Keyphrases
Crack Healing
100%
Capillary Bridge
62%
Capillary
55%
Single Bead
45%
Melt Pool
42%
Selective Laser Melting
41%
Electron Beam
38%
Additive Manufacturing Process
37%
Induced Cracking
35%
Nanoscale Roughness
35%
Asperity Surface
35%
Nucleation Rate
35%
Multi-asperity
35%
Ti-6Al-4V (Ti64)
35%
Part-scale
30%
Metal Additive Manufacturing
29%
Melt Pool Geometry
29%
Process Parameters Influence
29%
Adhesion
27%
Additive Manufacturing
26%
High Deposition Rate
26%
Micro-electro-mechanical Systems
24%
Micromachining
23%
Environmental Control
23%
Laser Powder Bed
23%
Melt Pool Dimensions
22%
Bridge Dynamics
21%
Humidity
21%
Polysilicon
21%
Powder Bed Fusion
21%
Microcantilever
21%
Part Quality
19%
Nucleation Time
18%
Bridge Crack
17%
Long Working Distance
17%
Double Ellipsoid Heat Source
17%
Van Der Waals Force
17%
Process Mapping
17%
Structured Process
17%
Laser Sintering
17%
Beam Model
17%
Rough Interface
17%
Interferometry
17%
AlSi10Mg Alloy
17%
Laser Direct Structuring
17%
Material Extrusion
17%
Thermomechanical Simulation
17%
Surface Roughness Effect
17%
Variable Design
17%
Insulated Rail Joints
17%
Engineering
Crack Healing
79%
Additive Manufacturing
65%
Process Parameter
58%
Powder Bed Fusion
52%
Melt Pool
48%
Selective Laser Melting
35%
Powder Bed
35%
Nanoscale Roughness
35%
Additive Manufacturing Process
29%
Deposition Rate
22%
Finite Element Analysis
22%
Microcantilevers
21%
High Deposition Rate
21%
Bridge Dynamics
21%
Experimental Investigation
21%
Polysilicon
21%
Surface Asperity
17%
Nucleation Rate
17%
Radio Frequency
17%
Ti-6al-4v
17%
Mapping Method
17%
Induced Force
17%
Joints (Structural Components)
17%
Product Design
17%
Multiobjective Optimization
17%
Beam Model
17%
Roughness Effect
17%
X-Band
17%
Design Parameter
17%
Interferometry
17%
Dynamic Behavior
17%
Adhesive Bond Strength
17%
Injection Moulding Process
17%
Test Chamber
17%
Mesoscale
17%
Scale Model
17%
Learning System
17%
Experimental Technique
12%
Part Quality
12%
Polycarbonate
11%
Injection Moulding
11%
Crack Tip
11%
Melting Temperature
11%
Acrylonitrile Butadiene Styrene
11%
Parallel Plate
11%
Energy Release Rate
9%
Experimental Result
9%
System Reliability
9%
Capillary Force
9%
Predictive Capability
9%