Difference between revisions of "Scientific Journal Publications"
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= Scientific Journal Publications = | = Scientific Journal Publications = | ||
This section contains publications from scientific peer reviewed journals that are applicable to reducing green house gas emissions and fighting climate disruption. Articles in this section should preferably be from a reputable peer reviewed journal, reputable government source or academic institution. Blogs, magazine articles or pop. science expose do not belong here. | This section contains publications from scientific peer reviewed journals that are applicable to reducing green house gas emissions and fighting climate disruption. Articles in this section should preferably be from a reputable peer reviewed journal, reputable government source or academic institution. Blogs, magazine articles or pop. science expose do not belong here. | ||
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==Climate Change Modeling== | ==Climate Change Modeling== | ||
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| + | |authorLast=Trisos | ||
| + | |year=2020 | ||
| + | |title=The projected timing of abrupt ecological disruption from climate change | ||
| + | |link=https://www.nature.com/articles/s41586-020-2189-9 | ||
| + | |summary= ? | ||
| + | }} | ||
==Renewable Electric Grid Modeling== | ==Renewable Electric Grid Modeling== | ||
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|authorLast = Jacobson | |authorLast = Jacobson | ||
|year = 2019 | |year = 2019 | ||
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|authorLast=Jacobson | |authorLast=Jacobson | ||
|year=2017 | |year=2017 | ||
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|authorLast=Jacobson | |authorLast=Jacobson | ||
|year=2015 | |year=2015 | ||
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|title=Evaluation of Jacobson's proposal for reliable low-cost grid power with 100% wind, water, and solar | |title=Evaluation of Jacobson's proposal for reliable low-cost grid power with 100% wind, water, and solar | ||
|link=https://www.pnas.org/content/114/26/6722 | |link=https://www.pnas.org/content/114/26/6722 | ||
| − | |summary= A critique of Jacobson's 2015 US WWS paper. Modeling areas that can be improved are identified. | + | |summary=A critique of Jacobson's 2015 US WWS paper. Modeling areas that can be improved are identified. |
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==Renewable Energy Grid Resources== | ==Renewable Energy Grid Resources== | ||
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|year=2017 | |year=2017 | ||
|title=Concentrating Solar Power Gen3 Demonstration Roadmap | |title=Concentrating Solar Power Gen3 Demonstration Roadmap | ||
| − | |link= | + | |link=https://www.nrel.gov/docs/fy17osti/67464.pdf |
|summary=An NREL roadmap of concentrated solar power development, with future cost points and review of emerging technology (Molten Salt, Falling Particle, Gas Phase). | |summary=An NREL roadmap of concentrated solar power development, with future cost points and review of emerging technology (Molten Salt, Falling Particle, Gas Phase). | ||
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|link=https://prod-ng.sandia.gov/techlib-noauth/access-control.cgi/2018/186187.pdf | |link=https://prod-ng.sandia.gov/techlib-noauth/access-control.cgi/2018/186187.pdf | ||
|summary=Contains a detailed review of laboratory commercialization research efforts into SCO2 Brayton cycle engines. | |summary=Contains a detailed review of laboratory commercialization research efforts into SCO2 Brayton cycle engines. | ||
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| + | === High Voltage DC Transmission === | ||
| + | {{JournalBrief | ||
| + | |authorLast=ICF Inc. | ||
| + | |year=2018 | ||
| + | |title = Assessing HVDC Transmission for Impacts of Non‐Dispatchable Generation | ||
| + | |link = https://www.eia.gov/analysis/studies/electricity/hvdctransmission/pdf/transmission.pdf | ||
| + | |summary = Provides an assessment of the potential for High‐Voltage Direct Current | ||
| + | Transmission to mitigate impacts of non‐dispatchable generation technologies. | ||
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==Regenerative Farming and Biomass== | ==Regenerative Farming and Biomass== | ||
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===Biomass=== | ===Biomass=== | ||
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|summary=Analyzes significant impact of "sub-surface(>30cm)" biomass when calculating soil organic carbon for GHG life-cycle assessment. | |summary=Analyzes significant impact of "sub-surface(>30cm)" biomass when calculating soil organic carbon for GHG life-cycle assessment. | ||
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==Industrial== | ==Industrial== | ||
Latest revision as of 03:00, 24 November 2020
Contents
Scientific Journal Publications
This section contains publications from scientific peer reviewed journals that are applicable to reducing green house gas emissions and fighting climate disruption. Articles in this section should preferably be from a reputable peer reviewed journal, reputable government source or academic institution. Blogs, magazine articles or pop. science expose do not belong here.
Climate Change Modeling
Trisos (2020) The projected timing of abrupt ecological disruption from climate change [1]
Summary - ?
Renewable Electric Grid Modeling
Jacobson (2019) Impacts of Green New Deal Energy Plans on Grid Stability, Costs, Jobs, Health, and Climate in 143 Countries [2]
Summary - This paper looks at a high level world model of an wind, water, and sunlight only electric grid, and the resources needed for 80% by 2030, and 100% by 2050.
Jacobson (2017) 100% Clean and Renewable Wind, Water, and Sunlight All-Sector Energy Roadmaps for 139 Countries of the World [3]
Summary -
Jacobson (2015) 100% clean and renewable wind, water, and sunlight (WWS) all-sector energy roadmaps for the 50 United States [4]
Summary - This paper looks at a medium granularity US model of 100% wind, water, and sunlight only electric grid. The paper identifies the amount of resources needed, and some novel technologies. The resource model is somewhat general and is a base to improve upon.
Clark (2017) Evaluation of Jacobson's proposal for reliable low-cost grid power with 100% wind, water, and solar [5]
Summary - A critique of Jacobson's 2015 US WWS paper. Modeling areas that can be improved are identified.
Renewable Energy Grid Resources
CSP
NREL (2017) Concentrating Solar Power Gen3 Demonstration Roadmap [6]
Summary - An NREL roadmap of concentrated solar power development, with future cost points and review of emerging technology (Molten Salt, Falling Particle, Gas Phase).
NREL (2018) CSP Systems Analysis - Final Project Report [7]
Summary - Primarily a review of pricing, properties and technology of different CSP systems.
Hybrid CSP
Powell (2017) Hybrid Concentrated Solar Thermal Power Systems: A Review [8]
Summary - Summary - A review of hybridization techniques used with concentrated solar power (CSP).
Korzynietz (2016) Solugas – Comprehensive analysis of the solar hybrid Brayton plant [9]
Summary - Detailed description of a 4.6MWe solar-hybrid gas turbine. CSP pre-heats air for the inlet of a gas turbine resulting in less gas usage.
Parrado (2016) 2050 LCOE (Levelized Cost of Energy) projection for a hybrid PV(photovoltaic)-CSP (concentrated solar power) plant in the Atacama Desert, Chile [10]
Summary -
Heat Engines
Carlson (2017) TECHNO-ECONOMIC COMPARISON OF SOLAR-DRIVEN SCO2 BRAYTON CYCLES USING COMPONENT COST MODELS BASELINED WITH VENDOR DATA AND ESTIMATES [11]
Summary - Contains pricing and performance information on sCO2 Brayton cycle engines.
Sandia (2018) sCO2 Brayton Cycle: Roadmap to sCO2 Power Cycles NE Commercial Applications [12]
Summary - Contains a detailed review of laboratory commercialization research efforts into SCO2 Brayton cycle engines.
High Voltage DC Transmission
ICF Inc. (2018) Assessing HVDC Transmission for Impacts of Non‐Dispatchable Generation [13]
Summary - Provides an assessment of the potential for High‐Voltage Direct Current
Transmission to mitigate impacts of non‐dispatchable generation technologies.
Other
NREL (2013) Land-Use Requirements for Solar Power Plants in the United States [14]
Summary - Provides statistics on the ratio of land to power generated for different solar generation technologies.
Regenerative Farming and Biomass
Biomass
Finnan (2013) Hemp: A more sustainable annual energy crop for climate and energy policy [15]
Summary -
Schmer (2015) Sub-surface soil carbon changes affects biofuel greenhouse gas emissions [16]
Summary - Analyzes significant impact of "sub-surface(>30cm)" biomass when calculating soil organic carbon for GHG life-cycle assessment.
Industrial
Turcheniuk (2018) Ten years left to redesign lithium-ion batteries [17]
Summary - Describes serious limitation in reserves of cobalt and nickel reserves for meeting future battery demand.
