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035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/79620
035   $a(EXLCZ)995400000000045287
100   $a20202203d2022      |y             0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aManaging the Product Quality of Vegetable Crops under Abiotic Stress
210   $aBasel$cMDPI - Multidisciplinary Digital Publishing Institute$d2022
215   $a1 electronic resource (168 p.)
311   $a3-0365-3098-3 
311   $a3-0365-3099-1 
330   $aVegetables are an important part of the human diet due to their nutrient density and, at the same time, low calorie content. Producers of vegetable crops mainly aim at achieving high yields with good external quality. However, there is an increasing demand of consumers for vegetables that provide good sensory properties and are rich in secondary compounds that can be valuable for human health. Sub- or supra-optimal abiotic conditions, like high temperatures, drought, excess light, salinity or nutrient deficiency, may alter the composition of vegetable crops and at the same time, result in yield loss. Thus, producers need to adapt their horticultural practices such as through the choice of variety, irrigation regime, light management, fruit thinning, or fertilizer application to improve the yield and quality of the vegetable product. In the future, altered climate conditions such as elevated atmospheric CO2 concentrations, rising temperatures, or altered precipitation patterns may become additional challenges for producers of vegetable crops, especially those that cultivate in the open field. This raises the need for optimized horticultural practices in order to minimize abiotic stresses. As well, specific storage conditions can have large impacts on the quality of vegetables. This Special Issue compiles research that deals with the optimization of vegetable product quality (e.g. sensory aspects, composition) under sub- or supra-optimal abiotic conditions.
606   $aResearch & information: general$2bicssc
610   $aascorbic acid
610   $abiostimulants
610   $aAllium cepa
610   $aPhulkara
610   $aNasarpuri
610   $aLambada and Red Bone
610   $agibberex
610   $aMomordica charantia L
610   $adismutase
610   $aperoxidase
610   $acatalase
610   $avegetative growth
610   $aflesh firmness
610   $aflowering
610   $aharvest time
610   $alycopene
610   $arootstock-scion combination
610   $atotal soluble solids
610   $aelevated CO?
610   $amodified atmosphere package
610   $asensory and physiological-biochemical characteristics
610   $atotal phenol
610   $aDPPH
610   $aheirloom beans
610   $adrought
610   $aabiotic stress
610   $alocal farming
610   $anutraceutical properties
610   $azinc
610   $aSolanum lycopersicum
610   $adrought potassium
610   $avacuolar transporter
610   $atomato
610   $aproduct quality
610   $anitrogen
610   $ashelf life
610   $acarotenoids
610   $aantioxidants
610   $ataste
610   $aminerals
610   $afatty acids
610   $aoxalate
610   $anitrate
610   $aphytochemicals
610   $aammonium
610   $aclimate change
610   $afood quality
610   $aphotosynthesis
610   $anitrogen source
610   $avegetable
610   $aOcimum basilicum
610   $asalt
610   $aNaCl
610   $ayield
610   $aquality
610   $apolyphenols
610   $agrafting
610   $awater-use efficiency
610   $anutrient use efficiency
610   $avegetable production
615  7$aResearch & information: general
700   $aSchmidt$b Lilian$4edt$01319400
702   $aSchmidt$b Lilian$4oth
906   $aBOOK
912   $a9910557611503321
996   $aManaging the Product Quality of Vegetable Crops under Abiotic Stress$93033879
997   $aUNINA

LEADER 04002nam  2201153z- 450 
001 9910367755003321
005 20231214133615.0
010   $a3-03921-547-7
035   $a(CKB)4100000010106167
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/42790
035   $a(EXLCZ)994100000010106167
100   $a20202102d2019      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aCatalysts Deactivation, Poisoning and Regeneration
210   $cMDPI - Multidisciplinary Digital Publishing Institute$d2019
215   $a1 electronic resource (254 p.)
311   $a3-03921-546-9 
330   $aCatalyst lifetime represents one of the most crucial economic aspects in industrial catalytic processes, due to costly shutdowns, catalyst replacements, and proper disposal of spent materials. Not surprisingly, there is considerable motivation to understand and treat catalyst deactivation, poisoning, and regeneration, which causes this research topic to continue to grow. The complexity of catalyst poisoning obviously increases along with the increasing use of biomass/waste-derived/residual feedstocks and with requirements for cleaner and novel sustainable processes. This book collects 15 research papers providing insights into several scientific and technical aspects of catalyst poisoning and deactivation, proposing more tolerant catalyst formulations, and exploring possible regeneration strategies.
610   $acyclic operation
610   $anickel catalysts
610   $aregeneration
610   $aCu/SSZ-13
610   $asyngas
610   $aNH3-SCR
610   $aoxysulfate
610   $aNi-catalyst
610   $aMW incinerator
610   $aiso-octane
610   $ahydrogenation
610   $adry reforming of methane
610   $aoxysulfide
610   $aCo-Zn/H-Beta
610   $aLow-temperature catalyst
610   $aRh catalysts
610   $adeactivation
610   $avanadia species
610   $aSO2 poisoning
610   $avehicle emission control
610   $abarium carbonate
610   $asodium ions
610   $asulfur deactivation
610   $atetragonal zirconia
610   $asulfur poisoning
610   $aLiquefied natural gas
610   $awater
610   $adeactivation by coking
610   $aphase stabilization
610   $acatalyst
610   $aNO removal
610   $aphysico-chemical characterization
610   $aoctanol
610   $aSEM
610   $aaluminum sulfate
610   $aoxygen storage capacity
610   $aunusual deactivation
610   $adiesel
610   $anitrous oxide
610   $aexhaust gas
610   $aover-reduction
610   $apoisoning
610   $acatalyst deactivation
610   $aammonium sulfates
610   $aCO2 reforming
610   $aSO3
610   $aRh
610   $ain situ regeneration
610   $acopper
610   $aV2O5-WO3/TiO2 catalysts
610   $apalladium sulfate
610   $aSelective Catalytic Reduction (SCR)
610   $abiogas
610   $athermal stability
610   $aphthalic anhydride
610   $aoctanal
610   $anatural gas
610   $asulfur-containing sodium salts
610   $awashing
610   $acoke deposition
610   $avanadia-titania catalyst
610   $aCPO reactor
610   $ahomogeneous catalysis
610   $aNOx reduction by C3H8
610   $anitrogen oxides
610   $aeffect of flow rate
610   $aDeNOx
610   $acatalytic methane combustion
610   $adeactivation mechanism
610   $aTEM
610   $acatalyst durability
700   $aLisi$b Luciana$4auth$01292431
702   $aCimino$b Stefano$4auth
906   $aBOOK
912   $a9910367755003321
996   $aCatalysts Deactivation, Poisoning and Regeneration$93022301
997   $aUNINA