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100   $a20040205d2004      uy             0
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200 10$aNumerical methods in aerospace$b[electronic resource] $ecivil aviation and space exploration /$fM.A. Keavey
210   $aBradford, England $cEmerald Group$d2004
215   $a1 online resource (169 p.)
225 1 $aInternational Journal of Numerical methods for heat & fluid flow. No. 4 ;$vVol. 14
300   $aDescription based upon print version of record.
311   $a0-86176-958-9 
327   $aCONTENTS; EDITORIAL ADVISORY BOARD; Abstracts and keywords; Editorial; Simulation of transonic flutter and active shockwave control; Numerical study of active shock control for transonic aerodynamics; Dynamic modeling in large-eddy simulation of turbulent channel flow Investigation of two-dimensional versus three-dimensional test filtering; The role of endothermic gasification in propellant ignition; Rarefied, superorbital flows in an expansion tube; Numerical simulation of inductively coupled plasma flows under chemical non-equilibrium; Discretization of the magnetic field in MPD thrusters
330   $aTransonic flutter and active flap control, in two dimensions, are simulated by coupling independent structural dynamic and inviscid aerodynamic models, in the time domain. A flight control system, to actively control the trailing edge flap motion, has also been incorporated and, since this requires perfect synchronisation of fluid, structure and control signal, the ''strong'' coupling approach is adopted. The computational method developed is used to perform transonic aeroelastic and aeroservoelastic calculations in the time domain, and used to compute stability (flutter) boundaries of 2D wing
410  0$aInternational journal of numerical methods for heat & fluid flow ;$vv. 14, no. 4.
606   $aAeronautics
606   $aAstronautics
608   $aElectronic books.
615  0$aAeronautics.
615  0$aAstronautics.
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200 10$aDrought Stress in Maize (Zea mays L.) $eEffects, Resistance Mechanisms, Global Achievements and Biological Strategies for Improvement /$fby Muhammad Aslam, Muhammad Amir Maqbool, Rahime Cengiz
205   $a1st ed. 2015.
210  1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2015.
215   $a1 online resource (79 p.)
225 1 $aSpringerBriefs in Agriculture,$x2211-808X
300   $aDescription based upon print version of record.
311   $a3-319-25440-5 
320   $aIncludes bibliographical references.
330   $aThis book focuses on early germination, one of maize germplasm most important strategies for adapting to drought-induced stress. Some genotypes have the ability to adapt by either reducing water losses or by increasing water uptake. Drought tolerance is also an adaptive strategy that enables crop plants to maintain their normal physiological processes and deliver higher economical yield despite drought stress. Several processes are involved in conferring drought tolerance in maize: the accumulation of osmolytes or antioxidants, plant growth regulators, stress proteins and water channel proteins, transcription factors and signal transduction pathways.  Drought is one of the most detrimental forms of abiotic stress around the world and seriously limits the productivity of agricultural crops. Maize, one of the leading cereal crops in the world, is sensitive to drought stress. Maize harvests are affected by drought stress at different growth stages in different regions. Numerous events in the life of maize crops can be affected by drought stress: germination potential, seedling growth, seedling stand establishment, overall growth and development, pollen and silk development, anthesis silking interval, pollination, and embryo, endosperm and kernel development.  Though every maize genotype has the ability to avoid or withstand drought stress, there is a concrete need to improve the level of adaptability to drought stress to address the global issue of food security. The most common biological strategies for improving drought stress resistance include screening available maize germplasm for drought tolerance, conventional breeding strategies, and marker-assisted and genomic-assisted breeding and development of transgenic maize. As a comprehensive understanding of the effects of drought stress, adaptive strategies and potential breeding tools is the prerequisite for any sound breeding plan, this brief addresses these aspects.
410  0$aSpringerBriefs in Agriculture,$x2211-808X
606   $aPlant anatomy
606   $aPlants$xDevelopment
606   $aClimatic changes
606   $aPlant physiology
606   $aAgriculture
606   $aPlants$vClassification
606   $aPlants$vClassification
606   $aPlant genetics
606   $aPlant Anatomy/Development$3https://scigraph.springernature.com/ontologies/product-market-codes/L24019
606   $aClimate Change/Climate Change Impacts$3https://scigraph.springernature.com/ontologies/product-market-codes/313000
606   $aPlant Physiology$3https://scigraph.springernature.com/ontologies/product-market-codes/L33020
606   $aAgriculture$3https://scigraph.springernature.com/ontologies/product-market-codes/L11006
606   $aPlant Systematics/Taxonomy/Biogeography$3https://scigraph.springernature.com/ontologies/product-market-codes/L24051
606   $aPlant Genetics and Genomics$3https://scigraph.springernature.com/ontologies/product-market-codes/L32020
615  0$aPlant anatomy.
615  0$aPlants$xDevelopment.
615  0$aClimatic changes.
615  0$aPlant physiology.
615  0$aAgriculture.
615  0$aPlants
615  0$aPlants
615  0$aPlant genetics.
615 14$aPlant Anatomy/Development.
615 24$aClimate Change/Climate Change Impacts.
615 24$aPlant Physiology.
615 24$aAgriculture.
615 24$aPlant Systematics/Taxonomy/Biogeography.
615 24$aPlant Genetics and Genomics.
676   $a633.15
700   $aAslam$b Muhammad$4aut$4http://id.loc.gov/vocabulary/relators/aut$0643574
702   $aMaqbool$b Muhammad Amir$4aut$4http://id.loc.gov/vocabulary/relators/aut
702   $aCengiz$b Rahime$4aut$4http://id.loc.gov/vocabulary/relators/aut
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