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New Advances in High-Entropy Alloys



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Autore: Zhang Yong Visualizza persona
Titolo: New Advances in High-Entropy Alloys Visualizza cluster
Pubblicazione: Basel, Switzerland, : MDPI - Multidisciplinary Digital Publishing Institute, 2021
Descrizione fisica: 1 electronic resource (652 p.)
Soggetto topico: Research & information: general
Soggetto non controllato: high-entropy alloys
alloys design
lightweight alloys
high entropy alloys
elemental addition
annealing treatment
magnetic property
microhardness
in situ X-ray diffraction
grain refinement
thermoelectric properties
scandium effect
HEA
high-entropy alloy
CCA
compositionally complex alloy
phase composition
microstructure
wear behaviour
metal matrix composites
mechanical properties
high-entropy films
phase structures
hardness
solid-solution
interstitial phase
transmission electron microscopy
compositionally complex alloys
CrFeCoNi(Nb,Mo)
corrosion
sulfuric acid
sodium chloride
entropy
multicomponent
differential scanning calorimetry (DSC)
specific heat
stacking-fault energy
density functional theory
nanoscaled high-entropy alloys
nanodisturbances
phase transformations
atomic-scale unstable
mechanical alloying
spark plasma sintering
nanoprecipitates
annealing
phase constituent
ion irradiation
hardening behavior
volume swelling
medium entropy alloy
high-pressure torsion
partial recrystallization
tensile strength
high-entropy alloys (HEAs)
phase constitution
magnetic properties
Curie temperature
phase transition
precipitation
strengthening
coherent microstructure
conventional alloys
nanocrystalline materials
high entropy alloy
sputtering
deformation and fracture
strain rate sensitivity
liquid phase separation
immiscible alloys
HEAs
multicomponent alloys
miscibility gaps
multi-principal element alloys
MPEAs
complex concentrated alloys
CCAs
electron microscopy
plasticity methods
plasticity
serration behavior
alloy design
structural metals
CALPHAD
solid-solution alloys
lattice distortion
phase transformation
(CoCrFeNi)100−xMox alloys
corrosion behavior
gamma double prime nanoparticles
elemental partitioning
atom probe tomography
first-principles calculations
bcc
phase stability
composition scanning
laser cladding
high-entropy alloy coating
AZ91D magnesium alloy
wear
kinetics
deformation
thermal expansion
diamond
composite
powder metallurgy
additive manufacturing
low-activation high-entropy alloys (HEAs)
high-temperature structural alloys
microstructures
compressive properties
heat-softening resistance
tensile creep behavior
microstructural evolution
creep mechanism
first-principles calculation
maximum entropy
elastic property
mechanical property
recrystallization
laser metal deposition
elemental powder
graded material
refractory high-entropy alloys
elevated-temperature yield strength
solid solution strengthening effect
bulk metallic glass
complex stress field
shear band
flow serration
deformation mechanism
ab initio
configuration entropy
matrix formulation
cluster expansion
cluster variation method
monte carlo
thermodynamic integration
(AlCrTiZrV)-Six-N films
nanocomposite structure
refractory high entropy alloys
medium entropy alloys, mechanical properties
thin films
deformation behaviors
nanocrystalline
coating
interface
mechanical characterization
high pressure
polymorphic transition
solidification
eutectic dendrites
hierarchical nanotwins
precipitation kinetics
strengthening mechanisms
elongation prediction
welding
Hall–Petch (H–P) effect
lattice constants
high-entropy ceramic
solid-state diffusion
phase evolution
mechanical behaviors
high-entropy film
low-activation alloys
Persona (resp. second.): ZhangYong
Sommario/riassunto: In recent years, people have tended to adjust the degree of order/disorder to explore new materials. The degree of order/disorder can be measured by entropy, and it can be divided into two parts: topological disordering and chemical disordering. The former mainly refers to order in the spatial configuration, e.g., amorphous alloys which show short-range ordering but without long-range ordering, while the latter mainly refers to the order in the chemical occupancy, that is to say, the components can replace each other, and typical representatives are high-entropy alloy (HEAs). HEAs, in sharp contrast to traditional alloys based on one or two principal elements, have one striking characteristic: their unusually high entropy of mixing. They have not received much noticed until the review paper entitled “Microstructure and Properties of High-Entropy Alloys” was published in 2014 in the journal of Progress in Materials Science. Numerous reports have shown they exhibit five recognized performance characteristics, namely, strength–plasticity trade-off breaking, irradiation tolerance, corrosion resistance, high-impact toughness within a wider temperature range, and high thermal stability. So far, the development of HEAs has gone through three main stages: 1. Quinary equal-atomic single-phase solid solution alloys; 2. Quaternary or quinary non-equal-atomic multiphase alloys; 3. Medium-entropy alloys, high-entropy fibers, high-entropy films, lightweight HEAs, etc. Nowadays, more in-depth research on high-entropy alloys is urgently needed.
Titolo autorizzato: New Advances in High-Entropy Alloys  Visualizza cluster
Formato: Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione: Inglese
Record Nr.: 9910557430203321
Lo trovi qui: Univ. Federico II
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