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210512 ||| eng |
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|a 9783039283521
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|a books978-3-03928-353-8
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|a 9783039283538
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|a Wang, Zhi
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|a Additive Manufacturing: Alloy Design and Process Innovations
|h Elektronische Ressource
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260 |
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|b MDPI - Multidisciplinary Digital Publishing Institute
|c 2020
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300 |
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|a 1 electronic resource (372 p.)
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|a thermal stress analysis
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|a GH4169
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|a 3D metal printing
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|a analytical modeling
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|a rapid solidification
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|a CuAl2 phase
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|a volumetric heat source
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|a model
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|a porosity reduction
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|a thermal capillary effects
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|a parts design
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|a crystallographic texture
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|a divisional scanning
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|a Taguchi
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|a epitaxial growth
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|a wire feeding additive manufacturing
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|a 3D printing
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|a Al-Mg alloy
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|a titanium alloy
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|a molten pool evolution
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|a radial grooves
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|a arc additive manufacturing
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|a dynamic characteristics
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|a thermosetting epoxy resin
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|a design
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|a mechanical property
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|a Ti6Al4V alloy
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|a multi-laser manufacturing
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|a fatigue
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|a WxNbMoTa
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|a Additive manufacturing
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|a laser powder bed fusion
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|a pulse frequency
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|a constitutive model
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|a disc brake
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|a macro defects
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|a circular economy
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|a Powder bed
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|a aluminum
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|a SLM process parameters
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|a femtosecond
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|a additive manufacturing
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|a bulk metallic glasses
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|a impact
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|a microstructural evolution
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|a graphene nano-sheets (GNSs)
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|a valorization
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|a high computational efficiency
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|a workpiece scale
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|a scanning electron microscopy (SEM)
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|a elastic abrasive
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|a stability lobe diagram
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|a regular mixing
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|a dynamic properties
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|a direct metal laser sintering
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|a Al-Si
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|a microstructure and properties
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|a temperature and stress fields
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|a powder properties
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|a microstructures
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|a Al-Mg-Si alloy
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|a PSO-BP neural network algorithm
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|a precipitates
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|a amorphous alloy
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|a laser powder bed fusion (LPBF)
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|a finite element analysis
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|a properties
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|a interfaces
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|a composite materials
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|a aluminum alloys
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|a selective laser melting
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|a martensitic transformation
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|a numerical analysis
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|a 2219 aluminum alloy
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|a powder flowability
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|a composition
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|a latent heat
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|a M300 mold steel
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|a tensile strength
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|a quenching rate
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|a scanning
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|a magnetizer
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|a microstructure
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|a 12CrNi2 alloy steel powder
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|a nickel alloys
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|a scanning strategy
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|a AlSi10Mg
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|a ultrafast laser
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|a Hastelloy X alloy
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|a heat treatment
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|a continuous carbon fiber
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|a continuous dynamic recrystallization
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|a water absorption
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|a laser cladding deposition
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|a microhardness measurement
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|a process-damping
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|a hot deformation
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|a paint bake-hardening
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|a tailored properties
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|a Cu50Zr43Al7
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|a molten pool dynamic behavior
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|a additive surface structuring
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|a selective laser melting (SLM)
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|a Electron Beam Melting
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|a thermal behaviour
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|a n/a
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|a wear
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|a defects
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|a metallic glasses
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|a refractory high-entropy alloy
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|a process parameters
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|a thin-walled weak rigidity parts
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|a equivalent processing model
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|a element segregation
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|a Mg content
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|a History of engineering and technology / bicssc
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|a powder packing
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|a melt pool size
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|a grain refinement
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|a vanadium
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|a laser power absorption
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|a parameter optimization
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|a ablation
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|a texture evolution
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|a simulation
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|a porosity
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|a in-process temperature in MPBAM
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|a Inconel 718
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|a arc additive manufacture
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|a laves phase
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|a intermediate thermo-mechanical treatment
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|a side spatters
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|a localized inductive heating
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|a arc current
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|a H13 tool steel
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|a deformation
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|a concrete
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|a ultrasonic bonding
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|a Al6061
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|a laser energy density
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|a inoculation
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|a laser cladding
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|a ball milling
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|a numerical simulation
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|a epoxy solder
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|a hot stamping steel blanks
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|a cement
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|a milling
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|a support strategy
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|a Hot Isostatic Pressure
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|a gray cast iron
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|a hydrophobicity
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|a flowability
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|a subgranular dendrites
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|a intermetallic compound (IMC)
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|a performance characteristics
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|a substrate preheating
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|a mechanical properties
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|a quality of the as-built parts
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|a ABS
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|a Al-5Si alloy
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|a storage energy
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|a thermal conductivity
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|a powder bed fusion
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|a slag
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|a AlSi10Mg alloy
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|a metal powders
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|a Ti-6Al-4V
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|a fused filament fabrication
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|a nickel-based superalloy
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|a residual stress
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|a wire lateral feeding
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1 |
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|a Konda Gokuldoss, Prashanth
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041 |
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7 |
|a eng
|2 ISO 639-2
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|b DOAB
|a Directory of Open Access Books
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500 |
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|a Creative Commons (cc), https://creativecommons.org/licenses/by-nc-nd/4.0/
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024 |
8 |
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|a 10.3390/books978-3-03928-353-8
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856 |
4 |
2 |
|u https://directory.doabooks.org/handle/20.500.12854/40123
|z DOAB: description of the publication
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|u https://www.mdpi.com/books/pdfview/book/2187
|7 0
|x Verlag
|3 Volltext
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|a 000
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|a 576
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|a 330
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|a 900
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|a 333
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|a 700
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|a 600
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|a 620
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|a Additive manufacturing (AM) is one of the manufacturing processes that warrants the attention of industrialists, researchers and scientists, because of its ability to produce materials with a complex shape without theoretical restrictions and with added functionalities. There are several advantages to employing additive manufacturing as the primary additive manufacturing process. However, there exist several challenges that need to be addressed systematically. A couple such issues are alloy design and process development. Traditionally alloys designed for conventional cast/powder metallurgical processes were fabricated using advanced AM processes. This is the wrong approach considering that the alloys should be coined based on the process characteristics and meta-stable nature of the process. Hence, we must focus on alloy design and development for AM that suits the AM processes. The AM processes, however, improve almost every day, either in terms of processing capabilities or processing conditions. Hence, the processing part warrants a section that is devoted to these advancements and innovations. Accordingly, the present Special Issue (book) focuses on two aspects of alloy development and process innovations. Here, 45 articles are presented covering different AM processes including selective laser melting, electron beam melting, laser cladding, direct metal laser sintering, ultrasonic consolidation, wire arc additive manufacturing, and hybrid manufacturing. I believe that this Special Issue bears is vital to the field of AM and will be a valuable addition.
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