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200 10$aAddressing the impact of temperature extremes on large format li-lon batteries for vehicle applications /$fAhmad Pesaran, Ph.D, Shriram Santhanagopalan, Gi-Heon Kim, NationalRenewal Energy Laboratory
210  1$aGolden, Colorado :$cNational Renewable Energy Laboratory,$d2013.
215   $a1 online resource (29 pages) $ccolor illustrations
225 1 $aNREL/PR ;$v5400-58145
300   $aTitle from title screen (viewed on Nov. 22, 2013).
300   $a"30th International Battery Seminar, Ft. Lauderdale, Florida, March 11-14, 2013."
606   $aAutomobiles$xBatteries$xResearch$vCongresses
606   $aLithium ion batteries$xResearch$vCongresses
608   $aConference papers and proceedings.$2lcgft
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615  0$aLithium ion batteries$xResearch
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702   $aSanthanagopalan$b Shriram
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200 10$aOrganic synthesis via examination of selected natural products$b[electronic resource] /$fDavid J. Hart
210   $aHackensack, N.J. $cWorld Scientific$d2011
215   $a1 online resource (589 p.)
300   $aDescription based upon print version of record.
311   $a981-4313-70-X 
320   $aIncludes bibliographical references and index.
327   $aContents; Preface; Chapter 1 Introduction; Chapter 2 Steroids; Chapter 3 Prostaglandins; Chapter 4 Pyrrolizidine Alkaloids; Chapter 5 Juvabione and the Vicinal Stereochemistry Problem; Chapter 6 Functional Group Reactivity Patterns and Difunctional Relationships; Chapter 7 Some Unnatural Products - Twistane and Triquinacene; Chapter 8 Alkaloids - Difunctional Relationships and the Importance of the Mannich Reaction; Chapter 9 Alkaloids from "Dart-Poison" Frogs; Chapter 10 Morphine and Oxidative Phenolic Coupling; Chapter 11 Olefin Synthesis and Cecropia Juvenile Hormone
327   $aChapter 12 A Recent Example of Structure Determination Through Total Synthesis and Convergent Syntheses: Lasonolide AChapter 13 Ionophores: Calcimycin; Chapter 14 Erythromycin A Aglycone; Concluding Remarks; Index
330   $aComplete with problems and solutions, this book is written for advanced graduate and undergraduate students to expose them to a variety of strategies for the synthesis of organic compounds. This is done largely within the context of natural products synthesis, but includes some unnatural products synthesis. Multiple approaches to each group of synthesis targets are presented, and the approaches are compared with one another with an eye on similarities and differences. General problems in organic synthesis (for example, strategies for the preparation of 6-membered rings and 5-membered rings, th
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615  0$aOrganic compounds$xSynthesis.
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200 00$aBioenergy and Biochar: Repurposing Waste to Sustainable Energy and Materials
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2021
215   $a1 online resource (180 p.)
311 08$a3-0365-1856-8 
311 08$a3-0365-1855-X 
330   $aDear Colleagues,All types of biomass, and their waste, comprised one the pillars of the preindustrial,pre-fossil fuel, agriculture-based economies of the past. Traditionalpractices of biomass waste management were applied, but not necessarily in asophisticated and efficient way, and included everything from agricultural activitiesto food production, animal feed, natural fiber separation, and processingof forest wood. The modern bioeconomy sector, however, includes new circulareconomy energy and materials streams of added-value products, such asgaseous, liquid and solid biofuels and bioenergy generation routes, and biocharproduction, along with all the previously mentioned traditional products emergingfrom the bioeconomy.This Special Issue includes some of the latest bioenergy and biochar advancementsand their incorporation into a bioeconomy in transition. It focuses onnature, properties, upgrading, and bioenergy generation processes from all typesof biomass waste and biochars originating from biomass waste. The multidisciplinarityof bioenergy and biochar research is evident throughout the SpecialIssue, highlighting the highly variable and tunable processes involved inbiomass handling, pre-processing, converting to biochar, and recovering energy.Dr. Dimitrios KalderisGuest EditorDr. Vasiliki Skoulouco-Guest Editor
517   $aBioenergy and Biochar
606   $aResearch and information: general$2bicssc
606   $aTechnology: general issues$2bicssc
610   $aacute phytotoxicity test
610   $aamino acid wastes
610   $aanaerobic digestion
610   $aAPSIM sugarcane model
610   $aartificial neural network
610   $aBCR sequential extraction
610   $abiochar
610   $abiocharing
610   $abiodegradation
610   $abioenergy resource
610   $abiofuels
610   $abiogas
610   $abiomass combustion
610   $abioplastics
610   $acalorific value
610   $acharacterization
610   $aCiteSpace
610   $acoconut shell
610   $acoconut wastes
610   $acoffee waste
610   $aeconomic performance
610   $aenergy potential
610   $aenzymatic hydrolysis
610   $aethanol
610   $afermentable sugar
610   $afixed bed
610   $afluidized bed boilers
610   $afly ash
610   $aGHG emissions
610   $ahydrochar
610   $ahydrothermal carbonization
610   $alife cycle assessment
610   $alignocellulosic biomass
610   $amarginal land
610   $ametal speciation
610   $amicroalgae
610   $amicrobial lipids
610   $amineral fertilizer
610   $aMitigation of CO2-equiv.
610   $anutrient release
610   $apolitical incentives
610   $apollutant emissions
610   $apolycaprolactone
610   $apyrolysis yield
610   $arespirometric reactors
610   $aRhodosporidium toruloides
610   $arice paddy water and soil system
610   $ascientometric analysis
610   $aSEM
610   $asensitivity analysis
610   $aslow-release fertilizer
610   $astarch
610   $atemperature
610   $atwo-stage culture
615  7$aResearch and information: general
615  7$aTechnology: general issues
700   $aKalderis$b Dimitrios$4edt$01303491
702   $aSkoulou$b Vasiliki$4edt
702   $aKalderis$b Dimitrios$4oth
702   $aSkoulou$b Vasiliki$4oth
906   $aBOOK
912   $a9910557634003321
996   $aBioenergy and Biochar: Repurposing Waste to Sustainable Energy and Materials$93027112
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