Item talk:Q46451
From geokb
{
"USGS Staff Profile": {
"@context": "https://schema.org",
"@type": "Person",
"dateModified": "2024-09-21T07:56:17.393235",
"name": "Edmund E Grote",
"identifier": [
{
"@type": "PropertyValue",
"propertyID": "ORCID",
"value": "0000-0002-9103-9482"
}
],
"jobTitle": "Biologist",
"hasOccupation": [
{
"@type": "OrganizationalRole",
"startDate": "2024-09-21T07:56:17.399853",
"affiliatedOrganization": {
"@type": "Organization",
"name": "Southwest Biological Science Center",
"url": "https://www.usgs.gov/centers/southwest-biological-science-center"
},
"roleName": "Biologist"
},
{
"@type": "Occupation",
"additionalType": "self-claimed professional experience",
"name": "1999 - present: Biologist, USGS, Southwest Biological Science Center, Moab, UT"
},
{
"@type": "Occupation",
"additionalType": "self-claimed professional experience",
"name": "1997 - 1999: Research Technician, Cornell University, Ithaca, NY"
},
{
"@type": "Occupation",
"additionalType": "self-claimed professional experience",
"name": "1996 - 1997: Research Technician, Universidad de La Serena, La Serena, Chile"
},
{
"@type": "Occupation",
"additionalType": "self-claimed professional experience",
"name": "1995 - 1996: Research Technician, Cornell University, Ithaca, NY"
}
],
"description": [
{
"@type": "TextObject",
"additionalType": "short description",
"abstract": "Biologist with the Southwest Biological Science Center"
},
{
"@type": "TextObject",
"additionalType": "staff profile page introductory statement",
"abstract": "Ed is a Biologist with the Southwest Biological Science Center based out of the Canyonlands Research Station in Moab, Utah. He spends his days setting up and tinkering with large micrometeorological and soil sensor arrays throughout the Colorado Plateau and points beyond."
},
{
"@type": "TextObject",
"additionalType": "personal statement",
"abstract": "Ed received his BA in Plant Biology from the University of Utah in Salt Lake City. While an undergrad he worked in the Ehleringer Lab, mostly with stable isotope mass spectrometers at SIRFER and it was there that he was introduced to the world of plant ecophysiology and all of its fun, electronic gadgets. Ed then spent two years working in a chemistry lab at Native Plants Inc. doing HPLC and GC methods-development, creating assays for various natural product extracts from neem seeds and pyrethrum daisies. From there he went on to pursue an MA in Plant Ecophysiology from the University of Colorado in Boulder running gas exchange and nitrogen fixation experiments on alpine clovers from Niwot Ridge. He worked for several years at Cornell University in the Dawson Lab doing physiology experiments while climbing around in the tops of sugar maple trees, as well as methods-development for the newly formed Cornell University Stable Isotope Lab. In the middle of his years back in lush, green, rainy, upstate New York, he took a hiatus and spent a year working with high alpine and Atacama Desert plants at the Universidad de La Serena in Chile in the Squeo Lab. Longing to return to the desert southwest, he found his niche within the US Geological Survey in Moab, UT. Who knew the USGS had biologists and ecologists, not just geologists and mappers? And they are doing amazing scientific research on all kinds of stuff. He was initially hired to create a gas exchange system to concurrently measure carbon dioxide exchange and nitrogen fixation on biological soil crust organisms. It turns out that these biocrust organisms can do many of the same things (and more) that plants can do. However, unlike most plants, biocrusts can completely dry out and, later, when it rains or snows, come back to life and do it all over again. Over the years Ed has set up several automated gas exchange systems which measure soil crust CO2 fluxes. He set up an Eddy Flux tower to measure CO2 flux at a landscape scale in a desert ecosystem. He has also helped design, set up and maintain long-term climate change experiments, some with dozens of temperature-controlled plots simulating warmer future climate conditions and others simulating a potentially drier future climate. All of these experimental setups require constant monitoring and maintenance of thousands of sensors measuring soil moisture, temperature, wind, light, pressure, precipitation, and the associated telemetry systems used to collect their data. As a plant ecophysiologist, Ed finds this type of work not only to be engaging and exciting, but also a lot of fun. On his time off he also enjoys backcountry skiing, mountain biking, hiking, or whitewater rafting among many other outdoor activities."
}
],
"email": "ed_grote@usgs.gov",
"url": "https://www.usgs.gov/staff-profiles/edmund-e-grote",
"affiliation": [],
"hasCredential": [
{
"@type": "EducationalOccupationalCredential",
"name": "M.A., 1995: University of Colorado, Boulder, CO. Major: Plant Physiological Ecology"
},
{
"@type": "EducationalOccupationalCredential",
"name": "B.S., 1989: University of Utah, Salt Lake City, UT. Major: Plant Biology; Minor: Chemistry"
}
],
"knowsAbout": [
{
"@type": "Thing",
"additionalType": "self-claimed expertise",
"name": "Desert Ecosystems"
},
{
"@type": "Thing",
"additionalType": "self-claimed expertise",
"name": "Alpine Ecosystems"
},
{
"@type": "Thing",
"additionalType": "self-claimed expertise",
"name": "Biological Soil Crust"
},
{
"@type": "Thing",
"additionalType": "self-claimed expertise",
"name": "Telemetry"
},
{
"@type": "Thing",
"additionalType": "self-claimed expertise",
"name": "Sensor arrays"
},
{
"@type": "Thing",
"additionalType": "self-claimed expertise",
"name": "Meteorological stations"
}
],
"memberOf": {
"@type": "OrganizationalRole",
"name": "staff member",
"member": {
"@type": "Organization",
"name": "U.S. Geological Survey"
},
"startDate": "2024-09-21T07:56:17.393244"
}
},
"ORCID": {
"@context": "http://schema.org",
"@id": "https://orcid.org/0000-0002-9103-9482",
"@reverse": {
"creator": [
{
"@id": "https://doi.org/10.1111/gcb.16681",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1111/gcb.16681"
},
"name": "Droughting a megadrought: Ecological consequences of a decade of experimental drought atop aridification on the Colorado Plateau"
},
{
"@id": "https://doi.org/10.1029/2021jg006492",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1029/2021jg006492"
},
"name": "Climatic Controls on Soil Carbon Accumulation and Loss in a Dryland Ecosystems"
},
{
"@id": "https://doi.org/10.3791/60308",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.3791/60308"
},
"name": "Manufacturing Simple and Inexpensive Soil Surface Temperature and Gravimetric Water Content Sensors"
},
{
"@id": "https://doi.org/10.5194/bg-15-4561-2018",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.5194/bg-15-4561-2018"
},
"name": "Patterns of longer-term climate change effects on CO<sub>2</sub> efflux from biocrusted soils differ from those observed in the short term"
},
{
"@id": "https://doi.org/10.5194/bg-2017-543-supplement",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.5194/bg-2017-543-supplement"
},
"name": "Supplementary material to "Patterns of longer-term climate change effects on CO<sub>2</sub> efflux from biocrusted soils differ from those observed in the short-term""
},
{
"@id": "https://doi.org/10.1007/s10533-017-0372-3",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1007/s10533-017-0372-3"
},
"name": "The concurrent use of novel soil surface microclimate measurements to evaluate CO2 pulses in biocrusted interspaces in a cool desert ecosystem"
},
{
"@id": "https://doi.org/10.1007/s10533-015-0163-7",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1007/s10533-015-0163-7"
},
"name": "Observations of net soil exchange of CO2 in a dryland show experimental warming increases carbon losses in biocrust soils"
},
{
"@id": "https://doi.org/10.1111/j.1399-3054.2012.01566.x",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1111/j.1399-3054.2012.01566.x"
},
"name": "Physiological ecology of desert biocrust moss following 10 years exposure to elevated CO2: evidence for enhanced photosynthetic thermotolerance"
},
{
"@id": "https://doi.org/10.1007/s11104-011-1097-z",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1007/s11104-011-1097-z"
},
"name": "Warming and increased precipitation frequency on the Colorado Plateau: implications for biological soil crusts and soil processes"
},
{
"@id": "https://doi.org/10.1029/2011jg001643",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1029/2011jg001643"
},
"name": "Rain pulse response of soil CO2exchange by biological soil crusts and grasslands of the semiarid Colorado Plateau, United States"
},
{
"@id": "https://doi.org/10.1029/2010jg001322",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1029/2010jg001322"
},
"name": "Carbon, water, and energy fluxes in a semiarid cold desert grassland during and following multiyear drought"
},
{
"@id": "https://doi.org/10.1111/j.1365-2486.2010.02201.x",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1111/j.1365-2486.2010.02201.x"
},
"name": "Carbon exchange in biological soil crust communities under differential temperatures and soil water contents: implications for global change"
},
{
"@id": "https://doi.org/10.1128/aem.70.2.973-983.2004",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1128/aem.70.2.973-983.2004"
},
"name": "Diazotrophic Community Structure and Function in Two Successional Stages of Biological Soil Crusts from the Colorado Plateau and Chihuahuan Desert"
},
{
"@id": "https://doi.org/10.1093/treephys/20.4.217",
"@type": "CreativeWork",
"identifier": {
"@type": "PropertyValue",
"propertyID": "doi",
"value": "10.1093/treephys/20.4.217"
},
"name": "Estimating water use by sugar maple trees: considerations when using heat-pulse methods in trees with deep functional sapwood"
}
]
},
"@type": "Person",
"alumniOf": [
{
"@type": "Organization",
"alternateName": "EPOB",
"identifier": {
"@type": "PropertyValue",
"propertyID": "RINGGOLD",
"value": "1877"
},
"name": "University of Colorado Boulder"
},
{
"@type": "Organization",
"alternateName": "Biology",
"identifier": {
"@type": "PropertyValue",
"propertyID": "RINGGOLD",
"value": "7060"
},
"name": "University of Utah"
}
],
"familyName": "Grote",
"givenName": "Edmund E",
"mainEntityOfPage": "https://orcid.org/0000-0002-9103-9482",
"name": "Edmund E Grote"
},
"OpenAlex": {
"created_date": "2023-07-21",
"display_name": "Edmund E. Grote",
"display_name_alternatives": [
"E. Grote",
"Ed E. Grote",
"Edmund E. Grote",
"E. E. Grote"
],
"ids": {
"openalex": "https://openalex.org/A5045852509",
"orcid": "https://orcid.org/0000-0002-9103-9482"
},
"last_known_institutions": [
{
"country_code": "US",
"display_name": "United States Geological Survey",
"id": "https://openalex.org/I1286329397",
"lineage": [
"https://openalex.org/I1286329397",
"https://openalex.org/I1335927249"
],
"ror": "https://ror.org/035a68863",
"type": "government"
}
],
"orcid": "https://orcid.org/0000-0002-9103-9482",
"topics": [
{
"count": 11,
"display_name": "Biological Soil Crusts and their Roles in Ecosystems",
"domain": {
"display_name": "Life Sciences",
"id": "https://openalex.org/domains/1"
},
"field": {
"display_name": "Agricultural and Biological Sciences",
"id": "https://openalex.org/fields/11"
},
"id": "https://openalex.org/T12832",
"subfield": {
"display_name": "Ecology, Evolution, Behavior and Systematics",
"id": "https://openalex.org/subfields/1105"
}
},
{
"count": 7,
"display_name": "Lichen Symbiotic Relationships and Ecological Impact",
"domain": {
"display_name": "Life Sciences",
"id": "https://openalex.org/domains/1"
},
"field": {
"display_name": "Agricultural and Biological Sciences",
"id": "https://openalex.org/fields/11"
},
"id": "https://openalex.org/T11528",
"subfield": {
"display_name": "Ecology, Evolution, Behavior and Systematics",
"id": "https://openalex.org/subfields/1105"
}
},
{
"count": 7,
"display_name": "Global Forest Drought Response and Climate Change",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T10266",
"subfield": {
"display_name": "Global and Planetary Change",
"id": "https://openalex.org/subfields/2306"
}
},
{
"count": 4,
"display_name": "Eutrophication and Harmful Algal Blooms",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T10236",
"subfield": {
"display_name": "Environmental Chemistry",
"id": "https://openalex.org/subfields/2304"
}
},
{
"count": 2,
"display_name": "Global Methane Emissions and Impacts",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T11588",
"subfield": {
"display_name": "Global and Planetary Change",
"id": "https://openalex.org/subfields/2306"
}
},
{
"count": 2,
"display_name": "Impacts of Climate Change on Glaciers and Water Availability",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Earth and Planetary Sciences",
"id": "https://openalex.org/fields/19"
},
"id": "https://openalex.org/T10644",
"subfield": {
"display_name": "Atmospheric Science",
"id": "https://openalex.org/subfields/1902"
}
},
{
"count": 2,
"display_name": "Mechanics and Transport in Unsaturated Soils",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Engineering",
"id": "https://openalex.org/fields/22"
},
"id": "https://openalex.org/T10716",
"subfield": {
"display_name": "Civil and Structural Engineering",
"id": "https://openalex.org/subfields/2205"
}
},
{
"count": 1,
"display_name": "Biodiversity Conservation and Ecosystem Management",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T10005",
"subfield": {
"display_name": "Nature and Landscape Conservation",
"id": "https://openalex.org/subfields/2309"
}
},
{
"count": 1,
"display_name": "Atmospheric Aerosols and their Impacts",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Earth and Planetary Sciences",
"id": "https://openalex.org/fields/19"
},
"id": "https://openalex.org/T10075",
"subfield": {
"display_name": "Atmospheric Science",
"id": "https://openalex.org/subfields/1902"
}
},
{
"count": 1,
"display_name": "Anticipating Critical Transitions in Ecosystems",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T13377",
"subfield": {
"display_name": "Global and Planetary Change",
"id": "https://openalex.org/subfields/2306"
}
},
{
"count": 1,
"display_name": "Low-Cost Air Quality Monitoring Systems",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T12120",
"subfield": {
"display_name": "Environmental Engineering",
"id": "https://openalex.org/subfields/2305"
}
},
{
"count": 1,
"display_name": "Climate Change and Variability Research",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T10029",
"subfield": {
"display_name": "Global and Planetary Change",
"id": "https://openalex.org/subfields/2306"
}
},
{
"count": 1,
"display_name": "Microalgae as a Source for Biofuels Production",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Energy",
"id": "https://openalex.org/fields/21"
},
"id": "https://openalex.org/T10476",
"subfield": {
"display_name": "Renewable Energy, Sustainability and the Environment",
"id": "https://openalex.org/subfields/2105"
}
},
{
"count": 1,
"display_name": "Factors Affecting Sagebrush Ecosystems and Wildlife Conservation",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T13388",
"subfield": {
"display_name": "Ecology",
"id": "https://openalex.org/subfields/2303"
}
},
{
"count": 1,
"display_name": "Mycorrhizal Fungi and Plant Interactions",
"domain": {
"display_name": "Life Sciences",
"id": "https://openalex.org/domains/1"
},
"field": {
"display_name": "Agricultural and Biological Sciences",
"id": "https://openalex.org/fields/11"
},
"id": "https://openalex.org/T10451",
"subfield": {
"display_name": "Plant Science",
"id": "https://openalex.org/subfields/1110"
}
},
{
"count": 1,
"display_name": "Impact of Climate Change on Forest Wildfires",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T10555",
"subfield": {
"display_name": "Global and Planetary Change",
"id": "https://openalex.org/subfields/2306"
}
},
{
"count": 1,
"display_name": "Causes and Impacts of Climate Change Over Millennia",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Earth and Planetary Sciences",
"id": "https://openalex.org/fields/19"
},
"id": "https://openalex.org/T11594",
"subfield": {
"display_name": "Atmospheric Science",
"id": "https://openalex.org/subfields/1902"
}
},
{
"count": 1,
"display_name": "Impacts of Elevated CO2 and Ozone on Plant Physiology",
"domain": {
"display_name": "Life Sciences",
"id": "https://openalex.org/domains/1"
},
"field": {
"display_name": "Agricultural and Biological Sciences",
"id": "https://openalex.org/fields/11"
},
"id": "https://openalex.org/T11760",
"subfield": {
"display_name": "Plant Science",
"id": "https://openalex.org/subfields/1110"
}
},
{
"count": 1,
"display_name": "Aeolian Geomorphology and Wind Erosion Dynamics",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Earth and Planetary Sciences",
"id": "https://openalex.org/fields/19"
},
"id": "https://openalex.org/T12383",
"subfield": {
"display_name": "Earth-Surface Processes",
"id": "https://openalex.org/subfields/1904"
}
},
{
"count": 1,
"display_name": "Estimation of Forest Biomass and Carbon Stocks",
"domain": {
"display_name": "Physical Sciences",
"id": "https://openalex.org/domains/3"
},
"field": {
"display_name": "Environmental Science",
"id": "https://openalex.org/fields/23"
},
"id": "https://openalex.org/T11880",
"subfield": {
"display_name": "Nature and Landscape Conservation",
"id": "https://openalex.org/subfields/2309"
}
},
{
"count": 1,
"display_name": "Soil Carbon Dynamics and Nutrient Cycling in Ecosystems",
"domain": {
"display_name": "Life Sciences",
"id": "https://openalex.org/domains/1"
},
"field": {
"display_name": "Agricultural and Biological Sciences",
"id": "https://openalex.org/fields/11"
},
"id": "https://openalex.org/T10004",
"subfield": {
"display_name": "Soil Science",
"id": "https://openalex.org/subfields/1111"
}
}
],
"updated_date": "2024-05-15T20:56:38.611771"
}
}
