Micromechanical Deformation & Characterization of Materials Gr… · The global market for all...
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Mechanical surface treatments use cold working to develop residual stresses on the substrate or in the bulk to enhance a material’s mechanical properties. Materials that are mechanically surface treated tend to have increased service lifetimes and resist wear and fatigue. Shot peening is one of the well-established methods to induce compressive residual stresses in the metallic components for the cold working purposes. Finite element simulation and nanoindentation methods can be used to study the elastic-plastic deformation and mechanical behaviors after shot peening process to determine residual stress profile. Micromechanical Deformation & Characterization of Materials Graduate students: Jesus Hector Morales, Raheleh Mohammad Rahimi, Siavash Ghanbari, Kim Chang-Eun, Alexandra Burch, Temitope Q Aminu, Zara Molaeinia, David Brice Faculty Advisor: Prof. David F. Bahr The ability to characterize the mechanical properties of materials at the nanoscale has become a crucial component of the research and development in nanoscience and nanotechnologies. Such ability addresses themes relevant across a number of manufacturing and processing sectors such as semiconductor industry, life sciences, electronics and biomaterials. The global market for all types of materials characterization instrument was worth an estimated $20.3 billion in 2003. Our group works on linking the structure of a wide range of classes of materials and processing with the subsequent micromechanical behavior, including elastic, plastic, and fracture properties. . Characterization of the mechanical response of materials under nanoindentation (load-displacement monitored indentation), when coupled with scanning probe microscopy can be used to test small volumes of materials that are either (1) Small because the sample is small, or (2) Features in the material are small (such as second phase particles). Nanoindentation is one of the fundamental tools used within our group to explore diverse materials, either experimentally or coupled with computational modeling. Some examples of current areas of research where we are assessing materials properties and structures are (A) Shot peened surfaces for creating fatigue resistant structures (B) Mechanical characterization of complex nano- foams (C) Energetic and explosive materials tested in volumes that are safe to handle (D) Dual phase metal systems (E) Characterize adhesion of cytotoxic nanomaterials on polymeric supports for antimicrobial filtration membranes (F) Cracking and fracture of laser modified surfaces Testing dangerous and expensive, so it is often desirable to have an inert “mock material” that imitates the mechanical, chemical, and thermal properties of the explosive. Nanoindentation is a useful way to study and compare mechanical properties of these crystals such as hardness and elastic modulus, as well as cracking behavior. The pharmaceutical idoxuridine is very similar to the explosive HMX in hardness and elastic modulus, with respective elastic explosive molecular crystals can be very modulus values of 23.3 GPa and 25.2 GPa and each with a hardness value of 1 GPa. Cracking behavior is being studied by analyzing the unloading portion of the load-depth curves for each material using different geometries of indenter probes. Idoxuridine indented to a maximum load of 250 mN, resulting in fracture. Load-depth data comparison for HMX and idoxuridine indented to a maximum load of 1000 μN, showing similar mechanical response in each material. Metallic nano-foam is an extremely low-density metal that has very high surface-to-bulk ratio, and have been predicted to exhibit exceptional strength to weight ratios. Using advanced structural characterization tools, we investigate fundamental structure-property relations of this nano-foams. Assessment of the reliability of this exotic structural phase is crucial to developing any advanced applications. We use nanoscale mechanical testing in conjunction with accurate structural analyses to fully understand the structure-property relations of the nano-foams. Pathogenic microbes in water require clever combative techniques for prevention as well as control. Nanoscopic silver and copper are excellent antimicrobial agents with good physiological tolerance. Incorporating metallic nanoparticles on fibrous polymeric architectures creates a safe antibacterial water filtration membrane. The difference in molecular configurations of metals and polymers inevitably presents an adhesion challenge between these materials, undermining the functional application of fabricated membranes. Investigating bulk deformation behavior of metallized fibers as well as characterizing adhesion and delamination properties using surface probing functionality of the nanoindentation technique will help inform better design parameters. a) Nanoindentation pattern along the sample, b) nanoindentation pattern to measure residual stress indentation. Pulsed lasers can be used to modify a surface. They interact with metallic surfaces causing repeated heating/cooling cycles, which originates a network of microscopic cracks on the surface. This phenomenon also occurs in nature in drying mud (mud-flat cracking). These cracks do not alter the mechanical properties of the remaining metal. Metallic pipelines under water are very susceptible to the attack of bacteria (bio-corrosion), which bind to the surface forming biofilms. Antimicrobial peptides (AMP) can be infused into the cracks to confer antibacterial properties to the metal surface and, in this way, avoid its degradation. 1µm 0 50 100 150 200 0 200 400 600 800 1000 Load (uN) Depth (nm) HMX HMX Idoxuridine Idoxuridine HMX H = 1.00 GPa HMX Er = 25.2 GPa Idoxuridine H = 1.00 GPa Idoxuridine Er = 23.3 GPa SEM image of 10 *10 nanoindentation array on advanced high strength dual phase steel to distinguish between martensite and ferrite based on their mechanical properties differences. b a Indentation mark made after indenting Cu nano-foam, using cylindrical flat punch tip. Deformation mechanism of this extremely low density material can be evaluated using nano-indentation. Transmission electron microscopy images of the nano-foam showing pore structure. Corresponding centered dark field (CDF) image and selected area electron diffraction (SAED) pattern show the polycrystalline nature of this metallic nano-foam. Ti-6Al-4V after PL treatment. Cracks penetrate oxide film and substrate. Corroded steel pipelines covered by biofilms. (a) Bacteria grow on unprotected surface, (b) No bacteria on surface treated with AMP. Multiple and double side shot peening simulation, aluminum 7050. Shot peening on aircraft component to develop residual stress. (Image courtesy Wheelabrator Group.) The “Why” of Small Scale Indentation Testing Shot Peening for Surface Enhancement Mechanics of Energetics Metallic Nanofoams Antimicrobial Cracked Surfaces Metal-Polymer Composites for Water Filtration Applications SEM images of silver nanoparticles grown on polyacrylonitrile fibers. Copper particles on polycaprolactone fiber. (a) (b)
Transcript of Micromechanical Deformation & Characterization of Materials Gr… · The global market for all...
Mechanical surface treatments use cold working todevelop residual stresses on the substrate or in the bulk toenhance a material’s mechanical properties. Materials thatare mechanically surface treated tend to have increasedservice lifetimes and resist wear and fatigue. Shot peeningis one of the well-established methods to inducecompressive residual stresses in the metallic componentsfor the cold working purposes.
Finite element simulation and nanoindentation methodscan be used to study the elastic-plastic deformation andmechanical behaviors after shot peening process todetermine residual stress profile.
Micromechanical Deformation & Characterization of Materials
Graduate students: Jesus Hector Morales, Raheleh Mohammad Rahimi, Siavash Ghanbari, Kim Chang-Eun, Alexandra Burch, Temitope Q Aminu, Zara Molaeinia, David Brice Faculty Advisor: Prof. David F. Bahr
The ability to characterize the mechanical properties of materials at the nanoscale has become a crucial component of the research and development in nanoscienceand nanotechnologies. Such ability addresses themes relevant across a number of manufacturing and processing sectors such as semiconductor industry, lifesciences, electronics and biomaterials. The global market for all types of materials characterization instrument was worth an estimated $20.3 billion in 2003. Ourgroup works on linking the structure of a wide range of classes of materials and processing with the subsequent micromechanical behavior, including elastic,plastic, and fracture properties.
.
Characterization of the mechanical response ofmaterials under nanoindentation (load-displacementmonitored indentation), when coupled with scanningprobe microscopy can be used to test small volumes ofmaterials that are either(1)Small because the sample is small, or(2) Features in the material are small (such as second
phase particles).Nanoindentation is one of the fundamental tools usedwithin our group to explore diverse materials, eitherexperimentally or coupled with computationalmodeling. Some examples of current areas of researchwhere we are assessing materials properties andstructures are(A) Shot peened surfaces for creating fatigue resistant
structures(B) Mechanical characterization of complex nano-
foams(C) Energetic and explosive materials tested in
volumes that are safe to handle(D) Dual phase metal systems(E) Characterize adhesion of cytotoxic nanomaterials
on polymeric supports for antimicrobial filtrationmembranes
(F) Cracking and fracture of laser modified surfaces
Testing dangerous and expensive, so it is often desirableto have an inert “mock material” that imitates themechanical, chemical, and thermal properties of theexplosive. Nanoindentation is a useful way to study andcompare mechanical properties of these crystals such ashardness and elastic modulus, as well as crackingbehavior. The pharmaceutical idoxuridine is very similarto the explosive HMX in hardness and elastic modulus,with respective elastic explosive molecular crystals canbe very modulus values of 23.3 GPa and 25.2 GPa andeach with a hardness value of 1 GPa. Cracking behavioris being studied by analyzing the unloading portion of theload-depth curves for each material using differentgeometries of indenter probes.
Idoxuridine indented to a maximum load of 250 mN, resulting in fracture.
Load-depth data comparison for HMX and idoxuridine indented to a maximum load of 1000 μN, showing similar mechanical response in each material.
Metallic nano-foam is an extremely low-density metalthat has very high surface-to-bulk ratio, and have beenpredicted to exhibit exceptional strength to weight ratios.Using advanced structural characterization tools, weinvestigate fundamental structure-property relations ofthis nano-foams.
Assessment of the reliability of this exotic structuralphase is crucial to developing any advanced applications.We use nanoscale mechanical testing in conjunction withaccurate structural analyses to fully understand thestructure-property relations of the nano-foams.
Pathogenic microbes in water require clever combativetechniques for prevention as well as control. Nanoscopicsilver and copper are excellent antimicrobial agents withgood physiological tolerance. Incorporating metallicnanoparticles on fibrous polymeric architectures creates asafe antibacterial water filtration membrane. The differencein molecular configurations of metals and polymersinevitably presents an adhesion challenge between thesematerials, undermining the functional application offabricated membranes. Investigating bulk deformationbehavior of metallized fibers as well as characterizingadhesion and delamination properties using surfaceprobing functionality of the nanoindentation technique willhelp inform better design parameters.
a) Nanoindentation pattern along the sample, b) nanoindentation pattern to measure residual stress indentation.
Pulsed lasers can be used to modify a surface. Theyinteract with metallic surfaces causing repeatedheating/cooling cycles, which originates a network ofmicroscopic cracks on the surface. This phenomenon alsooccurs in nature in drying mud (mud-flat cracking).
These cracks do not alter the mechanical properties of theremaining metal. Metallic pipelines under water are verysusceptible to the attack of bacteria (bio-corrosion),which bind to the surface forming biofilms.Antimicrobial peptides (AMP) can be infused into thecracks to confer antibacterial properties to the metalsurface and, in this way, avoid its degradation.
1µm
0 50 100 150 200
0
200
400
600
800
1000
Load
(uN
)
Depth (nm)
HMX HMX Idoxuridine Idoxuridine
HMX H = 1.00 GPaHMX Er = 25.2 GPaIdoxuridine H = 1.00 GPaIdoxuridine Er = 23.3 GPa
SEM image of 10 *10 nanoindentation array on advanced high strength dual phase steel to distinguish between martensite and ferrite based on their mechanical properties differences.
b
a
Indentation mark made after indenting Cu nano-foam, using cylindrical flat punch tip.Deformation mechanism of this extremely low density material can be evaluated using nano-indentation.
Transmission electron microscopy images of the nano-foam showing pore structure. Corresponding centereddark field (CDF) image and selected area electron diffraction (SAED) pattern show the polycrystalline nature ofthis metallic nano-foam.
Ti-6Al-4V after PL treatment. Cracks penetrate oxide film and substrate.
Corroded steel pipelines covered by biofilms. (a) Bacteria grow on unprotected surface, (b) No bacteria on surface treated with AMP.
Multiple and double side shot peening simulation, aluminum 7050.
Shot peening on aircraft component to develop residual stress. (Image courtesy Wheelabrator Group.)
The “Why” of Small Scale Indentation Testing
Shot Peening for Surface Enhancement
Mechanics of Energetics
Metallic Nanofoams
Antimicrobial Cracked Surfaces
Metal-Polymer Composites for Water Filtration Applications
SEM images of silver nanoparticles grown on polyacrylonitrile fibers.
Copper particles on polycaprolactone fiber.
(a) (b)
