Small Scale Fracture Mechanisms in Alloys with Varying Microstructural Complexity

Jha, Shristy

07 1900

Small-scale fracture behavior of four model alloy systems were investigated in the order of increasing microstructural complexity, namely: (i) a Ni-based Bulk Metallic Glass (Ni-BMG) with an isotropic amorphous microstructure; (ii) a single-phase high entropy alloy, HfTaTiVZr, with body centered cubic (BCC) microstructure; (iii) a dual-phase high entropy alloy, AlCoCrFeNi2.1, with eutectic FCC (L12) -BCC (B2) microstructure; and (iv) a Medium-Mn steel with hierarchical microstructure. The micro-mechanical response of these model alloys was investigated using nano-indentation, micro-pillar compression, and micro-cantilever bending. The relaxed Ni-BMG showed 6% higher hardness, 22% higher yield strength, and 26% higher bending strength compared to its as-cast counterpart. Both the as-cast and corresponding relaxed BMGs showed stable notch opening and blunting during micro-cantilever bending tests rather than unstable crack propagation. However, pronounced notch weakening was observed for both the structural states, with the bending strength lower by ~ 25% for the notched samples compared to the un-notched samples. Deformation behavior of HfTaTiVZr was evaluated by micropillar compression and micro-cantilever bending as a function of two different grain orientations, namely [101] and [111]. The [111] oriented micropillars demonstrated higher strength and strain hardening rate compared to [101] oriented micropillars. The [111] oriented micropillars showed transformation induced plasticity (TRIP) in contrast to dislocation-based planar-slip for the [101] oriented micropillars, explaining the difference in strain hardenability for the two orientations. These differences in deformation behavior for the two orientations were explained using Schmid factor calculations, transmission electron microscopy, and in-situ deformation videos. For the dual-phase AlCoCrFeNi2.1 high entropy alloy, the L12 phase exhibited superior bending strength, strain hardening, and plastic deformation, while the B2 phase showed limited damage tolerance during bending. The microstructure and deformation mechanisms were characterized for a few different medium-Mn steels with varying carbon (0.05-0.15 at%) and manganese (5-10 at%) content. The alloy with 10 at% Mn and 0.15 at% C (1015 alloy) showed hierarchical microstructure of retained austenite and ferrite with lamellae 200 nm to 300 nm wide. Micro-pillar compression at different strain levels for this alloy revealed that deformation in austenite is primarily accommodated through transformation to martensite, thereby increasing the strain hardening rate.

Small Scale fracture

Micro-cantilever bending

Micro-pillar compression

Engineering, Materials Science

Variable Speed Flapping Wing Micro Air Vehicle using a Continuous Variable Transmission Design

Chuang, Jason C.

04 June 2014

No description available.

Aerospace Engineering

MAV

flapping wing micro air vehicle

FWMAV

Human Micro-Range/Micro-Doppler Signature Extraction, Association, and Statistical Characterization for High-Resolution Radar

Fogle, Orelle Ryan

21 June 2011

No description available.

Electrical Engineering

Remote Sensing

radar

dismount

micro-Doppler

micro-range

radar cross-section

Enhanced Heat Transfer in Micro-Scale Heat Exchangers Using Nano-Particle Laden Electro-osmotic Flow (EOF)

Al-Rjoub, Marwan Faisal

10 September 2015

No description available.

Mechanics

Electro-osmotic flow

Micro-scale heat exchanger

Thermal management

Micro-pump

Visualizing and Understanding Complex Micro/Nanofluidic Flow Behavior

Hemminger, Orin L.

03 September 2010

No description available.

Chemical Engineering

micro-fluidics

nano-fluidics

DNA visualization

non-Newtonian

micro-contraction

Detecting and mitigating software security vulnerabilities through secure environment programming

Blair, William

26 March 2024

Adversaries continue to exploit software in order to infiltrate organizations’ networks, extract sensitive information, and hijack control of computing resources. Given the grave threat posed by unknown security vulnerabilities, continuously monitoring for vulnerabilities during development and evidence of exploitation after deployment is now standard practice. While the tools that perform this analysis and monitoring have evolved significantly in the last several decades, many approaches require either directly modifying a program’s source code or its intermediate representation. In this thesis, I propose methods for efficiently detecting and mitigating security vulnerabilities in software without requiring access to program source code or instrumenting individual programs. At the core of this thesis is a technique called secure environment programming (SEP). SEP enhances execution environments, which may be CPUs, language interpreters, or computing clouds, to detect security vulnerabilities in production software artifacts. Furthermore, environment based security features allow SEP to mitigate certain memory corruption and system call based attacks. This thesis’ key insight is that a program’s execution environment may be augmented with functionality to detect security vulnerabilities or protect workloads from specific attack vectors. I propose a novel vulnerability detection technique called micro-fuzzing which automatically detects algorithmic complexity (AC) vulnerabilities in both time and space. The detected bugs and vulnerabilities were confirmed by vendors of real-world Java libraries. Programs implemented in memory unsafe languages like C/C++ are popular targets for memory corruption exploits. In order to protect programs from these exploits, I enhance memory allocators with security features available in modern hardware environments. I use efficient hash algorithm implementations and memory protection keys (MPKs) available on recent CPUs to enforce security policies on application memory. Finally, I deploy a microservice-aware policy monitor (MPM) that detects security policy deviations in container telemetry. These security policies are generated from binary analysis over container images. Embedding MPMs derived from binary analysis in micro-service environments allows operators to detect compromised components without modifying container images or incurring high performance overhead. Applying SEP at varying levels of the computing stack, from individual programs to popular micro-service architectures, demonstrates that SEP efficiently protects diverse workloads without requiring program source or instrumentation.

Computer science

Architectural security

Cloud security

Fuzz testing

Micro-execution

Micro-fuzzing

Microservices

Optical Fiber Microstructures for Self-Contained Whispering Gallery Mode Excitation

Fraser, Michael John

02 May 2016

Optical resonators, which confine light by resonant recirculation, serve as the basis for a wide variety of optical components. Though they appear in many geometric forms, the most effective of optical resonators show axial symmetry in at least one dimension. A popular variation that finds broad application is the dielectric sphere. Acclaimed for their high quality (Q) factor and small modal volume, spheres owe credit of these attractive features to their support of whispering gallery mode (WGM) resonances. The sensitivity of a resonance's frequency and Q to strain, temperature, and other parameters of the surrounding medium can be the basis for ultracompact modulators and sensors. Physically, WGMs are special optical modes which can be understood as light rays that orbit the equator of the sphere guided by total internal reflection. Like a smooth stone can be skipped along the surface of a pond, light can be confined to the inside of a sphere by successive reflections. To best excite WGMs, the source light should initially trace a line tangent to the sphere's circumference. But incorporating a tiny sphere with such nanometric tolerances into a practical sensor structure has its challenges and the prospects for microsphere applications have suffered because of the plight of this problem. The work in this dissertation details the fabrication and function of three new "press fit" spherical resonators. These etched fiber micro-devices were developed to meet the demand for a robust, self-integrated means of coupling light between an optical fiber and WGMs in a microsphere resonator. The etching processes have been tuned to enable secure storage of a microsphere while also providing efficient excitation and interrogation of WGMs. Furthermore, the methods have been designed to be staightforward, quick, and repeatable. Using standard etchants on common polarization-maintaining fiber with readily purchased microspheres, the press fit resonators demonstrated here can be batch-fabricated and assembled. The press fit spherical resonator offers an alignment-free and conveniently pigtailed WGM coupler that has great potential for bio-science sensing applications and studies of resonant bispheres. / Ph. D.

Resonators

Whispering Gallery Modes

Fiber Optics Sensors

Micro-devices

Micro-fabrication

Wet Chemical Etching

Theoretical and Experimental Investigations on Microelectrodeposition Process

Haghdoost, Atieh

09 September 2013

Electrodeposition is one of the main techniques for fabricating conductive parts with one or two dimensions in the micron size range. This technique is utilized to coat surfaces with protective films of several micrometers thickness or fabricate standalone microstructures. In this process, an electrochemical reaction occurs on the electrode surface by applying an electric voltage, called overpotential. Different electrochemical practices were presented in the literature to obtain kinetic parameters of an electrochemical reaction but most of these practices are hard to implement for the reactions occur on a microelectrode. Toward addressing this issue, the first part of the dissertation work presents a combined experimental and analytical method which can more appropriately provides for the kinetic measurement on a microelectrode. Another issue which occurs for electrodeposition on microscale recessed areas is the deviation of the profile of the deposition front from the substrate shape. Non-uniform deposition front usually obtains for a deposit evolved from a flat substrate with microscale size. Consequently, a subsequent precision grinding process is required to level the surface of the electrodeposited microparts. In order to remove the need for this subsequent process, in the second and third parts of the dissertation work, multiphysics modeling was used to study the effects of the fabrication parameters on the uniformity of the deposit surface and suggest a design strategy. Surface texture of the deposit is another parameter which depends on the fabrication parameters. Several important characteristics of the electrodeposited coating including its wettability depend on the surface texture. The next part of the dissertation work presents an experimental investigation and a theoretical explanation for the effects of the overpotential and bath concentration on the surface texture of the copper deposit. As a result of this investigation, a novel two-step electrodeposition technique is developed to fabricate a superhydrophobic copper coating. In the last part of the dissertation work, similar investigation to the previous sections was presented for the effects of the fabrication parameters on the crystalline structure of the deposit. This investigation shows that nanocrystalline and superplastic materials can be fabricated by electrodeposition if appropriate fabrication parameters are applied. / Ph. D.

Electrochemistry

Multiphysics Modeling

Micro/Nano Fabrication

Micro/Nano Electrochemical Systems

Nanoscale Characterization

Development of Bio-Impedance microprobes for Integration with a Smart Biopsy tool

Jayabalan, Vivek

14 November 2014

Biopsy is a standard practice in the diagnosis and treatment of many cancers. Despite its integral role in cancer diagnosis, in some instances, the biopsy tool facilitates metastasis by transferring cancerous cells attached to its exterior into the healthy tissue or the blood circulation during its retraction from the tumor. These few cancer cells can then serve as seeds for the malignant tumor to grow in the healthy tissue. Cauterization using extreme heat or cold can destroy cells in the region and minimize the chance of seeding but this can be an inexact process that increases damage to otherwise healthy tissue and prolongs healing time following a biopsy procedure. In our laboratory, we have developed the concept of a new smart biopsy tool that can reduce the chance of cancer cell dissemination during a biopsy. This tool improves on the conventional biopsy needle by introducing an impedance sensor on the biopsy tool which is housed in a sliding sheath. Due to the significant difference in the electrical conductivity of the tumor and the healthy tissue, the sensor is able to distinguish between the two and locate the exact tumor interface. The protective sheath placed around the instrumented biopsy tool and above the interface isolates the healthy tissue and prevents or at least minimizes the transfer of tumor cells. Delivering an RF dose through the sheath can kill any malignant cells that might be lurking around the interface. This thesis, in particular, will concentrate on the development of the design, fabrication and calibration of the impedance sensor and its integration with the biopsy tool. The impedance sensor essentially consists of conductive electrodes sandwiched between insulating layers. They are built on thin-film polymer, Polyimide, using conventional microfabrication techniques. These sensors are further calibrated to estimate the cell constant. Once calibrated, these probes are used to measure the conductivity of porcine tissues, and in-house prepared agar phantoms. / Master of Science

Bio-Impedance Micro Probes

Smart Biopsy tool

Cancer Cell Seeding

Prevention

Micro fabrication

Polyimide

Pressure losses experienced by liquid flow through straight PDMS microchannels of varying diameters

Wright, Darrel W.

01 January 2010

The field of microfluidics has the potential to provide a number of products to better everyday life, but is still not well understood. In previous research performed in the field, microfluidics has been shown to exhibit behavior different from what would be expected through normal pipe flow theory. While some research has shown that fluid flow through microchannels does conform to the theoretical flow mechanics, and thus can be predicted and understood through use of well-known relations; other research performed has indicated that fluid flow through microchannels experiences higher or lower pressure losses than would be expected with macro scale theory. This work strives to further explore and explain this anomaly by focusing on simple straight rectangular channels of varying hydraulic diameters from 24 µm to 88 µm, in order to form a more basic understanding for fluid flow in microchannels. Water was pumped through each of these channels at a number of different flow rates, and the static pressure was measured in two locations, a set length apart. The measured pressure loss over this length for each flow rate was then recorded and analyzed to provide relations between pressure loss and hydraulic diameter. Through the data obtained in this study, microfluidic flow of Reynolds numbers greater than 40 and in channels as small as 48 µm in diameter experienced pressure losses predicted from macroscale theory. Below these values, the data was more random, but still showed some conformance to theory. A clear relationship between measured pressure loss and hydraulic diameters over the entire range of channels was also found for two different flow rates. It is hoped that the data obtained will provide a better understanding of microfluidics and pave the way for potential applications to be realized.

Mechanical Engineering