulary_id": null | ||
212 | }, | 212 | }, | ||
213 | { | 213 | { | ||
214 | "display_name": "climate change", | 214 | "display_name": "climate change", | ||
215 | "id": "2e584d1c-98a9-4873-a854-88d5ea2fc466", | 215 | "id": "2e584d1c-98a9-4873-a854-88d5ea2fc466", | ||
216 | "name": "climate change", | 216 | "name": "climate change", | ||
217 | "state": "active", | 217 | "state": "active", | ||
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220 | ], | 220 | ], | ||
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224 | "title": "The effects of climate change on nutrient loading and | 224 | "title": "The effects of climate change on nutrient loading and | ||
225 | river discharge", | 225 | river discharge", | ||
226 | "type": "publication", | 226 | "type": "publication", | ||
227 | "url": null, | 227 | "url": null, | ||
228 | "version": null | 228 | "version": null | ||
229 | } | 229 | } |