| Nome |
# |
|
Fracture and fatigue behaviour of AlSi7Mg0.6 produced by Selective Laser Melting: effects of thermal-treatments, file e0c31c0e-5f29-4599-e053-1705fe0aef77
|
413
|
|
Emergence of Elastic Properties in a Minimalist Resilin-Derived Heptapeptide upon Bromination, file 01dca2b3-3b73-4bb0-9148-71992c77940d
|
398
|
|
Influence of production batch related parameters on static and fatigue resistance of LPBF produced AlSi7Mg0.6, file fdc81391-c9f5-4be3-bd0c-666fffea9c06
|
382
|
|
Turning Vulcanized Natural Rubber into a Self-Healing Polymer: Effect of the Disulfide/Polysulfide Ratio, file e0c31c0f-a0d4-4599-e053-1705fe0aef77
|
359
|
|
Self-healing materials for space applications: overview of present development and major limitations, file e0c31c11-b3c1-4599-e053-1705fe0aef77
|
237
|
|
Fracture and fatigue behaviour of AlSi7Mg0.6 produced by Selective Laser Melting: effects of thermal-treatments, file ea973999-2384-44f5-9a1f-55b64ef3733d
|
216
|
|
On the role of free carboxylic groups and cluster conformation on the surface scratch healing behaviour of ionomers, file e0c31c0d-4c61-4599-e053-1705fe0aef77
|
151
|
|
Numerical And Experimental Crushing Behaviour Investigation Of EBM Printed Auxetic Chiral Lattices, file e0c31c0e-5412-4599-e053-1705fe0aef77
|
143
|
|
Advantages and challenges of novel materials for future space applications, file 10ed2c7c-6c81-4ae9-92cd-d7734ce2f830
|
135
|
|
Self-Healing Polymers for Space: a Study on Autonomous Repair Performance and Response to Space Radiation, file 93bcd02d-b3f2-434b-b944-bd5ef6d7ea62
|
118
|
|
Integrated Solutions for Safe Fuel Tanks, file e0c31c0d-bae9-4599-e053-1705fe0aef77
|
118
|
|
Development of a supramolecular polymer based self-healing multilayer system for inflatable structures, file e0c31c0f-c368-4599-e053-1705fe0aef77
|
112
|
|
Effect of the Dianhydride/Branched Diamine Ratio on the Architecture and Room Temperature Healing Behavior of Polyetherimides, file e0c31c0f-715b-4599-e053-1705fe0aef77
|
107
|
|
A combined fracture mechanical - rheological study to separate the contributions of hydrogen bonds and disulphide linkages to the healing of poly(urea-urethane) networks, file e0c31c0d-e312-4599-e053-1705fe0aef77
|
106
|
|
Effects of Stacking Sequences on the Interlaminar Shear Strength of CF/PEKK Composites, file d3836bb0-bb34-46f7-98bb-6cb3e3dd2c27
|
99
|
|
Method for damping shocks and vibrations, file a7a43aff-8d01-445c-aa5a-8670d7fd3dab
|
98
|
|
Contributions of hard and soft blocks in the self-healing of metal-ligand-containing block copolymers, file e0c31c0b-2c99-4599-e053-1705fe0aef77
|
98
|
|
Combination of topology and shape optimization with finite element modeling in the case of an aerospace component produced by laser based additive manufacturing, file 33fb086b-1a2b-47bc-bc34-01b6587d6e9f
|
91
|
|
In-plane compression behavior of anti-tetrachiral and re-entrant lattices, file e0c31c0e-a3cd-4599-e053-1705fe0aef77
|
90
|
|
Improved Solutions for Dangerous Liquid Containment, file e0c31c0d-c821-4599-e053-1705fe0aef77
|
89
|
|
Self-Healing System for Hypervelocity Impact Protection, Repair and Debris Mitigation, file e0c31c11-37d9-4599-e053-1705fe0aef77
|
86
|
|
Self-Healing Multilayer Composites and Nanocomposites for Space Applications: a Study on Damage Recovery Performance after Simulated Space Radiation Exposure, file e97c2f2d-8025-46ae-951b-ac11c0a659f3
|
86
|
|
Self-healing behavior in blends of PDMS-based polyurethane ionomers, file e0c31c12-8441-4599-e053-1705fe0aef77
|
85
|
|
Thermoplastic Coating on Carbon Fiber for the Design of Sustainable Composite Materials, file 1b890abf-fb8e-48bb-a537-ded0d4af59ce
|
82
|
|
Towards an understanding of the functional properties of NiTi produced by powder bed fusion, file e0c31c10-3296-4599-e053-1705fe0aef77
|
81
|
|
On the interfacial healing of a supramolecular elastomer, file e0c31c0d-aae3-4599-e053-1705fe0aef77
|
76
|
|
Intrinsic Self-Healing Epoxies in Polymer Matrix Composites (PMCs) for Aerospace Applications, file e0c31c10-26d8-4599-e053-1705fe0aef77
|
76
|
|
A Study on Damping Property of NiTi Elements Produced by Selective Laser‐Beam Melting, file e0c31c10-a948-4599-e053-1705fe0aef77
|
75
|
|
Effect of graphene content on the restoration of mechanical, electrical and thermal functionalities of a self-healing natural rubber, file e0c31c0d-f0f2-4599-e053-1705fe0aef77
|
74
|
|
Multimodal locomotion via folding of a degree-four vertex, file e0c31c12-cf42-4599-e053-1705fe0aef77
|
68
|
|
Effect of the polymer structure on the viscoelastic and interfacial healing behaviour of poly(urea-urethane) networks containing aromatic disulphides, file e0c31c0b-c5c5-4599-e053-1705fe0aef77
|
64
|
|
Multilayer composites with self-healing materials: aerospace applications, file e0c31c0e-af55-4599-e053-1705fe0aef77
|
64
|
|
Influence of production batch related parameters on static and fatigue resistance of LPBF produced AlSi7Mg0.6, file 5433d6c5-5734-4a17-9ca5-0868b0ac3dd5
|
61
|
|
Compression Behavior of EBM Printed Auxetic Chiral Structures, file e0c31c12-8bc6-4599-e053-1705fe0aef77
|
61
|
|
Failure analysis of auxetic lattice structures under crush load, file e0c31c12-2cad-4599-e053-1705fe0aef77
|
58
|
|
Self-Healing Polymers for Inflatable Space Structures, file 97abe9a8-a869-4a38-a22f-9e65f7201a2d
|
55
|
|
Review of current strategies to induce self-healing behaviour in fibre reinforced polymer based composites, file e0c31c0d-aae2-4599-e053-1705fe0aef77
|
53
|
|
Functionally Graded Carbon Fiber-Reinforced Ceramics for Extreme Environments: Characterization and Numerical Assessment, file e0c31c11-eb0a-4599-e053-1705fe0aef77
|
49
|
|
Chiral-Lattice-Filled Composite Tubes under Uniaxial and Lateral Quasi-Static Load: Experimental Studies, file e0c31c11-78ac-4599-e053-1705fe0aef77
|
43
|
|
Monitoring Network and Interfacial Healing Processes by Broadband Dielectric Spectroscopy: A Case Study on Natural Rubber, file e0c31c0f-6fb7-4599-e053-1705fe0aef77
|
39
|
|
Towards Self-Healing Polymers for Aerospace Applications: Experimental Tools to Evaluate Healing Capability, file e0c31c0c-4d7d-4599-e053-1705fe0aef77
|
38
|
|
Bacterially Produced, Nacre-Inspired Composite Materials, file e0c31c0c-da67-4599-e053-1705fe0aef77
|
34
|
|
3D-Printing of Lunar Regolith Ceramics with High Mechanical Properties via SLA-based Approach, file ef0d68db-2c5c-4d5f-abad-4ed44647bf13
|
34
|
|
On the Fracture Healing Response of an Aeronautic Grade Fiber Reinforced Epoxy Vitrimer Composite, file c236929e-741a-4909-bcbc-c5eed43421bf
|
29
|
|
Characterization of Self-Healing Polymers Under Simulated Space Environment, file f7207fb2-1df2-4258-99e4-4d91a3c02158
|
27
|
|
Thermally Triggered Self-Healing Mechanism in Al-Sn Composite Phase Change Materials, file 157aab50-e296-4149-8c45-7083a4e4d91e
|
26
|
|
Multifunctional composites with self-healing and radiation shielding properties for space applications, file e0c31c11-6634-4599-e053-1705fe0aef77
|
26
|
|
Self-healing garment, file e0c31c11-bdea-4599-e053-1705fe0aef77
|
25
|
|
Damping property of a NiTi auxetic structure fabricated through selective laser melting, file cdcf6a58-8e02-4af8-961b-ef4cffb3eae0
|
23
|
|
Reduced thermal conductivity by nanoscale intergrowths in perovskite like layered structure La2Ti2O7, file e0c31c0b-2620-4599-e053-1705fe0aef77
|
23
|
|
Response to Comment on “Turning Vulcanized Natural Rubber into a Self-Healing Polymer: Effect of the Disulfide/Polysulfide Ratio”, file e0c31c0b-5728-4599-e053-1705fe0aef77
|
23
|
|
Mitigation of Impact Damage with Self-Healing and Anti-Sloshing Materials in Aerospace Fuel Tanks, file e0c31c0c-bedc-4599-e053-1705fe0aef77
|
23
|
|
Effect of curing on the mechanical and healing behaviour of a hybrid dual network: a time resolved evaluation, file e0c31c0f-414f-4599-e053-1705fe0aef77
|
22
|
|
Poly(methyl methacrylate) as Healing Agent for Carbon Fibre Reinforced Epoxy Composites, file b7ad4864-c2f0-4668-8241-69d165f5723a
|
21
|
|
Mycospace: Novel Mycotic Materials for Future Space Missions, file e0c31c11-e411-4599-e053-1705fe0aef77
|
16
|
|
Reduced thermal conductivity by nanoscale intergrowths in perovskite like layered structure La2Ti2O7, file e0c31c0d-3d82-4599-e053-1705fe0aef77
|
15
|
|
Selective Laser Melting Of NiTi Alloys, file e0c31c0f-8def-4599-e053-1705fe0aef77
|
13
|
|
Selective Laser Melting Of NiTi Alloys, file e0c31c0f-8df0-4599-e053-1705fe0aef77
|
12
|
|
A critical appraisal of fracture mechanics methods for self-healing and healable composites characterization, file 94b22330-59df-49b0-87bc-c779c93d0e7b
|
10
|
|
Bacterially Produced, Nacre-Inspired Composite Materials, file e0c31c0f-14b3-4599-e053-1705fe0aef77
|
10
|
|
A comprehensive study of A357 alloy printability via laser metal deposition, file ca69080c-adde-4c20-afdb-d92236ae8c53
|
9
|
|
Towards Multifunctional FRPCS for Aerospace Applications, file e0c31c0e-11cd-4599-e053-1705fe0aef77
|
9
|
|
Damping Behaviour of Ni-Ti Auxetic Structures Manufactured by Selective Laser Melting, file e0c31c11-58c8-4599-e053-1705fe0aef77
|
9
|
|
Self-healing polymers for space: A study on autonomous repair performance and response to space radiation, file fd0b3bb1-ce9b-44c6-ab24-bd049ce46061
|
9
|
|
Hingeless arm for space robotics actuated through shape memory alloys, file 8747a208-830a-422f-82e5-2aabf08f60a5
|
8
|
|
Towards Safer Space Suits with Self-Healing Materials, file e0c31c11-3736-4599-e053-1705fe0aef77
|
8
|
|
Assessment of radiation shielding properties of self-healing polymers and nanocomposites for a space habitat case study under GCR and LEO radiation, file 45c6e961-37d2-411a-a53f-92c450c81854
|
7
|
|
Thermo-elastic properties in short fibre reinforced ultra-high temperature ceramic matrix composites: characterization and numerical assessment, file e0c31c11-6d19-4599-e053-1705fe0aef77
|
7
|
|
New insights into the molecular structure and dynamics of a recyclable and ionically crosslinked carboxylated nitrile rubber (XNBR), file 046a59b7-ab7c-4e7b-82ef-a405ef146d1a
|
6
|
|
Halogenation as a strategy to modify the physical-chemical properties of resilin-like oligopeptides., file e0c31c12-7482-4599-e053-1705fe0aef77
|
6
|
|
Role of microstructure in the exploitation of self-healing potential in form-stable composite phase change materials based on immiscible alloys, file 644d01d8-f8d0-41f0-a86e-f45621377bd2
|
5
|
|
On the role of free carboxylic groups and cluster conformation on the surface scratch healing behaviour of ionomers, file e0c31c0b-27c7-4599-e053-1705fe0aef77
|
5
|
|
Design of complex NiTi dampers trough subtractive and additive production processes: three case studies, file e0c31c10-c635-4599-e053-1705fe0aef77
|
5
|
|
Experimental Characterization of Self-Healing Nanocomposite and Multilayer Samples for Space Applications, file e0c31c11-c221-4599-e053-1705fe0aef77
|
5
|
|
Functionally graded ultra-high temperature ceramics: From thermo-elastic numerical analysis to damage tolerant composites, file 1aa2bc68-a2ce-4b91-b028-c58afb54426f
|
4
|
|
Parametric optimization of bio-inspired engineered sandwich core, file bdd46f61-77da-4954-a7e6-e186b7890195
|
4
|
|
Ballistics Response of Self-Healing Polymers and Components, file e0c31c09-9a08-4599-e053-1705fe0aef77
|
4
|
|
Effect of curing on the mechanical and healing behaviour of a hybrid dual network: a time resolved evaluation, file e0c31c0b-28dc-4599-e053-1705fe0aef77
|
4
|
|
Modelling the Non-Linear Viscoelastic Behaviour and Damage Evolution of a Self-Healing Supramolecular Elastomer During Uniaxial Straining, file e0c31c0b-c930-4599-e053-1705fe0aef77
|
4
|
|
Comparative analysis of gas atomised and recycled 316L stainless steel powders for Binder Jetting, file da2b86e2-6fd1-4a57-8b63-dc37c9f42474
|
3
|
|
Review of current strategies to induce self-healing behaviour in fibre reinforced polymer based composites, file e0c31c0b-27c9-4599-e053-1705fe0aef77
|
3
|
|
Method for damping shocks and vibrations, file e0c31c12-3263-4599-e053-1705fe0aef77
|
3
|
|
Poly(ethylene-co-methacrylic acid) coated carbon fiber for self-healing composites, file e62c131f-ce20-4156-a9e6-98223927a278
|
3
|
|
Combination of topology and shape optimization with finite element modeling in the case of an aerospace component produced by laser based additive manufacturing, file 1bf8b71c-54fc-4e99-8469-4f2135c4d078
|
2
|
|
On fracture behaviour of CF/PEKK laminates: Mode I fracture toughness, file 7ec001de-0590-4b48-aeeb-7f4c2b98040f
|
2
|
|
High Velocity Impact Behavior of Composite Sandwich Panels with Self-Healing Capabilities, file e0c31c08-7202-4599-e053-1705fe0aef77
|
2
|
|
Turning Vulcanized Natural Rubber into a Self-Healing Polymer: Effect of the Disulfide/Polysulfide Ratio, file e0c31c0b-261e-4599-e053-1705fe0aef77
|
2
|
|
On the interfacial healing of a supramolecular elastomer, file e0c31c0b-27c5-4599-e053-1705fe0aef77
|
2
|
|
Contributions of Polymer Architecture and Hard VS. Soft Blocks to Self-Healing in Supramolecular Block Copolymers, file e0c31c0b-3b50-4599-e053-1705fe0aef77
|
2
|
|
Finite Element Model of Ballistic Impacts on Self-Healing Ionomers, file e0c31c0b-3b52-4599-e053-1705fe0aef77
|
2
|
|
Bacterially Produced, Nacre-Inspired Composite Materials with Tuneable Stiffness, file e0c31c0b-bbfe-4599-e053-1705fe0aef77
|
2
|
|
A Fracture Mechanics-Based Method to Evaluate the Healing Capability of Novel Elastomers, file e0c31c0b-c934-4599-e053-1705fe0aef77
|
2
|
|
Bacterially Produced, Nacre-Inspired Composite Materials, file e0c31c0c-dd2f-4599-e053-1705fe0aef77
|
2
|
|
Towards an understanding of the functional properties of NiTi produced by powder bed fusion, file e0c31c11-43a4-4599-e053-1705fe0aef77
|
2
|
|
Multiscale microstructural heterogeneity and mechanical property scatter in Inconel 718 produced by directed energy deposition, file e0c31c11-c3b4-4599-e053-1705fe0aef77
|
2
|
|
A comprehensive study of A357 alloy printability via laser metal deposition, file 2ccbf697-5d5a-449c-9388-68f31fd2b9dc
|
1
|
|
Comparison of Self-Healing Ionomer to Aluminium-Alloy Bumpers for Protecting Spacecraft Equipment from Space Debris Impacts, file e0c31c08-073e-4599-e053-1705fe0aef77
|
1
|
|
Self-Healing Behavior of Blends Based on Ionomers with Ethylene/Vinyl Alcohol, file e0c31c08-6414-4599-e053-1705fe0aef77
|
1
|
|
Role of Phase Morphology on the Damage Initiated Self-Healing Behavior of Ionomer Blends, file e0c31c08-7275-4599-e053-1705fe0aef77
|
1
|
|
Effect of graphene content on the restoration of mechanical, electrical and thermal functionalities of a self-healing natural rubber, file e0c31c0b-28ed-4599-e053-1705fe0aef77
|
1
|
| Totale |
5.505 |