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  • 1
    Online Resource
    Online Resource
    Phosgene : And Related Carbonyl Halides. (1996)
    San Diego :Elsevier Science & Technology,
    Details
    Keywords: Carbonyl halides. ; Electronic books.
    Type of Medium: Online Resource
    Pages: 1 online resource (979 pages)
    Edition: 1st ed.
    ISBN: 9780080538808
    Series Statement: Issn Series ; v.Volume 24
    URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=318376
    Language: English
    Note: Front Cover -- PHOSGENE AND RELATED CARBONYL HALIDES -- Copyright Page -- CONTENTS -- CHAPTER 1. HISTORY OF PHOSGENE -- 1.1 PHOTOGENESIS -- 1.2 QUIESCENCE -- 1.3 THE STORM APPROACHETH -- 1.4 REFINEMENTS OF EVIL -- 1.5 THE STATISTICS OF DEATH -- 1.6 THE ART OF WAR -- 1.7 PHOSGENE AND WORLD WAR II -- 1.8 PHOSGENE AND MODERN WARFARE -- 1.9 PHOSGENE AND THE MODERN WORLD -- 1.10 THE KRAKEN WAKES -- 1.11 ACCURACY AND THE PRESS -- 1.12 WHY THIS BOOK? -- CHAPTER 2. BIOLOGICAL ACTIVITY OF PHOSGENE -- 2.1 SYMPTOMS OF PHOSGENE POISONING -- 2.2 LUNG STRUCTURE AND FUNCTION -- 2.3 EFFECTS OF PHOSGENE ON THE RESPIRATORY SYSTEM -- 2.4 MEASUREMENT OF EXPOSURE DOSE -- 2.5 ANIMAL EXPERIMENTS -- 2.6 TREATMENT OF PHOSGENE POISONING -- 2.7 PHOSGENE AS A PESTICIDE -- 2.8 THE EFFECTS OF PHOSGENE ON PLANTS, SOILS AND FOODSTUFFS -- CHAPTER 3. INDUSTRIAL HYGIENE, ANALYTICAL METHODS AND ENVIRONMENTAL ISSUES -- 3.1 INDUSTRIAL HYGIENE -- 3.2 ANALYTICAL METHODS FOR THE DETERMINATION OF PHOSGENE -- 3.3 SOURCES OF PHOSGENE EMISSION -- 3.4 TREATMENT OF LIQUID PHOSGENE SPILLAGES -- 3.5 CASE REPORTS OF PHOSGENE POISONING -- 3.6 CATASTROPHIC EMISSIONS -- 3.7 ENVIRONMENTAL CONSIDERATIONS -- CHAPTER 4. INDUSTRIAL MANUFACTURE AND USES -- 4.1 INDUSTRIAL MANUFACTURE -- 4.2 PURIFICATION OF COMMERCIAL PHOSGENE -- 4.3 STORAGE -- 4.4 TREATMENT OF PHOSGENE EFFLUENTS -- 4.5 ENGINEERING PRACTICES -- 4.6 ASSAYING -- 4.7 INDUSTRIAL USES -- CHAPTER 5. SYNTHESIS AND FORMATION OF PHOSGENE -- 5.1 SYNTHESIS OF PHOSGENE FROM CARBON MONOXIDE -- 5.2 SYNTHESIS OF PHOSGENE FROM HALOGENATED HYDROCARBONS -- 5.3 SYNTHESIS OF PHOSGENE FROM CARBONACEOUS MATERIALS -- 5.4 SYNTHESIS OF PHOSGENE FROM CARBON DIOXIDE, CARBONYL SULFIDE OR CARBON DISULFIDE -- 5.5 SYNTHESIS OF PHOSGENE FROM OTHER CARBONYL HALIDES -- 5.6 SYNTHESIS OF PHOSGENE FROM OXYGENATES (OXYGEN-CONTAINING ORGANIC COMPOUNDS). , 5.7 SYNTHESIS OF PHOSGENE BY MISCELLANEOUS METHODS -- 5.8 SYNTHESIS OF LABELLED PHOSGENE -- CHAPTER 6. THERMODYNAMIC AND PHYSICAL PROPERTIES -- 6.1 THERMOCHEMICAL PROPERTIES -- 6.2 THERMAL PROPERTIES -- 6.3 MECHANICAL PROPERTIES -- 6.4 OPTICAL PROPERTIES -- 6.5 ELECTRICAL AND MAGNETIC PROPERTIES -- 6.6 SOLUBILITY AND VAPOUR-LIQUID EQUILIBRIA -- CHAPTER 7. STRUCTURAL AND SPECTROSCOPIC PROPERTIES -- 7.1 STRUCTURAL DETERMINATIONS -- 7.2 VIBRATIONAL SPECTROSCOPY -- 7.3 NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY -- 7.4 NUCLEAR QUADRUPOLE RESONANCE SPECTROSCOPY -- 7.5 MASS SPECTROMETRY -- CHAPTER 8. DISSOCIATION, DISMUTATION AND PHOTOCHEMISTRY OF PHOSGENE -- 8.1 DISSOCIATION OF PHOSGENE -- 8.2 DISMUTATION OF PHOSGENE -- 8.3 PHOTOCHEMISTRY OF PHOSGENE -- CHAPTER 9. REACTIONS WITH INORGANIC COMPOUNDS -- 9.1 MAIN GROUP HALIDES AND OXIDE HALIDES -- 9.2 TRANSITION METAL HALIDES AND OXIDE HALIDES -- 9.3 LANTHANIDE AND ACTINIDE HALIDES AND OXIDE HALIDES -- 9.4 MAIN GROUP OXIDES AND SULFIDES -- 9.5 TRANSITION METAL OXIDES AND SULFIDES -- 9.6 LANTHANIDE AND ACTINIDE OXIDES -- 9.7 MAIN GROUP ELEMENTS -- 9.8 TRANSITION ELEMENTS AND ACTINIDES -- 9.9 ORGANOMETALLICS -- 9.10 HYDRIDE DERIVATIVES -- 9.11 AMIDES -- 9.12 MISCELLANEOUS REACTIONS -- 9.13 PHOSGENITE -- CHAPTER 10. REACTIONS WITH ORGANIC COMPOUNDS -- 10.1 REACTIONS WITH HYDROCARBONS -- 10.2 REACTIONS WITH NITROGEN COMPOUNDS -- 10.3 REACTIONS WITH OXYGEN COMPOUNDS -- 10.4 REACTIONS WITH ORGANOSILICON COMPOUNDS -- 10.5 REACTIONS WITH ORGANOPHOSPHORUS AND RELATED COMPOUNDS -- 10.6 REACTIONS WITH ORGANOSULFUR COMPOUNDS -- 10.7 POLYMER CHEMISTRY -- 10.8 SYNTHESIS OF RADIOLABELLED COMPOUNDS -- CHAPTER 11. PHOSGENE AS A NON-AQUEOUS SOLVENT -- 11.1 PHYSICAL PROPERTIES OF LIQUID PHOSGENE -- 11.2 CONDUCTIVITY OF LIQUID PHOSGENE -- 11.3 PHOSGENE AS A NON-AQUEOUS SOLVENT -- CHAPTER 12. PHOSGENE SUBSTITUTES AND HOMOLOGUES. , 12.1 PHOSGENE SUBSTITUTES -- 12.2 HOMOLOGUES -- CHAPTER 13. CARBONYL DIFLUORIDE -- 13.1 BIOLOGICAL ACTIVITY OF CARBONYL DIFLUORIDE -- 13.2 INDUSTRIAL HYGIENE -- 13.3 ANALYTICAL METHODS FOR THE DETERMINATION OF CARBONYL DIFLUORIDE -- 13.4 TYPICAL ASSAY OF COMMERCIAL CARBONYL DIFLUORIDE -- 13.5 ENVIRONMENTAL CONSIDERATIONS -- 13.6 POTENTIAL USES OF CARBONYL DIFLUORIDE -- 13.7 SYNTHESIS AND FORMATION OF CARBONYL DIFLUORIDE -- 13.8 THERMODYNAMIC AND PHYSICAL PROPERTIES -- 13.9 STRUCTURAL DETERMINATIONS -- 13.10 SPECTROSCOPY -- 13.11 THERMAL DECOMPOSITION -- 13.12 PHOTOCHEMICAL DECOMPOSITION -- 13.13 REACTIONS WITH INORGANIC COMPOUNDS -- 13.14 REACTIONS WITH ORGANIC COMPOUNDS -- CHAPTER 14. CARBONYL DIBROMIDE -- 14.1 BIOLOGICAL ACTIVITY -- 14.2 ENVIRONMENTAL HAZARDS -- 14.3 FORMATION -- 14.4 THERMODYNAMIC AND PHYSICAL PROPERTIES -- 14.5 STRUCTURAL AND SPECTROSCOPIC PROPERTIES -- 14.6 REACTIONS WITH INORGANIC COMPOUNDS -- 14.7 REACTIONS WITH ORGANIC COMPOUNDS -- CHAPTER 15. CARBONYL DIIODIDE -- 15.1 EVIDENCE FOR THE PRESENCE OF CARBONYL DIIODIDE IN THE ESSENTIAL OIL OF Asparagopsis taxiformis -- 15.2 ATTEMPTED SYNTHESES OF CARBONYL DIIODIDE -- 15.3 ESTIMATED PHYSICAL AND THERMODYNAMIC PROPERTIES FOR CARBONYL DIIODIDE -- CHAPTER 16. ASYMMETRIC CARBONYL HALIDES -- 16.1 CARBONYL CHLORIDE FLUORIDE -- 16.2 CARBONYL BROMIDE FLUORIDE -- 16.3 CARBONYL BROMIDE CHLORIDE -- 16.4 CARBONYL FLUORIDE IODIDE -- 16.5 CARBONYL CHLORIDE IODIDE -- 16.6 CARBONYL BROMIDE IODIDE -- CHAPTER 17. ELECTRONIC STRUCTURE OF THE CARBONYL HALIDES -- 17.1 THEORETICAL DESCRIPTIONS OF THE ELECTRONIC STRUCTURE OF THE CARBONYL HALIDES -- 17.2 PHOTOELECTRON STUDIES -- 17.3 ELECTRONIC ABSORPTION -- 17.4 FLUORESCENCE -- 17.5 PHOSPHORESCENCE -- 17.6 REACTIVITY PATTERNS -- REFERENCES -- I.C.I. REPORTS -- APPENDICES -- A1 PHOSGENE: INDUSTRIAL OUTPUT. , A2 CARBONYL HALIDES: SUPPLIERS OF RESEARCH QUANTITIES -- A3 REGISTRY NUMBERS AND SYNONYMS -- A4 CHARACTER TABLES (C2v and Cs) -- A5 LABORATORY PREPARATIONS OF THE CARBONYL HALIDES -- INDEX.
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  • 2
    Online Resource
    Online Resource
    Complete Science Communication : A Guide to Connecting with Scientists, Journalists and the Public. (2018)
    La Vergne :Royal Society of Chemistry, The,
    Details
    Keywords: Electronic books.
    Description / Table of Contents: Authored by a highly regarded chemist and science communicator, this textbook pulls together all aspects of science communication.
    Type of Medium: Online Resource
    Pages: 1 online resource (147 pages)
    Edition: 1st ed.
    ISBN: 9781788015486
    URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=31227342
    DDC: 501.4
    Language: English
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  • 3
    Online Resource
    Online Resource
    Complete Science Communication : A Guide to Connecting with Scientists, Journalists and the Public. (2018)
    La Vergne :RSC,
    Details
    Keywords: Electronic books.
    Description / Table of Contents: Authored by a highly regarded chemist and science communicator, this textbook pulls together all aspects of science communication.
    Type of Medium: Online Resource
    Pages: 1 online resource (193 pages)
    Edition: 1st ed.
    ISBN: 9781788015486
    URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=7424968
    Language: English
    Note: Intro -- Half Title -- Title -- Copyright -- Preface -- Acknowledgements -- Contents -- 1 The Art and Motivation of Science Communication 1 -- 1.1 Introduction -- 1.2 The Written Word -- 1.3 Communication -- 1.4 Deciphering Science/Choosing an Audience -- 1.5 Assignments -- 1.5.1 Science in Entertainment Media -- 1.5.2 The Nightly News -- 2 Writing Science Through the Tenets of Journalism 12 -- 2.1 Introduction -- 2.2 The Inverted Pyramid -- 2.3 The 5 Ws of Journalism -- 2.4 Style Including the 3 Cs of Science Journalism -- 2.5 Sources -- 2.6 Interviews, Interviewing, and Being Interviewed -- 2.7 Length, Audience, and Media: Old and New -- 2.8 Assignments -- 2.8.1 The Lead -- 2.8.2 First Journalistic Style Piece -- 2.8.3 Peer-review -- 2.8.4 Second Journalistic Style Piece -- 2.8.5 Interview Article -- 2.8.6 Story Idea Meeting -- 2.8.7 Final Article -- 2.9 Examples -- 2.9.1 The Intersection of Biology, Chemistry, and History -- 2.9.2 Honey Bees and Cerium Oxide -- 2.9.3 Malaria Work Restarted -- 2.10 Student Examples -- 2.10.1 Award Notification -- 2.10.2 Chemical Spill -- 3 Writing Technical Science Like a Journalist 37 -- 3.1 Introduction -- 3.2 Writing Abstracts -- 3.2.1 Sample Abstracts -- 3.3 The Four Major Parts of a Scientific Article -- 3.3.1 Sample Results Section -- 3.4 Writing the Introduction and Utilizing the Scientific Literature -- 3.4.1 Introduction Example -- 3.4.2 Sample Conclusions -- 3.5 Telling an Effective Story -- 3.6 The Peer Review Process -- 3.7 Emerging Trends in Publishing and Writing Technically Without Peer Review -- 3.8 Assignments -- 3.8.1 Poetry -- 3.8.2 Reading Abstracts -- 3.8.3 Writing the Abstract -- 3.8.4 Writing the Methods and Results Sections -- 3.8.5 Writing the Introduction While Building the Discussion -- 3.8.6 Full Paper -- References -- 4 Speaking (not) Like a Scientist 67 -- 4.1 Introduction. , 4.2 The Art of Presenting -- 4.3 Structure of the Presentation -- 4.3.1 Setting -- 4.3.2 Rising Action and Climax -- 4.3.3 Resolution -- 4.4 The Visual Aid: The Campfire -- 4.5 Sample Presentation -- 4.5.1 Setting -- 4.5.2 Rising Action -- 4.5.3 The False Climax and Continuation of the Rising Action -- 4.5.4 Climax and Falling Action -- 4.5.5 Resolution and Ending -- 4.6 Assignments -- 4.6.1 TED Talks -- 4.6.2 First Presentation -- 4.6.3 Second Presentation -- 4.6.4 Final Presentation -- 5 The More Common Presentation, the Poster 112 -- 5.1 Introduction -- 5.2 The Conversation -- 5.3 Cues from Art -- 5.4 Layout and Coloring -- 5.5 The Actual Poster -- 5.6 The Future of Poster Presentations -- 5.7 Final Considerations -- 5.8 Assignments -- 5.8.1 Poster from the Literature -- 5.8.2 Poster Presentation -- 5.8.3 Final Poster Presentation -- 6 Public Relations and Marketing, The Synthesis of Science Communication 128 -- 6.1 Introduction: The Role of Public Relations for Science -- 6.2 Publics and Audience -- 6.3 The ROPE Method -- 6.3.1 Research -- 6.3.2 Objectives -- 6.3.3 Programming -- 6.3.4 Evaluation -- 6.4 The Public Relations Plan -- 6.5 Sample Press Releases -- 6.5.1 Nitrogen Grabbed -- 6.5.2 Anions in Space -- 6.6 Assignments -- 6.6.1 Annotated Event Budget -- 6.6.2 Public Relations Plan -- 6.7 Sample Public Relations Plan -- Subject Index.
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  • 4
    Online Resource
    Online Resource
    Community Forestry : Local Values, Conflict and Forest Governance. (2012)
    Cambridge :Cambridge University Press,
    Details
    Keywords: Forest management -- Political aspects. ; Electronic books.
    Description / Table of Contents: Providing an incisive examination of community forestry, this book highlights both the possibilities and challenges associated with its implementation. It studies complex issues in local forest governance, community sustainability and grassroots environmentalism, with compelling case studies and accounts from those directly involved with community forestry efforts in a pan-national context.
    Type of Medium: Online Resource
    Pages: 1 online resource (194 pages)
    Edition: 1st ed.
    ISBN: 9781139627870
    URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=1099786
    DDC: 333.75
    Language: English
    Note: Cover -- Community Forestry: Local Values, Conflict and Forest Governance -- Title -- Copyright -- Contents -- Acknowledgements -- 1 Defining concepts and spaces for the re-emergence of community forestry -- INTRODUCTION -- COMMUNITIES AND FORESTS -- COMMUNITY FORESTRY, COMMUNITY FORESTS AND COMMUNITY-BASED FORESTRY -- COMMUNITY(IES) -- CAVEATS -- THE ROAD AHEAD -- REFERENCES -- 2 Putting community forestry into place: implementation and conflict -- THE IMPLEMENTATION CHALLENGE -- THE CHARACTER OF CONFLICT -- CONFLICT AS A DYNAMIC ELEMENT IN COMMUNITY FOREST GOVERNANCE -- Communicative -- Personal dynamics (values, beliefs and interests) -- REFERENCES -- 3 Keeping New England's forests common -- COMMUNAL FORESTS -- THE "TOWN FOREST" MOVEMENT -- CONSERVING OPEN SPACE THROUGH PUBLIC-PRIVATE-CIVIC COLLABORATION -- The Freedom Town Forest, New Hampshire -- (Bruce) Lacroix Farm and Family Forest, Moretown, Vermont -- SUMMARY -- NOTE -- REFERENCES -- 4 Experiments and false starts: Ontario's community forestry experience -- APPROACHES TO COMMUNITY FORESTRY IN ONTARIO -- The Agreement Forest Program, 1922-2001 -- The Algonquin Forest Authority/Agence de foresterie du parc Algonquin, 1974 to present -- Wendaban Stewardship Authority, 1990-1995 -- Ontario Community Forest Pilot Program, 1991-1994 -- Westwind Stewardship Incorporated, 1996 to present -- SUCCESSES AND CHALLENGES WITH COMMUNITY FORESTRY IN ONTARIO -- Lessons from experience -- NOTES -- REFERENCES -- 5 A "watershed" case for community forestry in British Columbia's interior: the Creston Valley Forest Corporation -- COMMUNITY CONTEXT, TOWN OF CRESTON, BRITISH COLUMBIA -- INTEGRATING COMMUNITY WATERSHED AND FOREST MANAGEMENT: THE EMERGENCE OF THE CRESTON VALLEY FOREST CORPORATION -- IMPLEMENTATION CHALLENGES -- Weak support -- Local competition for tenure. , Contentious area and degraded site conditions -- Weak provincial support and bureaucracy -- Unrealistic goals and objectives -- Inadequate financing and skills -- Unsupportive stumpage appraisal system -- Poor markets and no economy of scale -- Biophysical context: difficult operating area and site conditions -- CONCLUSION -- REFERENCES -- 6 Contested forests and transition in two Gulf Island communities -- CASE 1: DENMAN ISLAND -- EMERGENCE OF THE DENMAN COMMUNITY FOREST COOPERATIVE -- CASE 2: KLAHOOSE FIRST NATION AND CORTES ECOFORESTRY SOCIETY PARTNERSHIP, CORTES ISLAND -- ORIGINS OF THE KLAHOOSE FIRST NATION/CORTES ECOFORESTY SOCIETY PARTNERSHIP -- TWO ISLANDS, TWO OUTCOMES -- Community mobilization -- Land ownership and stakeholders -- Local decision-making structures and processes -- MOTIVATIONS FOR LOCAL CONTROL: NATURAL RESOURCE AND AMENITY DEVELOPMENT PRESSURE -- CONCLUSION -- NOTES -- REFERENCES -- 7 The southwestern United States: community forestry as governance -- A BRIEF HISTORY -- A STORY FROM THE US SOUTHWEST -- ACCOMPLISHMENTS AND LIMITS -- REFERENCES -- 8 Community access and the culture of stewardship in Finland and Sweden -- OWNERSHIP -- THE EVOLUTION OF SWEDISH POLICY: FROM DICTATES TO PERSUASIVE PLANNING -- FINNISH POLICY AND PLANNING: THE HIERARCHICAL DISINTEGRATION OF PARTICIPATION -- BUILDING A CULTURE OF STEWARDSHIP -- NOTES -- REFERENCES -- 9 Community forestry: a way forward -- ADDRESSING LOCAL VALUES AND CONFLICT THROUGH COMMUNITY FORESTRY -- ENGAGING COMMUNITIES IN FOREST GOVERNANCE AND DEVELOPMENT -- REFERENCES -- Index.
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  • 5
    Online Resource
    Online Resource
    Plato in the Third Sophistic. (2014)
    Boston : De Gruyter, Inc.
    Details Availability
    Keywords: Plato -- Influence ; Christian literature, Byzantine -- History and criticism ; Christian literature, Early -- History and criticism ; Christian literature, Byzantine ; History and criticism ; Christian literature, Early ; History and criticism ; Plato ; Influence ; Electronic books
    Description / Table of Contents: Millenniumpursues an interdisciplinaryapproach transcending historical eras. The international editorial board and the advisory board represent a wide range of disciplines - contributions from art and literary studies are just as welcome as historical, theological and philosophical disciplines; contributions onLatin and Greek cultures just as welcome as on Oriental cultures.
    Type of Medium: Online Resource
    Pages: 1 online resource (438 pages)
    ISBN: 9781614510390
    Series Statement: Millennium-Studien / Millennium Studies v.50
    URL: https://ebookcentral.proquest.com/lib/kxp/detail.action?docID=893103
    DDC: 184
    Language: English
    Note: Description based on publisher supplied metadata and other sources
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  • 6
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    Unknown
    Harmonized in-situ observations of surface energy fluxes and environmental drivers at 64 Arctic vegetation and glacier sites (2022)
    PANGAEA
    Details
    Publication Date: 2024-04-12
    Description: Despite the importance of surface energy budgets (SEBs) for land-climate interactions in the Arctic, uncertainties in their prediction persist. In-situ observational data of SEB components - useful for research and model validation - are collected at relatively few sites across the terrestrial Arctic, and not all available datasets are readily interoperable. Furthermore, the terrestrial Arctic consists of a diversity of vegetation types, which are generally not well represented in land surface schemes of current Earth system models. Therefore, we here provide four datasets comprising: 1. Harmonized, standardized and aggregated in situ observations of SEB components at 64 vegetated and glaciated sites north of 60° latitude, in the time period 1994-2021 2. A description of all study sites and associated environmental conditions, including the vegetation types, which correspond to the classification of the Circumpolar Arctic Vegetation Map (CAVM, Raynolds et al. 2019). 3. Data generated in a literature synthesis from 358 study sites on vegetation or glacier (〉=60°N latitude) covered by 148 publications. 4. Metadata, including data contributor information and measurement heights of variables associated with Oehri et al. 2022.
    Keywords: Arctic; ArcticTundraSEB; Arctic Tundra Surface Energy Budget; dry tundra; Eddy covariance; eddy heat flux; glacier; graminoids; ground heat flux and net radiation; harmonized data; high latitude; Land-Atmosphere; Land-cover; latent and sensible heat; latent heat flux; longwave radiation; meteorological data; observatory data; Peat bog; Radiation fluxes; Radiative energy budget; sensible heat flux; shortwave radiation; shrub tundra; surface energy balance; synthetic data; tundra vegetation; wetland
    Type: Dataset
    Format: application/zip, 4 datasets
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    DATA PANGAEA
  • 7
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    Harmonized in-situ observations of surface energy fluxes and environmental drivers at 64 Arctic vegetation and glacier sites - Environmental conditions (2022)
    PANGAEA
    Details
    Publication Date: 2024-05-05
    Description: Despite the importance of surface energy budgets (SEBs) for land-climate interactions in the Arctic, uncertainties in their prediction persist. In situ observational data of SEB components - useful for research and model validation - are collected at relatively few sites across the terrestrial Arctic, and not all available datasets are readily interoperable. Furthermore, the terrestrial Arctic consists of a diversity of vegetation types, which are generally not well represented in land surface schemes of current Earth system models. This dataset describes the environmental conditions for 64 tundra and glacier sites (〉=60°N latitude) across the Arctic, for which in situ measurements of surface energy budget components were harmonized (see Oehri et al. 2022). These environmental conditions are (proxies of) potential drivers of SEB-components and could therefore be called SEB-drivers. The associated environmental conditions, include the vegetation types graminoid tundra, prostrate dwarf-shrub tundra, erect-shrub tundra, wetland complexes, barren complexes (≤ 40% horizontal plant cover), boreal peat bogs and glacier. These land surface types (apart from boreal peat bogs) correspond to the main classification units of the Circumpolar Arctic Vegetation Map (CAVM, Raynolds et al. 2019). For each site, additional climatic and biophysical variables are available, including cloud cover, snow cover duration, permafrost characteristics, climatic conditions and topographic conditions.
    Keywords: Arctic; Arctic_SEB_CA-SCB; Arctic_SEB_CP1; Arctic_SEB_Dye-2; Arctic_SEB_EGP; Arctic_SEB_FI-Lom; Arctic_SEB_GL-NuF; Arctic_SEB_GL-ZaF; Arctic_SEB_GL-ZaH; Arctic_SEB_KAN_B; Arctic_SEB_KAN_L; Arctic_SEB_KAN_M; Arctic_SEB_KAN_U; Arctic_SEB_KPC_L; Arctic_SEB_KPC_U; Arctic_SEB_MIT; Arctic_SEB_NASA-E; Arctic_SEB_NASA-SE; Arctic_SEB_NASA-U; Arctic_SEB_NUK_K; Arctic_SEB_NUK_L; Arctic_SEB_NUK_N; Arctic_SEB_NUK_U; Arctic_SEB_QAS_A; Arctic_SEB_QAS_L; Arctic_SEB_QAS_M; Arctic_SEB_QAS_U; Arctic_SEB_RU-Che; Arctic_SEB_RU-Cok; Arctic_SEB_RU-Sam; Arctic_SEB_RU-Tks; Arctic_SEB_RU-Vrk; Arctic_SEB_Saddle; Arctic_SEB_SCO_L; Arctic_SEB_SCO_U; Arctic_SEB_SE-St1; Arctic_SEB_SJ-Adv; Arctic_SEB_SJ-Blv; Arctic_SEB_SouthDome; Arctic_SEB_Summit; Arctic_SEB_TAS_A; Arctic_SEB_TAS_L; Arctic_SEB_TAS_U; Arctic_SEB_THU_L; Arctic_SEB_THU_U; Arctic_SEB_Tunu-N; Arctic_SEB_UPE_L; Arctic_SEB_UPE_U; Arctic_SEB_US-A03; Arctic_SEB_US-A10; Arctic_SEB_US-An1; Arctic_SEB_US-An2; Arctic_SEB_US-An3; Arctic_SEB_US-Atq; Arctic_SEB_US-Brw; Arctic_SEB_US-EML; Arctic_SEB_US-HVa; Arctic_SEB_US-ICh; Arctic_SEB_US-ICs; Arctic_SEB_US-ICt; Arctic_SEB_US-Ivo; Arctic_SEB_US-NGB; Arctic_SEB_US-Upa; Arctic_SEB_US-xHE; Arctic_SEB_US-xTL; ArcticTundraSEB; Arctic Tundra Surface Energy Budget; Aspect; Aspect, coefficient of variation; Calculated average/mean values; Cloud cover; Cloud cover, standard deviation; Cloud top pressure; Cloud top pressure, standard deviation; Cloud top temperature; Cloud top temperature, standard deviation; Conrad's continentality index; Daily maximum; Daily mean; Data source; Date/Time of event; dry tundra; Eddy covariance; eddy heat flux; ELEVATION; Elevation, standard deviation; Event label; Field observation; glacier; graminoids; ground heat flux and net radiation; harmonized data; high latitude; Humidity, relative; Land-Atmosphere; Land-cover; Land cover classes; Land cover type; latent and sensible heat; latent heat flux; LATITUDE; Location ID; LONGITUDE; longwave radiation; Mean values; Median values; meteorological data; Number of vegetation types; observatory data; Peat bog; Permafrost, type; Permafrost extent; Permafrost ice content, description; Precipitation; Precipitation, coefficient of variation; Precipitation, daily, maximum; Precipitation, snow; Precipitation, sum; Pressure, atmospheric; p-value; Radiation fluxes; Radiative energy budget; Reference/source; sensible heat flux; Shannon Diversity Index; Shannon Diversity Index, maximum; shortwave radiation; shrub tundra; Site; Slope; Slope, coefficient of variation; Slope, mathematical; Snow, onset, day of the year; Snow cover, number of days; Snowfall, coefficient of variation; Snow-free days; Snow type; Soil water content, volumetric; Species present; Summer warmth index; surface energy balance; synthetic data; Temperature, air, annual mean; Temperature, air, coefficient of variation; Temperature, annual mean range; tundra vegetation; Type of study; Uniform resource locator/link to reference; Vapour pressure deficit; Vegetation type; wetland; Wind speed; Zone
    Type: Dataset
    Format: text/tab-separated-values, 4705 data points
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    DATA PANGAEA
  • 8
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    Harmonized in-situ observations of surface energy fluxes and environmental drivers at 64 Arctic vegetation and glacier sites - Metadata (2022)
    PANGAEA
    Details
    Publication Date: 2024-04-12
    Description: Despite the importance of surface energy budgets (SEBs) for land-climate interactions in the Arctic, uncertainties in their prediction persist. In situ observational data of SEB components - useful for research and model validation - are collected at relatively few sites across the terrestrial Arctic, and not all available datasets are readily interoperable. Furthermore, the terrestrial Arctic consists of a diversity of vegetation types, which are generally not well represented in land surface schemes of current Earth system models. This dataset contains metadata information about surface energy budget components measured at 64 tundra and glacier sites 〉60° N across the Arctic. This information was taken from the open-access repositories FLUXNET, Ameriflux, AON, GC-Net and PROMICE. The contained datasets are associated with the publication vegetation type as an important predictor of the Arctic Summer Land Surface Energy Budget by Oehri et al. 2022, and intended to support research of surface energy budgets and their relationship with environmental conditions, in particular vegetation characteristics across the terrestrial Arctic.
    Keywords: Aggregation type; Arctic; Arctic_SEB_CA-SCB; Arctic_SEB_CP1; Arctic_SEB_Dye-2; Arctic_SEB_EGP; Arctic_SEB_FI-Lom; Arctic_SEB_GL-NuF; Arctic_SEB_GL-ZaF; Arctic_SEB_GL-ZaH; Arctic_SEB_KAN_B; Arctic_SEB_KAN_L; Arctic_SEB_KAN_M; Arctic_SEB_KAN_U; Arctic_SEB_KPC_L; Arctic_SEB_KPC_U; Arctic_SEB_MIT; Arctic_SEB_NASA-E; Arctic_SEB_NASA-SE; Arctic_SEB_NASA-U; Arctic_SEB_NUK_K; Arctic_SEB_NUK_L; Arctic_SEB_NUK_N; Arctic_SEB_NUK_U; Arctic_SEB_QAS_A; Arctic_SEB_QAS_L; Arctic_SEB_QAS_M; Arctic_SEB_QAS_U; Arctic_SEB_RU-Che; Arctic_SEB_RU-Cok; Arctic_SEB_RU-Sam; Arctic_SEB_RU-Tks; Arctic_SEB_RU-Vrk; Arctic_SEB_Saddle; Arctic_SEB_SCO_L; Arctic_SEB_SCO_U; Arctic_SEB_SE-St1; Arctic_SEB_SJ-Adv; Arctic_SEB_SJ-Blv; Arctic_SEB_SouthDome; Arctic_SEB_Summit; Arctic_SEB_TAS_A; Arctic_SEB_TAS_L; Arctic_SEB_TAS_U; Arctic_SEB_THU_L; Arctic_SEB_THU_U; Arctic_SEB_Tunu-N; Arctic_SEB_UPE_L; Arctic_SEB_UPE_U; Arctic_SEB_US-A03; Arctic_SEB_US-A10; Arctic_SEB_US-An1; Arctic_SEB_US-An2; Arctic_SEB_US-An3; Arctic_SEB_US-Atq; Arctic_SEB_US-Brw; Arctic_SEB_US-EML; Arctic_SEB_US-HVa; Arctic_SEB_US-ICh; Arctic_SEB_US-ICs; Arctic_SEB_US-ICt; Arctic_SEB_US-Ivo; Arctic_SEB_US-NGB; Arctic_SEB_US-Upa; Arctic_SEB_US-xHE; Arctic_SEB_US-xTL; ArcticTundraSEB; Arctic Tundra Surface Energy Budget; Author(s); Data source; Date/Time of event; Day of the year; Description; dry tundra; Eddy covariance; eddy heat flux; Event label; Field observation; First year of observation; glacier; graminoids; ground heat flux and net radiation; harmonized data; high latitude; Institution; Instrument; Land-Atmosphere; Land-cover; Last year of observation; latent and sensible heat; latent heat flux; LATITUDE; Location ID; LONGITUDE; longwave radiation; meteorological data; Method comment; observatory data; Peat bog; Radiation fluxes; Radiative energy budget; Sample height; sensible heat flux; shortwave radiation; shrub tundra; surface energy balance; synthetic data; tundra vegetation; Type of study; Unit; Variable; wetland
    Type: Dataset
    Format: text/tab-separated-values, 20562 data points
    Location Call Number Limitation Availability
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  • 9
    facet.materialart.
    Unknown
    Literature synthesis data of surface energy fluxes and environmental drivers from Arctic vegetation and glacier sites (2022)
    PANGAEA
    Details
    Publication Date: 2024-04-12
    Description: Despite the importance of surface energy budgets (SEBs) for land-climate interactions in the Arctic, uncertainties in their prediction persist. In situ observational data of SEB components - useful for research and model validation - are collected at relatively few sites across the terrestrial Arctic, and not all available datasets are readily interoperable. Furthermore, the terrestrial Arctic consists of a diversity of vegetation types, which are generally not well represented in land surface schemes of current Earth system models. This dataset describes the data generated in a literature synthesis, covering 358 study sites on vegetation or glacier (〉=60°N latitude), which contained surface energy budget observations. The literature synthesis comprised 148 publications searched on the ISI Web of Science Core Collection.
    Keywords: Arctic; Arctic_SEB_1; Arctic_SEB_1951-2009_1; Arctic_SEB_1965-2000_1; Arctic_SEB_1965-2000_2; Arctic_SEB_1965-2000_3; Arctic_SEB_1965-2000_4; Arctic_SEB_1969-2013_1; Arctic_SEB_1970-1972_1; Arctic_SEB_1970-1979_1; Arctic_SEB_1972-2004_1; Arctic_SEB_1972-2004_10; Arctic_SEB_1972-2004_11; Arctic_SEB_1972-2004_2; Arctic_SEB_1972-2004_3; Arctic_SEB_1972-2004_4; Arctic_SEB_1972-2004_5; Arctic_SEB_1972-2004_6; Arctic_SEB_1972-2004_7; Arctic_SEB_1972-2004_8; Arctic_SEB_1972-2004_9; Arctic_SEB_1979-1995_1; Arctic_SEB_1979-1995_2; Arctic_SEB_1979-1995_3; Arctic_SEB_1979-1995_4; Arctic_SEB_1979-2005_1; Arctic_SEB_1980-1981_1; Arctic_SEB_1981-1997_1; Arctic_SEB_1981-1997_2; Arctic_SEB_1983-2005_1; Arctic_SEB_1983-2005_2; Arctic_SEB_1983-2005_3; Arctic_SEB_1984-1991_1; Arctic_SEB_1985-1989_1; Arctic_SEB_1985-2016_1; Arctic_SEB_1988-1988_1; Arctic_SEB_1988-1988_2; Arctic_SEB_1988-1988_3; Arctic_SEB_1988-1988_4; Arctic_SEB_1988-1988_5; Arctic_SEB_1989-1990_1; Arctic_SEB_1990-1991_1; Arctic_SEB_1991-1991_1; Arctic_SEB_1991-1999_1; Arctic_SEB_1991-1999_2; Arctic_SEB_1991-1999_3; Arctic_SEB_1992-1992_1; Arctic_SEB_1992-1997_1; Arctic_SEB_1994-1994_1; Arctic_SEB_1994-1994_2; Arctic_SEB_1994-1994_3; Arctic_SEB_1994-1994_4; Arctic_SEB_1994-1996_1; Arctic_SEB_1994-1996_10; Arctic_SEB_1994-1996_11; Arctic_SEB_1994-1996_12; Arctic_SEB_1994-1996_13; Arctic_SEB_1994-1996_14; Arctic_SEB_1994-1996_15; Arctic_SEB_1994-1996_16; Arctic_SEB_1994-1996_17; Arctic_SEB_1994-1996_2; Arctic_SEB_1994-1996_3; Arctic_SEB_1994-1996_4; Arctic_SEB_1994-1996_5; Arctic_SEB_1994-1996_6; Arctic_SEB_1994-1996_7; Arctic_SEB_1994-1996_8; Arctic_SEB_1994-1996_9; Arctic_SEB_1994-2008_1; Arctic_SEB_1994-2008_2; Arctic_SEB_1994-2009_1; Arctic_SEB_1994-2015_1; Arctic_SEB_1994-2015_2; Arctic_SEB_1994-2015_3; Arctic_SEB_1994-2015_4; Arctic_SEB_1994-2015_5; Arctic_SEB_1994-2015_6; Arctic_SEB_1995-1995_1; Arctic_SEB_1995-1995_2; Arctic_SEB_1995-1996_1; Arctic_SEB_1995-1997_1; Arctic_SEB_1995-1997_2; Arctic_SEB_1995-1997_3; Arctic_SEB_1995-1997_4; Arctic_SEB_1995-1998_1; Arctic_SEB_1995-1999_1; Arctic_SEB_1996-1997_1; Arctic_SEB_1996-1999_1; Arctic_SEB_1996-2005_1; Arctic_SEB_1996-2005_2; Arctic_SEB_1996-2005_3; Arctic_SEB_1997-1998_1; Arctic_SEB_1997-1999_1; Arctic_SEB_1997-2018_1; Arctic_SEB_1997-2018_10; Arctic_SEB_1997-2018_11; Arctic_SEB_1997-2018_12; Arctic_SEB_1997-2018_13; Arctic_SEB_1997-2018_14; Arctic_SEB_1997-2018_15; Arctic_SEB_1997-2018_16; Arctic_SEB_1997-2018_17; Arctic_SEB_1997-2018_18; Arctic_SEB_1997-2018_19; Arctic_SEB_1997-2018_2; Arctic_SEB_1997-2018_20; Arctic_SEB_1997-2018_21; Arctic_SEB_1997-2018_22; Arctic_SEB_1997-2018_23; Arctic_SEB_1997-2018_24; Arctic_SEB_1997-2018_25; Arctic_SEB_1997-2018_3; Arctic_SEB_1997-2018_4; Arctic_SEB_1997-2018_5; Arctic_SEB_1997-2018_6; Arctic_SEB_1997-2018_7; Arctic_SEB_1997-2018_8; Arctic_SEB_1997-2018_9; Arctic_SEB_1998-1998_1; Arctic_SEB_1998-1999_1; Arctic_SEB_1998-2000_1; Arctic_SEB_1998-2001_1; Arctic_SEB_1998-2005_1; Arctic_SEB_1998-2011_1; Arctic_SEB_1998-2011_2; Arctic_SEB_1998-2011_3; Arctic_SEB_1998-2013_1; Arctic_SEB_1999-1999_1; Arctic_SEB_1999-2000_1; Arctic_SEB_1999-2008_1; Arctic_SEB_1999-2008_2; Arctic_SEB_1999-2009_1; Arctic_SEB_1999-2014_1; Arctic_SEB_2000-2000_1; Arctic_SEB_2000-2000_2; Arctic_SEB_2000-2000_3; Arctic_SEB_2000-2000_4; Arctic_SEB_2000-2002_1; Arctic_SEB_2000-2002_2; Arctic_SEB_2000-2002_3; Arctic_SEB_2000-2003_1; Arctic_SEB_2000-2003_2; Arctic_SEB_2000-2003_3; Arctic_SEB_2000-2007_1; Arctic_SEB_2000-2007_2; Arctic_SEB_2000-2007_3; Arctic_SEB_2000-2007_4; Arctic_SEB_2000-2008_1; Arctic_SEB_2000-2010_1; Arctic_SEB_2000-2011_1; Arctic_SEB_2000-2011_10; Arctic_SEB_2000-2011_11; Arctic_SEB_2000-2011_2; Arctic_SEB_2000-2011_3; Arctic_SEB_2000-2011_4; Arctic_SEB_2000-2011_5; Arctic_SEB_2000-2011_6; Arctic_SEB_2000-2011_7; Arctic_SEB_2000-2011_8; Arctic_SEB_2000-2011_9; Arctic_SEB_2000-2014_1; Arctic_SEB_2001-2003_1; Arctic_SEB_2002-2002_1; Arctic_SEB_2002-2003_1; Arctic_SEB_2002-2003_2; Arctic_SEB_2002-2004_1; Arctic_SEB_2002-2010_1; Arctic_SEB_2002-2012_1; Arctic_SEB_2002-2012_2; Arctic_SEB_2002-2012_3; Arctic_SEB_2003-2003_1; Arctic_SEB_2003-2004_1; Arctic_SEB_2003-2007_1; Arctic_SEB_2003-2008_1; Arctic_SEB_2003-2008_2; Arctic_SEB_2003-2010_1; Arctic_SEB_2003-2010_2; Arctic_SEB_2003-2010_3; Arctic_SEB_2003-2011_1; Arctic_SEB_2004-2004_1; Arctic_SEB_2004-2006_1; Arctic_SEB_2004-2013_1; Arctic_SEB_2005-2005_1; Arctic_SEB_2006-2006_1; Arctic_SEB_2006-2006_2; Arctic_SEB_2006-2007_1; Arctic_SEB_2006-2007_10; Arctic_SEB_2006-2007_11; Arctic_SEB_2006-2007_12; Arctic_SEB_2006-2007_13; Arctic_SEB_2006-2007_14; Arctic_SEB_2006-2007_2; Arctic_SEB_2006-2007_3; Arctic_SEB_2006-2007_4; Arctic_SEB_2006-2007_5; Arctic_SEB_2006-2007_6; Arctic_SEB_2006-2007_7; Arctic_SEB_2006-2007_8; Arctic_SEB_2006-2007_9; Arctic_SEB_2006-2008_1; Arctic_SEB_2006-2008_2; Arctic_SEB_2006-2009_1; Arctic_SEB_2007-2007_1; Arctic_SEB_2007-2008_1; Arctic_SEB_2007-2009_1; Arctic_SEB_2007-2009_2; Arctic_SEB_2007-2010_1; Arctic_SEB_2007-2014_1; Arctic_SEB_2007-2015_1; Arctic_SEB_2007-2015_2; Arctic_SEB_2008-2008_1; Arctic_SEB_2008-2008_2; Arctic_SEB_2008-2008_3; Arctic_SEB_2008-2009_1; Arctic_SEB_2008-2010_1; Arctic_SEB_2008-2010_2; Arctic_SEB_2008-2010_3; Arctic_SEB_2008-2011_1; Arctic_SEB_2008-2012_1; Arctic_SEB_2008-2012_2; Arctic_SEB_2008-2012_3; Arctic_SEB_2009-2012_1; Arctic_SEB_2009-2012_2; Arctic_SEB_2009-2012_3; Arctic_SEB_2009-2012_4; Arctic_SEB_2009-2012_5; Arctic_SEB_2009-2014_1; Arctic_SEB_2009-2014_2; Arctic_SEB_2010-2014_1; Arctic_SEB_2010-2014_2; Arctic_SEB_2010-2014_3; Arctic_SEB_2010-2014_4; Arctic_SEB_2010-2014_5; Arctic_SEB_2011-2011_1; Arctic_SEB_2011-2013_1; Arctic_SEB_2011-2014_1; Arctic_SEB_2012-2012_1; Arctic_SEB_2012-2013_1; Arctic_SEB_2012-2013_2; Arctic_SEB_2012-2013_3; Arctic_SEB_2012-2013_4; Arctic_SEB_2012-2014_1; Arctic_SEB_2012-2015_1; Arctic_SEB_2012-2015_2; Arctic_SEB_2012-2015_3; Arctic_SEB_2012-2015_4; Arctic_SEB_2012-2015_5; Arctic_SEB_2013-2013_1; Arctic_SEB_2013-2014_1; Arctic_SEB_2013-2015_1; Arctic_SEB_2013-2015_2; Arctic_SEB_2013-2015_3; Arctic_SEB_2014-2014_1; Arctic_SEB_2014-2015_1; Arctic_SEB_2014-2016_1; Arctic_SEB_2015-2015_1; Arctic_SEB_2015-2015_2; Arctic_SEB_2015-2015_3; ArcticTundraSEB; Arctic Tundra Surface Energy Budget; Author(s); Classification; Comment; Data collection methodology; Data type; Date/Time of event; dry tundra; Eddy covariance; eddy heat flux; ELEVATION; Energy budget, description; Event label; Field observation; First year of observation; glacier; glaciers; graminoids; ground heat flux and net radiation; harmonized data; high latitude; Identification; Journal/report title; Land-Atmosphere; Land-cover; Last year of observation; latent and sensible heat; latent heat flux; LATITUDE; Location; LONGITUDE; longwave radiation; meteorological data; observatory data; Peat bog; Persistent Identifier; Publication type; Radiation fluxes; Radiative energy budget; Resolution; Season; sensible heat flux; shortwave radiation; shrub tundra; Spatial coverage; surface energy balance; synthetic data; Title; tundra vegetation; Type of study; Variable; Vegetation type; wetland; wetlands; Year of publication
    Type: Dataset
    Format: text/tab-separated-values, 8650 data points
    Location Call Number Limitation Availability
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  • 10
    facet.materialart.
    Unknown
    Harmonized in-situ observations of surface energy fluxes and environmental drivers at 64 Arctic vegetation and glacier sites - Surface energy budget componenent data (2022)
    PANGAEA
    Details
    Publication Date: 2024-04-12
    Description: Despite the importance of surface energy budgets (SEBs) for land-climate interactions in the Arctic, uncertainties in their prediction persist. In situ observational data of SEB components - useful for research and model validation - are collected at relatively few sites across the terrestrial Arctic, and not all available datasets are readily interoperable. Furthermore, the terrestrial Arctic consists of a diversity of vegetation types, which are generally not well represented in land surface schemes of current Earth system models. This dataset comprises harmonized, standardized and aggregated in-situ observations of surface energy budget components measured at 64 sites on vegetated and glaciated sites north of 60° latitude, in the time period from 1994 till 2021. The surface energy budget components include net radiation, sensible heat flux, latent heat flux, ground heat flux, net shortwave radiation, net longwave radiation, surface temperature and albedo, which were aggregated to daily mean, minimum and maximum values from hourly and half-hourly measurements. Data were retrieved from the monitoring networks FLUXNET, AmeriFlux, AON, GC-Net and PROMICE.
    Keywords: Albedo; Albedo, maximum; Albedo, minimum; Arctic; Arctic_SEB_CA-SCB; Arctic_SEB_CP1; Arctic_SEB_Dye-2; Arctic_SEB_EGP; Arctic_SEB_FI-Lom; Arctic_SEB_GL-NuF; Arctic_SEB_GL-ZaF; Arctic_SEB_GL-ZaH; Arctic_SEB_KAN_B; Arctic_SEB_KAN_L; Arctic_SEB_KAN_M; Arctic_SEB_KAN_U; Arctic_SEB_KPC_L; Arctic_SEB_KPC_U; Arctic_SEB_MIT; Arctic_SEB_NASA-E; Arctic_SEB_NASA-SE; Arctic_SEB_NASA-U; Arctic_SEB_NUK_K; Arctic_SEB_NUK_L; Arctic_SEB_NUK_N; Arctic_SEB_NUK_U; Arctic_SEB_QAS_A; Arctic_SEB_QAS_L; Arctic_SEB_QAS_M; Arctic_SEB_QAS_U; Arctic_SEB_RU-Che; Arctic_SEB_RU-Cok; Arctic_SEB_RU-Sam; Arctic_SEB_RU-Tks; Arctic_SEB_RU-Vrk; Arctic_SEB_Saddle; Arctic_SEB_SCO_L; Arctic_SEB_SCO_U; Arctic_SEB_SE-St1; Arctic_SEB_SJ-Adv; Arctic_SEB_SJ-Blv; Arctic_SEB_SouthDome; Arctic_SEB_Summit; Arctic_SEB_TAS_A; Arctic_SEB_TAS_L; Arctic_SEB_TAS_U; Arctic_SEB_THU_L; Arctic_SEB_THU_U; Arctic_SEB_Tunu-N; Arctic_SEB_UPE_L; Arctic_SEB_UPE_U; Arctic_SEB_US-A03; Arctic_SEB_US-A10; Arctic_SEB_US-An1; Arctic_SEB_US-An2; Arctic_SEB_US-An3; Arctic_SEB_US-Atq; Arctic_SEB_US-Brw; Arctic_SEB_US-EML; Arctic_SEB_US-HVa; Arctic_SEB_US-ICh; Arctic_SEB_US-ICs; Arctic_SEB_US-ICt; Arctic_SEB_US-Ivo; Arctic_SEB_US-NGB; Arctic_SEB_US-Upa; Arctic_SEB_US-xHE; Arctic_SEB_US-xTL; ArcticTundraSEB; Arctic Tundra Surface Energy Budget; Bowen ratio; Calculated from Ground heat, flux / Net radiation; Calculated from Heat, flux, latent / Net radiation; Calculated from Heat, flux, sensible / Heat, flux, latent; Calculated from Heat, flux, sensible / Net radiation; Calculated from Heat, flux, sensible + Heat, flux, latent + Ground heat, flux; Calculated from Long-wave downward radiation, maximum - Long-wave upward radiation, maximum; Calculated from Long-wave downward radiation, minimum - Long-wave upward radiation, minimum; Calculated from Long-wave downward radiation - Long-wave upward radiation; Calculated from Long-wave net radiation / Net radiation; Calculated from Short-wave downward (GLOBAL) radiation, maximum - Short-wave upward (REFLEX) radiation, maximum; Calculated from Short-wave downward (GLOBAL) radiation, minimum - Short-wave upward (REFLEX) radiation, minimum; Calculated from Short-wave downward (GLOBAL) radiation - Short-wave upward (REFLEX) radiation; Calculated from Short-wave net radiation, maximum + Long-wave net radiation, maximum; Calculated from Short-wave net radiation, minimum + Long-wave net radiation, minimum; Calculated from Short-wave net radiation / Net radiation; Calculated from Short-wave net radiation + Long-wave net radiation; Calculated from Short-wave upward (REFLEX) radiation / Short-wave downward (GLOBAL) radiation; Calculated from Surface temperature, maximum - Temperature, air, maximum; Calculated from Surface temperature, minimum - Temperature, air, minimum; Calculated from Surface temperature - Temperature, air; Cloud coverage; Cloud coverage, maximum; Cloud coverage, minimum; Daily maximum; Daily mean; Daily minimum; Data source; DATE/TIME; Day of the year; dry tundra; Eddy covariance; eddy heat flux; ELEVATION; Event label; Field observation; glacier; graminoids; Ground heat, flux; Ground heat, flux, maximum; Ground heat, flux, minimum; Ground heat, flux/Net radiation ratio; ground heat flux and net radiation; harmonized data; Heat, flux, latent; Heat, flux, latent, maximum; Heat, flux, latent, minimum; Heat, flux, latent/Net radiation ratio; Heat, flux, sensible; Heat, flux, sensible, maximum; Heat, flux, sensible, minimum; Heat flux, sensible/Net radiation ratio; high latitude; Humidity, relative; Humidity, relative, maximum; Humidity, relative, minimum; Land-Atmosphere; Land-cover; latent and sensible heat; latent heat flux; LATITUDE; Location ID; LONGITUDE; Long-wave downward radiation; Long-wave downward radiation, maximum; Long-wave downward radiation, minimum; Long-wave net radiation; Long-wave net radiation, maximum; Long-wave net radiation, minimum; Long-wave net radiation/Net radiation ratio; longwave radiation; Long-wave upward radiation; Long-wave upward radiation, maximum; Long-wave upward radiation, minimum; meteorological data; Month; Net radiation; Net radiation, maximum; Net radiation, minimum; Normalized by X / Potential incoming solar radiation, maximum * 100; observatory data; Original variable; Peat bog; Potential incoming solar radiation; Potential incoming solar radiation, maximum; Potential incoming solar radiation, minimum; Precipitation; Precipitation, daily, maximum; Precipitation, daily, minimum; Pressure, atmospheric; Pressure, atmospheric, maximum; Pressure, atmospheric, minimum; Radiation fluxes; Radiative energy budget; sensible heat flux; Short-wave downward (GLOBAL) radiation; Short-wave downward (GLOBAL) radiation, maximum; Short-wave downward (GLOBAL) radiation, minimum; Short-wave net radiation; Short-wave net radiation, maximum; Short-wave net radiation, minimum; Short-wave net radiation/Net radiation ratio; shortwave radiation; Short-wave upward (REFLEX) radiation; Short-wave upward (REFLEX) radiation, maximum; Short-wave upward (REFLEX) radiation, minimum; shrub tundra; Soil water content, volumetric; Soil water content, volumetric, maximum; Soil water content, volumetric, minimum; surface energy balance; Surface temperature; Surface temperature, maximum; Surface temperature, minimum; synthetic data; Temperature, air; Temperature, air, maximum; Temperature, air, minimum; Temperature, soil; Temperature, soil, maximum; Temperature, soil, minimum; Temperature gradient, 0-2m above surface; Temperature gradient, 0-2m above surface, maximum; Temperature gradient, 0-2m above surface, minimum; tundra vegetation; Type of study; Vapour pressure deficit; Vapour pressure deficit, maximum; Vapour pressure deficit, minimum; wetland; Wind direction; Wind speed; Wind speed, maximum; Wind speed, minimum; Year of observation
    Type: Dataset
    Format: text/tab-separated-values, 17112737 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
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