Fabrication And Thermoelectric Characterization Of Stretchable Conductive Latex-Based Composites

Arcovitch, Cory Michael

01 January 2017

Miniaturized stretchable electronic devices that can be bent and strained elastically without breaking, have drawn considerable research interest in recent years for wearable computers and integrated bio-sensor applications. Portable electrical power harvesting remains a critical challenge in flexible electronics materials. One proposed solution has been to convert waste heat from the human body into electricity using thermoelectric materials. Traditionally, however, these materials are brittle ceramic semiconductors with limited fracture resistance under deformation. The primary objective of this thesis is to address this challenge by fabricating and studying the mechanical, thermal and electrical performance of stretchable composites combining natural latex polymer with either metallic (Ni) or thermoelectric (InSb) powders. Ni-based and InSb-based latex specimens were synthesized with different powder concentrations up to 36 vol.%. The effects of the powder concentration on tensile elongation, electrical conductivity, and thermal conductivity of the composites were measured at ambient temperature. Strong dependences of mechanical and electrical properties on powder concentration were found. By contrast, thermal conductivity was observed to remain low at all concentrations, suggesting that the predominant heat transport process is through the low-conductivity latex matrix rather than the conductive particles. This thesis was conducted with the support of a Vermont Space Grant Consortium graduate research assistantship.

Composite

Flexible

InSb

Latex

Stretchable

Thermoelectric

Mechanical Engineering

Mechanics of Materials

High tensile steel as normal reinforcement in concrete

Attisha, H. P.

January 1972

The use of high tensile steel as normal reinforcement in concrete members necessitates the study of the behaviour of such members under the action of static, fatigue and sustained loading. The present state of knowledge of the effects of the type of steel and the type of loading on the serviceability and strength of concrete members has been reviewed. From a comparison of structures reinforced with ordinary and high tensile steels, it has been indicated that by increasing the permissible steel stresses great savings can be obtained, but the deflection and cracking become more pronounced, especially when the effects of long-term loading are considered. Limited information has been reported on the effect of the static cyoles, subsequent to the first cycle, on these two limit states. In view of the above, the applicability of the limit state design, and the study of the recommendations of codes of practice of several countries, it was felt that an experimental investigation was required to study the behaviour, in cracking and deflection, of concrete members reinforced with hiEýi tensile steel and subjected to static, fatigue and sustained loading. A programme of an experimental investigation was designed to study the behaviour of reinforced concrete beams.

624.1

Seaweed to Sealant : Multifunctional Polysaccharides for Regenerative Medicine and Drug Delivery Applications

Fenn, Spencer Lincoln

01 January 2017

Pneumothorax, or a collapsed lung, is a serious medical condition resulting when air or fluid escapes the lung into the chest cavity and prevents the lung from inflating. Few viable means of sealing the damaged and leaking tissues are currently available, leading to longer hospital stays, multiple interventions, and increasing costs of care. The motivation of this dissertation is to engineer a novel polysaccharide-based therapeutic surgical sealant, which can be utilized to seal trauma-induced damage to the outer lining of the lung, i.e. pleura, preventing or reversing lung collapse to restore normal breathing function. The use of polysaccharides, such as alginate and hyaluronan, has become increasingly prevalent in biomedical and tissue engineering applications due to the ability to add functionality through chemical modification, allowing for tunable mechanical and physical properties. These hydrophilic polymer chains can be crosslinked to form hydrogels, which can retain large volumes of water and can mimic the properties of tissues found within the body. In this work, polysaccharide hydrogel sealants were engineered with well-regulated gelation and mechanical properties, and further modified to achieve adhesion to biological tissues. This was accomplished by mimicking the mechanical and physical properties of the complex tissues, and crosslinking the hydrogels in situ using a visible light-initiated system. Methacrylated alginate and oxidized alginate were successfully synthesized and utilized to fabricate adhesive sealant patches, which can adhere and seal damaged tissues in vivo. Methacrylation was implemented to allow covalent photo-crosslinking between adjacent polymer chains in solution. Here, a novel anhydrous chemistry was developed to allow for precise control over the degree of methacrylation and thus tune the mechanical properties of the resulting hydrogels by modulating the number of crosslinkable side-groups attached to the polysaccharide chain. To increase the adhesive properties of the resulting hydrogels, oxidation of the polysaccharide chain was subsequently implemented to form functional aldehyde groups capable of protein interactions through the formation of imine bonds on biological tissue surfaces. To test the performance of this multifunctional material, burst pressure testing was executed, revealing the relationship between the two distinct chemical modifications performed and the mechanical and adhesive properties of the resulting sealant. In addition, methacrylated alginate was utilized to synthesize therapeutic, drug-encapsulating hydrogel nanoparticles, which when incorporated within the polysaccharide-based surgical sealant allow for local drug release. The ability to control drug release at the site of application further broadens the potential uses of this surgical sealant patch and will be discussed further within this dissertation.

aldehyde

alginate

drug delivery

polysaccharide

sealant

Mechanics of Materials

Buoyancy driven flow in porous media applied to heat storage and carbon sequestration

Dudfield, Peter

January 2015

No description available.

550

Development And Characterization Of Multi-Crosslinking Injectable Hydrogels For Use In Cell And Drug Delivery

Etter, Jennifer

01 January 2019

Injectable hydrogels are important for use in tissue engineering due to their permeability and biocompatibility. Those that have shear thinning properties allow for minimally-invasive surgical procedures and a way to administer bioactive agents, and therapeutic cells by injection. Currently available injectable hydrogels have a single or dual input/stimulus for crosslinking which limits the range of mechanical properties and often utilize potentially toxic ultraviolet radiation that reduces viability of injected cells. To overcome these shortcomings, a tri-stimuli-responsive alginate-based injectable hydrogel was developed based on: 1) supramolecular complex formation between β-cyclodextrin (β-CD) conjugated alginate and thermo-responsive tri-block Pluronic® copolymers, 2) visible light crosslinking via acrylate conjugation, and 3) ionic crosslinking of the alginate backbone via exposure to calcium chloride. The capabilities of the novel multi-stimuli injectable hydrogel were demonstrated with a custom microfluidic devices (MFDs) to create microspheres encapsulating human mesenchymal stem cell (MSCs). These experiments proved that the new hydrogel was capable of serving as a stimuli responsive material for MSC cell delivery in the therapeutic range of 10-1000 µm in diameter. In order to enhance the drug delivery capabilities of the hydrogel, heparin sodium was conjugated onto the alginate backbone. The affinity of the growth factor, vascular endothelial growth factor (VEGF), to the heparin helped to prevent denaturing of the protein and improved vascularization. This new tri-crosslinking hydrogel with conjugated heparin allows the end-user to control the final physicomechanical and biochemical properties of the hydrogel using different external stimuli. The tri-crosslinking hydrogel is a versatile material that has great promise for a variety of soft tissue repair applications.

Alginate

Drug Delivery

Hydrogel

Injectable

Stem Cell

Mechanics of Materials

Atomistic Simulation Studies Of Grain-Boundary Segregation And Strengthening Mechanisms In Nanocrystalline Nanotwinned Silver-Copper Alloys

Ke, Xing

01 January 2019

Silver (Ag) is a precious metal with a low stacking fault energy that is known to form copious nanoscale coherent twin boundaries during magnetron sputtering synthesis. Nanotwinned Ag metals are potentially attractive for creating new interface-dominated nanomaterials with unprecedented mechanical and physical properties. Grain-boundary segregation of solute elements has been found to increase the stability of interfaces and hardness of nanocrystalline metals. However, heavily alloying inevitably complicates the underlying deformation mechanisms due to the hardening effects of solutes, or a change of stacking fault energies in Ag caused by alloying. For the above reasons, we developed a microalloying (or doping) strategy by carefully selecting Cu as the primary impurity – a solute that is predicted to have no solid-solution strengthening effect in Ag when its content is below 3.0 wt.%. Neither will Cu affect the stacking fault energy of Ag at a concentration <1.0 wt.%. Moreover, Cu atoms are ~12% smaller than Ag ones, and Ag-Cu is an immiscible system, which facilitates the segregation of Cu into high-energy interface sites such as grain-boundaries and twin-boundary defects. In this thesis, large-scale hybrid Monte-Carlo and molecular dynamics simulations are used to study the unexplored mechanical behavior of Cu-segregated nanocrystalline nanotwinned Ag. First, the small-scale mechanics of solute Cu segregation and its effects on incipient plasticity mechanisms in nanotwinned Ag were studied. It was found that solute Cu atoms are segregated concurrently to grain boundaries and intrinsic twin-boundary kink-step defects. Low segregated Cu contents (< 1 at.%) are found to substantially increase twin-defect stability, leading to a pronounced rise in yield strength at 300 K. Second, atomistic simulations with a constant grain size of 45 nm and a wide range of twin boundary spacings were performed to investigate the Hall-Petch strength limit in nanocrystalline nanotwinned Ag containing either perfect or kinked twin boundaries. Three distinct strength regions were discovered as twin boundary decreases, delineated by normal Hall-Petch strengthening with a positive slope, the grain-boundary-dictated mechanism with near-zero Hall-Petch slope, and twin-boundary defect induced softening mechanism with a negative Hall-Petch slope. Third, by systematically studying smaller grain sizes, we find that the “strongest” size for pure nanotwinned Ag is achieved for a grain size of ~16 nm, below which softening occurs. The controlling plastic deformation mechanism changes from dislocation nucleation to grain boundary motion. This transition decreases to smaller grain sizes when Cu contents are segregated to the interfaces. Our simulations show that continuous Hall-Petch strengthening without softening, down to grain sizes as small as 6 nm, is reached when adding Cu atoms up to 12 at. %. For Cu contents ≥ 15 at. %, however, the predominant plastic deformation mechanism changes to shear-band induced softening. The present thesis provides new fundamental insights into solute segregation, and strengthening mechanisms mediated by grain boundaries and twin boundaries in face-centered cubic Ag metals, which is expected to motivate experimental studies on new nanotwinned metals with superior mechanical properties controlled by microalloying.

Atomistic simulation

Atom segregation

Nanotwinned silver

Plasticity

Strength

Mechanics of Materials

Design, Prototyping And Fabrication Of Powder Spray Device For Dehydrated Biological Particulates

Reilly, James

01 January 2019

Tissue sealants of a liquid based formulation are widely studied in biomedical research with many starting to gain FDA approval. To date, little investigation has been put toward methods of application for tissue sealant materials, more specifically a powder based formulation. The focus of this research was to develop and prototype a powder spray device capable of administering powder based formulations with a long-term goal of integrating the device within the clinical setting. Powders can be administered in a variety of dry forms. These forms can range from non-homogenous nanoscale particles to homogeneous micro and nano-scale spheres. Incorporation of therapeutics within the powder makes this method of application favorable for the prevention or maintenance of disease. Pneumatic conveying is the transport of granulated solids using gas and is the principal basis from which the powder spray gun was designed. Fluidization aids were added to the device in order to increase powder flow properties. Analysis of spray field, spray rate, characterization of powder and ex-vivo testing was performed. All results suggest that the powder spray device is applicable for the deposition of powder based tissue sealants in a clinical setting.

Hydrogel

Powder

Spray Device

Tissue Sealant

Mechanical Engineering

Mechanics of Materials

Inferring traffic induced sediment production processes from forest road particle size distributions /

Rhee, Hakjun.

January 2006

Thesis (Ph. D.)--University of Washington, 2006. / Vita. Includes bibliographical references (leaves 191-196).

High strength steel reinforcement in ordinary reinforced and fibre reinforced cement composite lightweight concrete beams

Al-Sanjary, K. A. A.

January 1975

When high strength steel is used as reinforcement in lightweight concrete members, great economies can be achieved. However, because lightweight concrete has low tensile strength and modulus of elasticity, the working steel stresses hoped for may not be fully utilised due to the limit states of serviceability (cracking and deflection) not being satisfied. To control the amount of cracking and deflection in flexural concrete members, a new type of construction has been employed, whereby precast fibre reinforced cement (f. r. c) units in the form of thin channels are used as a surface reinforcement at the flexural tensile zone of the concrete members. The concrete in the tensile zone, confined by the f. r. c channel, will have a greater resistance to formation and extension of crack; consequently the rate of reduction in the flexural rigidity of the member will be decreased. A total of 27 ordinary reinforced and fibre reinforced cement composite lightweight concrete beams, 150mm wide, 300mm deep and 5m long were tested, 18 under static load test, 5 under fatigue load test and 4 under sustained load test. The composite beams were similar to the ordinary beams in every respect, except that f. r. c. channels (150mm width, 60mm length of upstands and 6mm thickness) were incorporated as integral parts on their flexural tensile sides. The main parameters employed for both beams were the type and amount of steel provided for the tension reinforcement. The various types of reinforcement with the corresponding nominal yield, or 0.2% proof stress employed were mild steel (275 N/mm2), Unisteel 410 (410 N/mm2), Unisteel 550 (550 N/mm2), "Kam 60" (590 N/mm2) and "Kam 90" (875 N/mm2). The flexural behaviour of both types of beams under static, fatigue and sustained types of loading has been studied, great emphasis being placed upon the limit states of ultimate strength, cracking and deflection with particular reference to the contribution of the f. r. c. channels in the composite beams. From the results, it is concluded that a considerable reduction in the amount of deflection and cracking can be achieved by using f. r. c. channels at the flexural tensile zone of concrete members, thus allowing a more efficient use of the highstrength steel.

624

Optical spectroscopy of two-dimensional hole systems in the quantum limit

Townsley, Christopher Mark

January 1999

No description available.

530.41