Comparison of 500 Solid Copper Bullets and an Analysis of their Influence on the Individual Rifling Characteristics of Firearms

Torres Garcia, Christine

16 March 2019

<p> This study examines whether 500 solid copper bullets fired from a 9mm firearm would have a significant effect on the individual rifling characteristics of the barrels of a Glock Model 17, a Beretta Model M9, and a Taurus Model PT 92 AF. Five silicone casts of each barrel bore were prepared over the course of this study. The casts were used to compare and evaluate the wear on the rifling of each barrel and note any changes that may have occurred during the progression of the study. The bullets were purchased as reloading components and were tested for hardness in addition to Energy Dispersive Spectroscopy (EDS) analysis. The bullets used for examination were collected at the start, throughout the experiment, and after the firearm had been cleaned following the 500 firings. The bullets, as well as barrel casts, were analyzed using a Leica FS C comparison microscope. Results from the analysis indicate the bullets do not obturate and they do not engage with the grooves of each barrel. Analysis of land impressions show striations that deteriorate or disappear completely; while others appear over the course of firing the 500 copper bullets. Regarding the influence of the bullet wear on the individual rifling characteristics, the striations of each firearm barrel were permanently changed to the point where bullet identification no longer was possible.</p><p>

Forensic anthropology|Materials science

Finite element analysis of composites integral armour

El-Habti, Mohamed

January 2010

This thesis is focussed on a numerical method to analyse the ballistic performance of multi-material armour system. The overall objective of this work is to develop numerical models to be used within MSC. DYTRAN capable of accurately predicting the ballistic response of multi-material composite armour, the effect of impact type on the damage and to help improve the armour design. The research presented in this thesis includes a review of the existing ceramic and composite damage models, combine, modify and optimize them to investigate the type and extent of damage response of the materials used in ballistic protection. The numerical model leads to insight into the parameters governing the penetration and deformation response of laminated composite subjected to ballistic impact. The effect of various model parameters on the predicted ballistic response of the ballistic plate is intensively investigated. It was found that the through thickness properties used in the numerical model have a large effect on the predicted ballistic response. A detailed study of the effect of mesh density on the numerical solution has shown that the numerical predictions are highly influenced by the element shape and size. The smaller the element the sooner the failure occurs, the less energy is absorbed and the smaller the time step becomes leading to a larger simulation time. The accuracy of the composite numerical model was evaluated by comparing the numerical prediction to experimental data obtained from ballistic impact trials. Very good agreement has been found between the experimental and numerical results for both observations of damage and deformation. Further, values of measured ballistic limit are in very good agreement with the values gained from the simulations. This correlation forms a verification of our finite element simulations. Fibre breakage is generally acknowledged as the main energy absorption mechanism in damage due to ballistic impact; in this work the delamination and matrix failure have been shown to increasingly contribute to the energy absorption mechanism by reducing the matrix strength. Further study of multi-layered ceramic composite armour has shown that use of ceramic tiles can improve the ballistic protection of the armour within an optimum ceramic composite ratio. Finite element simulation has been shown to be a very powerful technique to predict the behaviour of composite and ceramic panels under ballistic impact.

620.110287

Materials Science

Spatial mechanical behaviour of skin

Kao, Alexander Peter

January 2016

Skin is a complex biological composite system that serves as the outermost barrier to the environment and is mechanically robust. Understanding the mechanical properties of skin is important to improve and compare current in vitro experiments to the physiological conditions as the mechanical properties have a crucial role in determining cell behaviour. The mechanical behaviour of skin at the cellular level is expected to be dominated by the collagen fibre network within the dermis, which displays an anisotropic mechanical response to macroscopic loading. However, the three dimensional mechanical properties of skin at the nanoscale are not well understood. The aim of this work is to examine the mechanical properties of skin at the nanoscale in three dimensions and explore the links between the nanoscale and the macroscopic behaviour. Multiple sample preparation techniques are employed to expose the different layers of skin for mechanical testing and the elastic modulus of skin is evaluated by using atomic force microscopy (AFM) nanoindentation. The effect of freezing skin to cryogenic temperatures on the mechanical properties is evaluated and found to have no impact on the mechanical response of skin, indicating that the composition and structure of skin are robust enough to withstand the cryosectioning sample preparation methods used to expose the transverse layers of skin. AFM indentation was used to evaluate the elastic modulus of the dermis depending on the orientation of the sample and found to have an isotropic mechanical response. This result is opposite to anisotropy observed in macroscopic skin due to small scale mechanical testing ignoring collagen fibril orientation during strain. The variations in the elastic modulus of skin are also evaluated by AFM indentation at high spatial resolution to construct a composite model of the mechanical behaviour of skin at the nanoscale to predict the macroscopic response. The AFM nanoindentation technique was extended to evaluate the mechanical properties of a cell derived matrix deposited on an electrospun nanofibre scaffold, where the results indicate increasing the nanofibre diameter produces a cell derived matrix with an increased elastic modulus for more effective scaffolds. This work highlights the use of AFM mechanical testing to evaluate the nanoscale mechanical behaviour of skin, treated as a composite biological system, and determine the influence of the length scale and sample orientation on the observed mechanical response.

Engineering and Materials Science

Low variance methods for Monte Carlo simulation of phonon transport

Péraud, Jean-Philippe M. (Jean-Philippe Michel)

January 2011

Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 2011. / Cataloged from PDF version of thesis. / Includes bibliographical references (p. 95-97). / Computational studies in kinetic transport are of great use in micro and nanotechnologies. In this work, we focus on Monte Carlo methods for phonon transport, intended for studies in microscale heat transfer. After reviewing the theory of phonons, we use scientific literature to write a Monte Carlo code solving the Boltzmann Transport Equation for phonons. As a first improvement to the particle method presented, we choose to use the Boltzmann Equation in terms of energy as a more convenient and accurate formulation to develop such a code. Then, we use the concept of control variates in order to introduce the notion of deviational particles. Noticing that a thermalized system at equilibrium is inherently a solution of the Boltzmann Transport Equation, we take advantage of this deterministic piece of information: we only simulate the deviation from a nearby equilibrium, which removes a great part of the statistical uncertainty. Doing so, the standard deviation of the result that we obtain is proportional to the deviation from equilibrium. In other words, we are able to simulate signals of arbitrarily low amplitude with no additional computational cost. After exploring two other variants based on the idea of control variates, we validate our code on a few theoretical results derived from the Boltzmann equation. Finally, we present a few applications of the methods. / by Jean-Philippe M. Péraud. / S.M.

Materials Science and Engineering.

Novel molecular architectures from iptycene polymers

Tsui, Nicholas T. (Nicholas Tang)

January 2007

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 2007. / Includes bibliographical references (p. 201-215). / This thesis explored the incorporation of iptycenes into polymers as a means to enhance the mechanical properties. Iptycene structures were targeted because they possess a unique structural property called internal molecular free volume. When these bulky pendant groups are incorporated into the backbone of a polymer chain, they produce a novel chain architecture called molecular barbed wire. This molecular barbed wire architecture not only influences individual polymer chain dynamics but also induces lateral interactions between polymer chains through the minimization of internal molecular free volume. Work began by developing the concepts of internal molecular free volume and how to exploit its minimization. A formal definition for this property was created along with methods to identify and quantify its existence. Experimental results document the effects of introducing this property into polyesters and polycarbonates. Two specific novel inter-chain interactions were established: molecular threading and molecular interlocking. These steric interactions between polymers chains generate a non-bonded, network morphology and actively enhance the mechanical properties during deformation. / (cont.) It was demonstrated that the stiffness, strength and ductility of polymers could be enhanced simultaneously through this method. Mechanical properties were observed in tension at quasistatic deformation rates and in compression at both quasistatic and ballistic deformation rates. Improved mechanical performances were related back to structural properties through x-ray scattering experiments. Concepts of internal molecular free volume were necessary to explain the structure-property relationships observed. In addition, a prototype of enhanced polycarbonate was successfully developed for possible use in protective armor applications. This work provides a new pathway for the continued research and development in the field of ballistic protection. / by Nicholas T. Tsui. / Ph.D.

Materials Science and Engineering.

A technical and economic evaluation of novel pH-responsive core-shell nanoparticles : delivering innovation from laboratory to market

Cho, Eun Chol, M. Eng. Massachusetts Institute of Technology

January 2008

Thesis (M. Eng.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 2008. / Vita. / Includes bibliographical references (leaves 64-69). / Many potentially powerful therapeutic strategies for the treatment of disease require the delivery of drugs into the cytosolic or nuclear compartments of cells. Members of the Irvine laboratory have developed a novel pH-responsive core-shell nanoparticle system that can achieve efficient and non-cytotoxic drug delivery into the cytosol. Another advantage is that the shell can be easily modified to bind to different types of drug agents and incorporate ligands for specific cell targeting. Experimental analysis of the newly synthesized nanoparticles with various shell structures has demonstrated that modification of the shell does not compromise their cytosolic delivery. These nanoparticles, if successful, will improve the therapeutic potential of a wide range of drugs. However, critical issues on the research side need to be resolved, and an appropriate intellectual property strategy should be initiated in the near future. Applications to siRNA delivery and vaccines have been examined in depth, as cytosolic delivery is one of the main challenges in these fields. Partnerships with large pharmaceutical companies are critical in order to acquire key patents on siRNA/antigen. Even though the market is competitive, there is a strong demand for innovative delivery platforms; provided that the overall profile of the core-shell nanoparticles is comparable to that of emerging drug delivery systems, and a strong intellectual property portfolio is developed, the Irvine technology should be able to compete in the market. After analyzing risks on the business side, including the FDA approval process, a suggested business strategy is outlined, through which value can be successfully obtained throughout the existing pharmaceutical supply chain from the novel drug delivery system. / (cont.) The Irvine technology company will develop formulations, contract manufacturers will produce the nanoparticles, and pharmaceutical companies will concentrate on clinical trials, late-stage development and sales and marketing. A case study on the liver cancer market has demonstrated that commercial development of the Irvine nanoparticles can be a financially successful endeavor. / by Eun Chol Cho. / M.Eng.

Materials Science and Engineering.

Printed circuit board materials : an evaluation of manufacturing technologies and market requirements

Ng, Lee Hong

January 1990

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 1990. / Includes bibliographical references (leaves 190-194). / by Ng, Lee Hong. / Ph.D.

Materials Science and Engineering.

The electrical and optical properties of doped yttrium aluminum garnets

Chen, Jimmy Kuo-Wei

January 1994

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 1994. / Includes bibliographical references (leaves 221-226). / by Jimmy Kuo-Wei Chen. / Ph.D.

Materials Science and Engineering

Towards material-informed tectonics

Tai, Yen-Ju Timothy

January 2018

Thesis: S.M., Massachusetts Institute of Technology, Department of Materials Science and Engineering, 2018. / Cataloged from PDF version of thesis. / Includes bibliographical references. / This thesis introduces, demonstrates, and implements a unified computational design framework for material distribution modeling that enables the production of geometrically complex, materially heterogeneous, and functionally graded objects, across scales, media, and platforms. Receiving user-defined performance mappings as input, the workflow generates and evaluates instructions for designated fabrication systems, informed by the extrinsic constraints presented by the hardware and the intrinsic characteristics embedded in the materials utilized. As a proof of concept to the generalizable approach, three novel design-to-fabrication processes within the framework are introduced with material and materialization precedents and implemented through computational and robotic platforms: implicit modeling for the fabrication of photopolymers, trajectory optimizing for the fabrication of water-based material, and toolpath planning for the fabrication of fiber-based material. Titled Material-informed Tectonics, the framework extends the domain of parametric design processes from geometry to material, expands the potential application of volumetric material modeling techniques beyond high resolution multi-material 3D printing systems, and bridges between the virtual and the physical by integrating material information into the tectonic relationship between manufactured objects and manufacturing methods; thereby outlining an approach towards a synthesis of material properties, computational design, digital fabrication, and the environment. / by Yen-Ju Timothy Tai. / S.M.

Materials Science and Engineering.

Assessment of colloidal self-assembly for photonic crystal

Yip, Chan Hoe

January 2006

Thesis (M. Eng.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 2006. / Includes bibliographical references (p. 87-93). / A suspension of monodisperse colloids has an interesting property of self-assembling into a three-dimensional ordered structure. This crystalline material has attracted significant interest on the implementation of photonic crystals, which have practical applications in reflectors, filters, resonators, and waveguides. In this thesis, self-assembly of colloidal crystals and photonic crystal technologies are reviewed. Potential colloidal photonic and non-photonic devices were presented and their values/limitations were discussed. Colloidal photonic crystals were assessed on their technical capabilities, growth techniques and fabrication cost. In this assessment, the bulk colloidal photonic crystals are found to be inherently robust against stacking disorder, cracks and voids. The high reflectance performance and lattice parameter tailoring are useful for implementing reflectors, optical switch and sensors. Besides, the anomalous dispersion characteristic near to the band edges or near to flat bands of the photonic band diagram is suited for superprism and light harvesting applications. Potentially, the unique characteristics of colloidal photonic crystal could be capitalized in a low cost micro-fabrication model. Finally, the study has shown that it is more technically and commercially viable to implement bulk colloidal photonic crystal applications rather than lithographically-defined types. / by Chan Hoe Yip. / M.Eng.

Materials Science and Engineering.