Your search keyword '"Ceramics, Glass, Composites, Natural Methods"' showing total 457 results

1. Formation of Delta Ferrite in 9 Wt Pct Cr Steel Investigated by In-Situ X-Ray Diffraction Using Synchrotron Radiation

Author

Mayr, P., Palmer, T.A., Elmer, J.W., Specht, E.D., and Allen, S.M.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

In-situ X-ray diffraction (XRD) measurements using high energy synchrotron radiation were performed to monitor in real time the formation of delta ferrite in a martensitic 9 wt pct chromium steel under simulated weld thermal cycles. Volume fractions of martensite, austenite, and delta ferrite were measured as a function of temperature at a 10 K/s heating rate to 1573 K (1300 °C) and subsequent cooling. At the peak temperature, the delta ferrite concentration rose to 19 pct, of which 17 pct transformed back to austenite on subsequent cooling.

Published

2010

2. Influence of the Substrate on the Creep of SN Solder Joints

Author

Lee, K.-O., Morris, J.W., and Hua, F.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

The creep rate of Sn solder joints is noticeably affected by joint metallization. Cu|Sn|Cu joints have significantly higher creep rates than Ni|Sn|Cu joints, which, in turn, have higher creep rates than Ni|Sn|Ni joints. Replacing Ni by Cu on both substrates increases the creep rate at 333 K (60 °C) by roughly an order of magnitude. The increased creep rate appears with no apparent change in the dominant creep mechanism; the change in the constitutive equation for creep (the Dorn equation) is in the pre-exponential factor. The decreased creep rate on substituting Ni is accompanied by an increase in the hardness of the polygranular solder but a decrease in the nanohardness of the grain interiors. The source of the strong influence of the Ni substrate appears to be the introduction of an array of Ni3Sn4 intermetallic precipitates along the grain boundaries. These precipitates inhibit grain boundary sliding, boundary reconfiguration, and grain growth during creep. The intermediate creep rate of the asymmetric Ni|Sn|Cu joint has two causes: a decrease in grain boundary mobility due to precipitate decoration and a restriction in the free volume of the joint due to rapid intermetallic growth from the substrate on the Ni side. The sources of this anomalous intermetallic growth are discussed.

Published

2010

3. Deformation Mechanisms in Nanocrystalline Materials

Author

Mohamed, Farghalli A. and Yang, Heather

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

As a result of recent investigations on nanocrystalline (nc) materials, extensive experimental data on the deformation behavior of these materials have become available. In this article, an analysis of these data was performed to identify the requirements that a viable deformation mechanism should meet in terms of accounting for the mechanical characteristics and trends that are revealed by the data. The results of the analysis show that a viable deformation mechanism is required to account for the following: (1) an activation volume the value of which is in the range 10 to 40 b 3; (2) an activation energy that is close to the activation energy for boundary diffusion but that decreases with increasing applied stress; (3) the magnitudes of deformation rates that cover wide ranges of temperatures, stresses, and grain sizes; (4) inverse Hall–Petch behavior; and (5) limited ductility. The validity of available deformation mechanisms for nc materials is closely examined in the light of these requirements.

Published

2010

4. Tensile Deformation and Fracture Mechanism of Bulk Bimodal Ultrafine-Grained Al-Mg Alloy

Author

Lee, Zonghoon, Radmilovic, Velimir, Ahn, Byungmin, Lavernia, Enrique J., and Nutt, Steven R.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

The tensile fractures of ultrafine-grained (UFG) Al-Mg alloy with a bimodal grain size were investigated at the micro- and macroscale using transmission electron microscopy (TEM), scanning electron microscopy (SEM) equipped with focused ion beam (FIB), and optical microscopy. The nanoscale voids and crack behaviors near the tensile fracture surfaces were revealed in various scale ranges and provided the evidence to determine the underlying tensile deformation and fracture mechanisms associated with the bulk bimodal metals. The bimodal grain structures exhibit unusual deformation and fracture mechanisms similar to ductile-phase toughening of brittle materials. The ductile coarse grains in the UFG matrix effectively impede propagation of microcracks, resulting in enhanced ductility and toughness while retaining high strength. In view of the observations collected, we propose a descriptive model for tensile deformation and fracture of bimodal UFG metals.

Published

2010

5. Microscale wear behavior and crosslinking of PEG-like coatings for total hip replacements

Author

Kane, Sheryl R., Ashby, Paul D., and Pruitt, Lisa A.

Subjects

Material Science, Surfaces and Interfaces, Thin Films, Characterization and Evaluation of Materials, Metallic Materials, Ceramics, Glass, Composites, Natural Methods, Polymer Sciences, Biomaterials

Abstract

The predominant cause of late-state failure of total hip replacements is wear-mediated osteolysis caused by wear particles that originate from the ultrahigh molecular weight polyethylene (UHMWPE) acetabular cup surface. One strategy for reducing wear particle formation from UHMWPE is to modify the surface with a hydrophilic coating to increase lubrication from synovial fluid. This study focuses on the wear behavior of hydrophilic coatings similar to poly(ethylene glycol) (PEG). The coatings were produced by plasma-polymerizing tetraglyme on UHMWPE in a chamber heated to 40°C or 50°C. Both temperatures yielded coatings with PEG-like chemistry and increased hydrophilicity relative to uncoated UHMWPE; however, the 40°C coatings were significantly more resistant to damage induced by atomic force microscopy nanoscratching. The 40°C coatings exhibited only one damage mode (delamination) and often showed no signs of damage after repeated scratching. In contrast, the 50°C coatings exhibited three damage modes (roughening, thinning, and delamination), and always showed visible signs of damage after no more than two scratches. The greater wear resistance of the 40°C coatings could not be explained by coating chemistry or hydrophilicity, but it corresponded to an approximately 26–32% greater degree of crosslinking relative to the 50°C surfaces, suggesting that crosslinking should be a significant design consideration for hydrophilic coatings used for total hip replacements and other wear-dependent applications.

Published

2010

6. The Influence of Ni-Coated TiC on Laser-Deposited IN625 Metal Matrix Composites

Author

Zheng, Baolong, Topping, Troy, Smugeresky, John E., Zhou, Yizhang, Biswas, Asit, Baker, Dean, and Lavernia, Enrique J.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

IN625 Ni-based metal matrix composites (MMCs) components were deposited using Laser Engineered Net-Shaping (LENS) with Ni-coated and uncoated TiC reinforcement particles to provide insight into the influence of interfaces on MMCs. The microstructures and spatial distribution of TiC particles in the deposited MMCs were characterized, and the mechanical responses were investigated. The results demonstrate that the flowability of the mixed powders, the integrity of the interface between the matrix and the TiC particles, the interaction between the laser beam and the TiC ceramic particles, and the mechanical properties of the LENS-deposited MMCs were all effectively improved by using Ni-coated TiC particles.

Published

2010

7. Effect of Annealing on Hardness and the Modulus of Elasticity in Bulk Nanocrystalline Nickel

Author

Torrents, Anna, Yang, Heather, and Mohamed, Farghalli A.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

Experiments on hardness and the modulus of elasticity were conducted at room temperature on samples of electrodeposited (ED) nanocrystalline (nc) Ni that were annealed at temperatures ranging from 323 to 693 K (50 to 420 °C). The results showed the presence of three regions: I, II, and III. In region I (300 K (27 °C)  500 K (227 °C)), the hardness dropped and then decreased with increasing grain size, whereas the modulus of elasticity approached a maximum plateau of ~240 GPa. It is suggested that while the increase in hardness in region II can be attributed in part to the formation of annealing twins, which serve as a source of strengthening, the decrease in hardness above 500 K (227 °C) is due to the occurrence of significant grain growth. The increase in the modulus of elasticity with increasing temperature in region II was attributed to the preferred orientation along (200) that was observed in the as-received samples and that continuously diminished with increasing temperature. In region III (T > 500 K (227 °C)), the preferred orientation disappeared and, a result, the modulus of elasticity approached a constant value of approximately 240 GPa.

Published

2010

8. Degassing Behavior of Nanostructured Al and Its Composites

Author

Zhang, Zhihui, Dallek, Steven, Vogt, Rustin, Li, Ying, Topping, Troy D., Zhou, Yizhang, Schoenung, Julie M., and Lavernia, Enrique J.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

The synthesis of bulk ultrafine-grained (UFG) and nanostructured Al via cryomilling can frequently require a degassing step prior to consolidation, partly due to the large surface area of the as-milled powders. The objective of this study is to investigate the effects associated with cryomilling with stearic acid additions (as a process-control agent) on the degassing behavior of Al powders. This objective was accomplished by completing select experiments with Al-7.5Mg, Al-6.4 wt pct Al85Ni10La5, and Al-14.3 wt pct B4C. The interaction between Al and stearic acid was determined using thermal analysis combined with Fourier transform infrared spectroscopy (FTIR). The degassing experiments were carried out under high vacuum (10−4 to ~10−6 torr) in a range from room temperature to 400 °C, with the pressure of the released gases monitored using a digital vacuum gage. The results showed that the liberation of chemisorbed water was suppressed in cryomilled Al powders and both the chemisorbed water and stearic acid were primarily released in the form of hydrogen. It was also demonstrated that under certain conditions, a nanostructure (grain size ~100 nm) can be retained following the hot vacuum degassing of cryomilled Al.

Published

2010

9. Low-Cycle Fatigue of Ultra-Fine-Grained Cryomilled 5083 Aluminum Alloy

Author

Walley, J. L., Lavernia, E. J., and Gibeling, J. C.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

The cyclic deformation behavior of cryomilled (CM) AA5083 alloys was compared to that of conventional AA5083-H131. The materials studied were a 100 pct CM alloy with a Gaussian grain size average of 315 nm and an alloy created by mixing 85 pct CM powder with 15 pct unmilled powder before consolidation to fabricate a plate with a bimodal grain size distribution with peak averages at 240 nm and 1.8 μm. Although the ultra-fine-grain (UFG) alloys exhibited considerably higher tensile strengths than those of the conventional material, the results from plastic-strain-controlled low-cycle fatigue tests demonstrate that all three materials exhibit identical fatigue lives across a range of plastic strain amplitudes. The CM materials exhibited softening during the first cycle, similar to other alloys produced by conventional powder metallurgy, followed by continual hardening to saturation before failure. The results reported in this study show that fatigue deformation in the CM material is accompanied by slight grain growth, pinning of dislocations at the grain boundaries, and grain rotation to produce macroscopic slip bands that localize strain, creating a single dominant fatigue crack. In contrast, the conventional alloy exhibits a cell structure and more diffuse fatigue damage accumulation.

Published

2009

10. High-Velocity Oxygen Fuel Thermal Spray of Fe-Based Amorphous Alloy: a Numerical and Experimental Study

Author

Ajdelsztajn, L., Dannenberg, J., Lopez, J., Yang, N., Farmer, J., and Lavernia, E. J.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

The fabrication of dense coatings with appropriate properties using a high velocity oxygen fuel (HVOF) spray process requires an in-depth understanding of the complete gas flow field and particle behavior during the process. A computational fluid dynamics (CFD) model is implemented to investigate the gas flow behavior that occurs during the HVOF process and a simplified one-dimensional decoupled model of the in-flight thermal behavior of the amorphous Fe-based powder particles was developed and applied for three different spray conditions. The numerical results were used to rationalize the different coating microstructures described in the experimental results. Low porosity and amorphous coatings were produced using two different particle size distributions (16 to 25 μm and 25 to 53 μm). The amorphous characteristics of the powder were retained in the coating due to melting and rapid solidification in the case of very fine powder or ligaments (

Published

2009

11. Compaction Behavior and Mechanical Properties of Uniaxially Pressed Bi-W Composites

Author

Peter Martin, L., Hodge, Andrea M., and Campbell, Geoffrey H.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

Powder metallurgy is a useful route to forming particulate composite materials; however, the densification of hard and soft powder mixtures is usually inhibited by the more refractory phase. The Bi-W powder compacts were uniaxially pressed at room temperature and the compaction behavior and mechanical properties were evaluated. Pressing was performed in incremental steps from ~1 to 540 MPa. After each step, the pressure was relieved and the thickness and sound-wave transit time were measured in situ (in the die), in order to determine the density and sound-wave velocity in the compact. The data show that the unreinforced Bi powder compacts to ~98 pct density at 540 MPa. The W reinforcement inhibits the densification process, resulting in increased levels of residual porosity. The compaction behavior was evaluated using a modified Heckel equation, while the porosity dependence of the ultrasonically determined elastic modulus was described by a site percolation approach. Postcompaction sound-wave velocity and Vicker’s hardness measurements show

Published

2009

12. Mechanical Behavior of Cryomilled Ni Superalloy by Spark Plasma Sintering

Author

Zhang, Z., Han, B.Q., Huang, J.Y., Han, Y.H., Zhou, Y., Kakegawa, K., and Lavernia, E.J.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

The mechanical behavior of ultra-fine-grained (UFG) INCONEL 625 superalloy prepared via cryomilling and spark plasma sintering (SPS) was studied. The work-hardening response of the ultra-fine-grained (600 to 700 nm) INCONEL 625 was compared to that of the material with a 1-μm grain size and the results showed normal work hardening for the latter material but not for the former. Moreover, the results suggest that a combination of high strength and good ductility can be simultaneously obtained in the UFG INCONEL 625 alloy.

Published

2009

13. Mechanical Behavior and Microstructural Development of Low-Carbon Steel and Microcomposite Steel Reinforcement Bars Deformed under Quasi-Static and Dynamic Shear Loading

Author

Dougherty, L.M., Cerreta, E.K., Gray, G.T., Trujillo, C.P., Lopez, M.F., Vecchio, K.S., and Kusinski, G.J.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

Reinforcement bars of microcomposite (MC) steel, composed of lath martensite and minor amounts of retained austenite, possess improved strength and corrosion characteristics over low-carbon (LC) steel rebar; however, their performance under shear loading has not previously been investigated at the microstructural level. In this study, LC and MC steel cylinders were compression tested, and specimens machined into a forced-shear geometry were subjected to quasi-static and dynamic shear loading to determine their shear behavior as a function of the strain and strain rate. The as-received and sheared microstructures were examined using optical microscopy (OM), scanning electron microscopy (SEM), and electron backscatter diffraction (EBSD). Higher-resolution microstructural examinations were performed using transmission electron microscopy (TEM). The influence of the starting microstructure on the shear behavior was found to depend strongly on the strain rate; the MC steel exhibited not only greater strain-rate sensitivity than the LC steel but also a greater resistance to shear localization with load. In both steels, despite differences in the starting microstructure, post-mortem observations were consistent with a continuous mechanism operating within adiabatic shear bands (ASBs), in which subgrains rotated into highly misoriented grains containing a high density of dislocations.

Published

2009

14. Ductile-Phase Toughening of Brazed Joints

Author

Philips, N. R., Levi, C. G., and Evans, A. G.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

A heat treatment is presented that uses ductile-phase toughening to mitigate the effect of brittle intermetallics in a Ni-based braze alloy. The fracture resistance has been enhanced by creating a microstructure containing elongated ductile γ-(Ni) domains that align, preferentially, across the joint. The development of this beneficial microstructure is based on an understanding of the transient dissolution, isothermal solidification, and coarsening phenomena. Due to slow kinetics, the elimination of intermetallics by diffusion is avoided in favor of ductile domain formation through solidification control. The toughening has been attributed to a combination of bridging and process zone dissipation, enabled by the ductile phase.

Published

2009

15. Applications in the Nuclear Industry for Thermal Spray Amorphous Metal and Ceramic Coatings

Author

Blink, J., Farmer, J., Choi, J., and Saw, C.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

Amorphous metal and ceramic thermal spray coatings have been developed with excellent corrosion resistance and neutron absorption. These coatings, with further development, could be cost-effective options to enhance the corrosion resistance of drip shields and waste packages, and limit nuclear criticality in canisters for the transportation, aging, and disposal of spent nuclear fuel. Iron-based amorphous metal formulations with chromium, molybdenum, and tungsten have shown the corrosion resistance believed to be necessary for such applications. Rare earth additions enable very low critical cooling rates to be achieved. The boron content of these materials and their stability at high neutron doses enable them to serve as high efficiency neutron absorbers for criticality control. Ceramic coatings may provide even greater corrosion resistance for waste package and drip shield applications, although the boron-containing amorphous metals are still favored for criticality control applications. These amorphous metal and ceramic materials have been produced as gas-atomized powders and applied as near full density, nonporous coatings with the high-velocity oxy-fuel process. This article summarizes the performance of these coatings as corrosion-resistant barriers and as neutron absorbers. This article also presents a simple cost model to quantify the economic benefits possible with these new materials.

Published

2009

16. Bio-hybrid materials for immunoassay-based sensing of cortisol

Author

Fang, Jonathan, Zhou, Jing C., Lan, Esther H., Dunn, Bruce, and Zink, Jeffrey I.

Subjects

Material Science, Nanotechnology, Optical and Electronic Materials, Inorganic Chemistry, Ceramics, Glass, Composites, Natural Methods, Sol–gel, Biosensing, Immunoassay, Cortisol, Standard additions

Abstract

Sol–gel encapsulation has been used as the basis for detecting cortisol by an immunoassay approach. Previous research showed that antibodies immobilized in the pores of a sol–gel derived silica were able to bind cortisol and be used as an immunosensor. However, this approach was not effective when measuring cortisol levels in human serum because of interference from other fluorescence sources. The present paper describes a protocol which overcomes these limitations and enables sol–gel immunoassays to effectively measure cortisol in human serum over the physiological range of cortisol blood concentrations in an adult (2–28 μg/dL). The method involves a standard additions approach in which various amounts of cortisol are added to the serum. The cortisol concentration values obtained with our sol–gel immunoassay were typically within 10% of the values obtained by traditional analytical methods. The protocol presented here represents a significant contribution to sol–gel sensing and immunoassays in particular, because of the ability to detect an analyte in human serum. In addition, this work reports the first comparison between results from a sol–gel immunosensor and an alternative immuno-binding method for analyte detection.

Published

2009

17. Processing and Behavior of Fe-Based Metallic Glass Components via Laser-Engineered Net Shaping

Author

Zheng, B., Zhou, Y., Smugeresky, J. E., and Lavernia, E. J.

Subjects

Material Science, Ceramics, Glass, Composites, Natural Methods, Physical Chemistry, Structural Materials, Metallic Materials, Materials Science, general

Abstract

In this article, the laser-engineered net shaping (LENS) process is implemented to fabricate net-shaped Fe-based Fe-B-Cr-C-Mn-Mo-W-Zr metallic glass (MG) components. The glass-forming ability (GFA), glass transition, crystallization behavior, and mechanical properties of the glassy alloy are analyzed to provide fundamental insights into the underlying physical mechanisms. The microstructures of various LENS-processed component geometries are characterized via scanning electron microscopy (SEM), X-ray diffraction (XRD), differential scanning calorimetry (DSC), and transmission electron microscopy (TEM). The results reveal that the as-processed microstructure consists of nanocrystalline α-Fe particles embedded in an amorphous matrix. An amorphous microstructure is observed in deposited layers that are located near the substrate. From a microstructure standpoint, the fraction of crystalline phases increases with the increasing number of deposited layers, effectively resulting in the formation of a functionally graded microstructure with in-situ-precipitated particles in an MG matrix. The microhardness of LENS-processed Fe-based MG components has a high value of 9.52 GPa.

Published

2009

18. Material Additives for Microstructured Polymer Optical Fibres.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

Two doping methods that specifically use the holey nature of mPOF are discussed. Dopants or particles can be introduced into the holes of the preform or the cane. Both methods are described here, and results showing the fluorescence from fibres doped with organic dyes, embedded organo-silica nanoparticles and quantum dots are presented. Indeed, an mPOF laser has been demonstrated using the solution doping method. [ABSTRACT FROM AUTHOR]

Published

2008

19. Bragg and Long Period Gratings in mPOF.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

This chapter describes both Fibre Bragg Gratings (FBG) and Long Period Gratings (LPG) in mPOF, and the required theoretical basis to understand their operation. Gratings are a highly developed research area, and no attempt has been made to review the whole field. Excellent reviews are available, including [Othonos and Kalli 1999, Kashyap 1999]. The two most relevant related areas however are described here: gratings in MOFs and POFs. This work is significant in identifying applications where the material or waveguide properties of mPOF may offer new functionality. The chapter also describes the experimental techniques used to make mPOF gratings, and their performance characteristics. Finally, conclusions are drawn about how mPOF gratings may be improved and application areas where they may prove useful. [ABSTRACT FROM AUTHOR]

Published

2008

20. Graded-Index Microstructured Polymer Optical Fibres.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

In this chapter we describe the factors that limit the bandwidth of large-core multimode polymer fibres, including intramodal and intermodal dispersion. The latter is usually addressed by using a graded-index (GI) to equalise the group velocities of the fast and slow modes. While most GI fibres use differences in chemical composition to produce the index gradient, it is also possible to use a graded microstructure. Such fibres (denoted GImPOF) differ from conventional GI POF not just in having a microstructure, but also in having a much larger index contrast. We model the behaviour of a non-microstructured (i.e. azimuthally averaged) fibre with the same contrast. We present the modelling and experimental results for a GImPOF and assess its potential. [ABSTRACT FROM AUTHOR]

Published

2008

21. Hollow-Core Microstructured Polymer Optical Fibres.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

This chapter is devoted to mPOFs that guide in a hollow core. It describes two methods for fabricating these fibres and explains their transmission characteristics. Common issues affecting the performance are discussed as well as the various applications. [ABSTRACT FROM AUTHOR]

Published

2008

22. The Handling and Characterisation of Microstructured Polymer Optical Fibres.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

This chapter outlines three methods for cutting mPOFs as well as giving details of techniques that have been used to characterise mPOFs through accurate imaging of their microstructure as well as outlining measurements of their light guiding properties such as loss, numerical aperture, bandwidth and birefringence. [ABSTRACT FROM AUTHOR]

Published

2008

23. Effects of Drawing on the Microstructure.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

The stretch and drawing processes used to make mPOF pose considerable computational challenges, combining as they do non-isothermal, threedimensional (3-D) and time dependent behaviour. This complexity is further complicated if the materials used exhibit significant nonlinear viscoelastic behaviour, while the very nature of an mPOF means that its fabrication involves the substantial deformation of a (potentially large) number of 3-D free surfaces. Unsurprisingly the relevant analytical [Fitt et al. 2002] and numerical [Deflandre 2002, Lyytikäinen et al. 2004] literature is limited. However a convincing story has recently emerged that quantitatively ties together the roles of material properties and tower draw conditions in determining both hole size and shape deformation within an overall MOF structure. This chapter begins with a scaling analysis leading to a suite of dimensionless numbers whose values can be used to assess the relative importance of the viscous, inertial, gravitational and surface tension forces in any particular drawing process. Subsequently both isothermal and non-isothermal drawing are considered. In the former case indicative theoretical analysis is possible, while in the latter it is necessary to rely on numerical modelling. Both hole size and shape changes are considered. Although the focus is on polymer fibres, consideration is also given to silica based microstructured optical fibres so as to highlight the impact of differing material properties. The chapter concludes by considering the impact of hole pressurisation during the draw process. [ABSTRACT FROM AUTHOR]

Published

2008

24. Fabrication of Microstructured Polymer Optical Fibres.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

Conceptually, the fabrication of microstructured polymer optical fibre is a straightforward process involving just two steps - the creation of a preform containing a large-scale version of the structure desired in the fibre, followed by heating and drawing of the preform to produce the final fibre. Three issues soon emerge however when trying to turn this simple two-step process into a reality. [ABSTRACT FROM AUTHOR]

Published

2008

25. The Modelling and Design of Microstructured Polymer Optical Fibres.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

The first part of this chapter is about algorithms for modelling microstructured fibres. We also begin by briefly summarising the two major conventions for naming modes. The ideas behind the algorithms for calculating modes are then discussed but detailed results available in the literature are not reproduced here. It is impossible to be comprehensive or even perfectly balanced when covering such a wide field. Some references to both commercial and free software are given. We also sometimes give examples of how these algorithms have been used to analyse interesting features of microstructured fibres. [ABSTRACT FROM AUTHOR]

Published

2008

26. Guiding Concepts in Microstructured Fibres.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

This chapter builds on the concepts in Chapter 2 but focusses on differences between microstructured and conventional fibres. It begins with a description of the two different guidance mechanisms specific to MOFs. It then goes on to discuss two important ways in which the optical properties of MOFs differ from conventional fibres, namely confinement loss and dispersion. An understanding of these differences is crucial to appreciating how MOFs have expanded the ways and the range in which optical fibres can be used. [ABSTRACT FROM AUTHOR]

Published

2008

27. Concepts in Waveguide Theory.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

This chapter assumes the reader is familiar with the basic undergraduate optical concepts of electromagnetic waves, refractive index, phase, polarisation, diffraction and interference. The focus is on the important concepts, and although in this chapter we only look at conventional fibres we examine the concepts with sufficient clarity to ensure that they will be correctly applied to microstructured fibres. We also discuss whether a concept has a primarily historical, pragmatic or theoretical basis. Mathematical formalism is kept to a minimum while retaining as much rigour as necessary, and most of the approximations presented are based on sound theoretical concepts. We begin with how modes are classified and the role of polarisation and birefringence. We then move on to counting modes and the important concept of cutoff. We look at coupling light into fibres and then at dispersion. Finally, we cover the physics behind how modes are confined in conventional fibres to prepare the reader for the next chapter. [ABSTRACT FROM AUTHOR]

Published

2008

28. History and Applications of Polymer Fibres and Microstructured Fibres.

Author

Large, Maryanne C. J., Poladian, Leon, Barton, Geoff W., and van Eijkelenborg, Martijn A.

Abstract

This chapter places the rest of the book in context. It describes the history and state-of-the-art of both polymer fibres (POFs) and microstructured optical fibres (MOFs). The physical properties of these fibre types differ considerably in terms of the materials used and the possible waveguide geometries, and these form the basis for the difference in their applications. This chapter outlines both the physical differences and the major applications of each. The applications of POFs are described in more detail because most of the applications of microstructured fibres reappear in later chapters. [ABSTRACT FROM AUTHOR]

Published

2008

29. Hierarchical Modeling of Deformation of Materials from the Atomic to the Continuum Scale.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, and Chandra, Namas

Abstract

During the last few years, novel structures, phenomena, and processes have been observed at the nanoscale. In addition, the very nature of thermal and mechanical responses of materials is governed by the phenomena occurring at the atomic nanoscale. With the development in nanoscale systems, there is an urgent need for theory, modeling, and computational tools to understand and accelerate development and applications. Modeling efforts in nanoscale systems have predominantly used atomistic simulations based on molecular dynamics or other refined techniques, such as density functional and tight binding theories, which help clarify the issues involved at the macroscale. Though atomistic simulations provide insightful details into many problems of interest, the exceedingly high computational requirements of atomistic simulations place a stringent limitation on length and time scales for the problem of interest. [ABSTRACT FROM AUTHOR]

Published

2008

30. Multiscale Modeling for Damage Analysis.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, and Singh, Chandra Veer

Abstract

The increased computational power and programming capabilities in recent years have given impetus to the so-called multiscale modeling, which implements the largely intuitive notion that physical phenomena occurring at a lower length or size scale determine the observed response at a higher scale. A logical outcome of this thought is an organization of differentiated scales - from the lowest, such as nanometer scale, to the highest scale typical of the part or structure in mind - giving a hierarchy of scales. Working up the scales produces a hierarchical multiscale modeling, in which the essential challenge consists of "bridging" the scales. The simulation techniques, such as molecular dynamics simulation (MDS), succeed mostly in revealing phenomena from one scale to the next; but proceeding to three or more scales often necessitates unrealistic computing power even with the most versatile facilities available. In addition, the limitation of independent physical validation of the simulated results questions the wisdom of total reliance on the multiscale hierarchical modeling strategy. When it comes to subcritical (prefailure) damage in composites, the multiscale modeling concept needs closer examination, firstly, because the length scales of constituents and heterogeneities are fixed while those of damage evolve progressively, and secondly, because the mechanisms of damage tend to segregate in modes with individual characteristic scales. All this is the subject of this chapter, which will first describe and clarify the damage mechanisms in common types of composites followed by the induced response observed at the macroscale. The hierarchical modeling approach will be discussed against this knowledge; and a different approach, named synergistic multiscale modeling, will be advocated. Assessment will be offered of the current state of this modeling, and future activities aimed at accomplishing its objectives will be outlined. [ABSTRACT FROM AUTHOR]

Published

2008

31. Multiscale Modeling of the Evolution of Damage in Heterogeneous Viscoelastic Solids.

Author

Kwon, Young W., Talreja, Ramesh, Allen, David H., and Soares, Roberto F.

Abstract

It has long been recognized that one of the primary failure modes in solids is due to crack growth, whether it be a single or multiple cracks. It is known, for instance, that Da Vinci [14] proposed experiments of this type in the late fifteenth century. Indeed, modern history is replete with accounts of events wherein fracture-induced failure of structural components has caused the loss of significant life. Such events are common in buildings subjected to acts of nature, such as earthquakes, aircraft subjected to inclement weather, and even human organs subjected to aging. Therefore, it would seem self-evident that cogent models capable of predicting such catastrophic events could be utilized to avoid much loss of life. However, despite the fact that such events occur regularly, the ability to predict the evolution of cracks, especially in inelastic media, continues to elude scientists and engineers. This appears to be at least due, in part, to two as yet unresolved issues (1) there is still no agreed upon model for predicting crack extension in inelastic media and (2) the prediction of the extension of multiple cracks simultaneously in the same object is as yet untenable. While it would be presumptuous to say that the authors have resolved these two outstanding issues, there is at least a glimmer of hope that these two issues may be resolved by using an approach not unlike that proposed herein. This chapter outlines an approach for predicting the evolution of multiple cracks in heterogeneous viscoelastic media that ultimately leads to failure of the component to perform its intended task. [ABSTRACT FROM AUTHOR]

Published

2008

32. Modeling of Stiffness, Strength, and Structure-Property Relationship in Crosslinked Silica Aerogel.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, Roy, Samit, and Hossain, Awlad

Abstract

Mechanically stable forms of lightweight materials with porosities up to 98% were first introduced in the form of silica aerogels in the 1930s. Recently, interest in aerogels and other lightweight materials in engineering applications have increased tremendously. Native silica aerogels are chemically inert, low-density, nanostructured porous materials with poor mechanical properties. They are the product of the sol-gel process whose final step involves extracting the pore-filled solvent with liquid carbon dioxide through supercritical drying. Practical applications of native aerogels are somewhat limited as they are brittle and hygroscopic, absorbing moisture from the environment which eventually leads to aerogel collapse due to capillary forces in the pores. Nevertheless, it has been recently discovered that crosslinking the nanoparticle building blocks of silica aerogels with polymeric tethers increases both modulus and strength significantly [4]. Along these lines, a novel, multifunctional, crosslinked silica aerogel, to be referred to as x-aerogel, is derived by coating and encapsulating the skeletal framework of amine-modified silica aerogels with polyurea as depicted in Fig. 10.1. [ABSTRACT FROM AUTHOR]

Published

2008

33. Predicting Thermooxidative Degradation and Performance of High-Temperature Polymer Matrix Composites.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, Schoeppner, G. A., Tandon, G. P., and Pochiraju, K. V.

Abstract

Polymer matrix composites (PMCs) used in aerospace high-temperature applications, such as turbine engines and engine-exhaust-washed structures, are known to have limited life due to environmental degradation. Predicting the extended service life of composite structures subjected to mechanical, high temperature, moisture, and corrosive conditions is challenging due to the complex physical, chemical, and thermomechanical mechanisms involved. Additionally, the constituent phases of the material, in particular the matrix phase, continuously evolve with aging time. It is the agingdependent evolution of the constituent properties that makes prediction of the long-term performance of PMCs in high-temperature environments so challenging. A comprehensive prediction methodology must deal with several complications presented by the highly coupled material aging, damage evolution, and thermooxidation processes. [ABSTRACT FROM AUTHOR]

Published

2008

34. Nested Nonlinear Multiscale Frameworks for the Analysis of Thick-Section Composite Materials and Structures.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, and Haj-Ali, Rami

Abstract

This chapter presents nonlinear and time-dependent multiscale frameworks for the analysis of thick-section and multilayered composite materials and structures. Nested and hierarchical three-dimensional (3D) micromechanical models are formulated within the nonlinear analysis framework. The sublaminate model for a repeating ply-stacking sequence. A unified development of a class of constant deformation cell (CDC) micromodels is presented to generate the effective nonlinear response of a unidirectional lamina from the response of its matrix and fiber constituents (subcells). Two structural modeling approaches for nonlinear analysis of laminated composites are proposed using 3D and shell nonlinear finite element (FE) analysis. [ABSTRACT FROM AUTHOR]

Published

2008

35. Multiscale Modeling of Composites Using Analytical Methods.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, and McCartney, L. N.

Abstract

Both fiber and particulate composite materials provide applications in materials science where the multiscale microstructure leads to the need for multiscale modeling. The length scales encountered range from the fiber and particle sizes whose dimensions are measured in microns, to the individual plies in laminates whose thicknesses are measured in fractions of millimeters, to the laminates themselves whose thicknesses in the laboratory are measured in millimeters, e.g., 40-50 mm. The laminates then form parts of composite structures whose sizes are measured in meters, although modeling at this scale will not form part of this chapter. While conventional composites are based on essentially homogeneous matrices, which can be polymeric, metallic, or ceramic, advanced composites are also being considered to have matrices, which are themselves composites reinforced by submicron particles or whiskers, e.g., carbon nanotubes. Such developments lead to the need to be able to estimate the properties of composite laminates that have multiscale reinforcements, e.g., fibers in particulate/whisker-reinforced matrices. Also, there is a need to predict the onset of damage in the materials when they are operating in service conditions. [ABSTRACT FROM AUTHOR]

Published

2008

36. Multiscale Modeling and Simulation of Deformation in Nanoscale Metallic Multilayered Composites.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, Akasheh, F., and Zbib, H. M.

Abstract

Nanoscale metallic multilayered (NMM) composites represent an important class of advanced engineering materials which have a great promise for high performance that can be tailored for different applications. Traditionally, NMM composites are made of bimetallic systems produced by vapor or electrodeposition. Careful experiments by several groups have clearly demonstrated that such materials exhibit a combination of several superior mechanical properties: ultrahigh strength reaching 1/3 to 1/2 of the theoretical strength of any of the constituent materials [28], high ductility [25], morphological stability under high temperatures and after large deformation [22], enhanced fatigue resistance of an order of magnitude higher than the values typically reported for the bulk form [35], and improved irradiation damage resistance [17, 27], again, as compared to the bulk. However, the basic understanding of the behavior of those materials is not yet at a level that allows them to be harnessed and designed for engineering applications. [ABSTRACT FROM AUTHOR]

Published

2008

37. A Micromechanics-Based Notion of Stress for Use in the Determination of Continuum-Level Mechanical Properties via Molecular Dynamics.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, Costanzo, Francesco, and Gray, Gary L.

Abstract

By formulating a continuum homogenization problem that includes inertia effects, a link is established between continuum homogenization and the estimation of effective mechanical properties for particle ensembles whose interactions are governed by potentials (e.g., as is seen in molecular dynamics). The focus of this chapter is on showing that there is a fundamental consistency of ideas between continuum mechanics and the study of discrete particle systems, and that it is possible to define a notion of effective stress applicable to discrete systems that can be claimed to have the same meaning as it has in continuum mechanics. [ABSTRACT FROM AUTHOR]

Published

2008

38. Multiscale and Multilevel Modeling of Composites.

Author

Allen, David H., Talreja, Ramesh, and Kwon, Young W.

Abstract

Composites have been used increasingly in various engineering applications which include, but are not limited to, the aerospace, automobile, sports, and leisure industries. To improve properties of composites so that they become stronger, stiffer, tougher, refractory, etc., it would be very useful to design the composite materials from the atomic levels. This requires proper multiscale and multilevel modeling techniques so that those techniques can be used for the design stage of new composites as well as the analysis of existing composites. This chapter presents multiscale and multilevel modeling techniques for different kinds of composite architectures which include particle-reinforced, fiber-reinforced, and woven fabric composites. [ABSTRACT FROM AUTHOR]

Published

2008

39. Adaptive Concurrent Multi-Level Model for Multiscale Analysis of Composite Materials Including Damage.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, and Ghosh, Somnath

Abstract

The past few decades have seen rapid developments in the science and technology of a variety of advanced heterogeneous materials like polymer, ceramic, or metal matrix composite, functionally graded materials, and porous materials, as well as various alloy systems. Many of these engineered materials are designed to possess optimal properties for different functions, e.g., low weight, high strength, superior energy absorption and dissipation, high impact and penetration resistance, superior crashworthiness, better structural durability, etc. Tailoring their microstructures and properties to yield high structural efficiency has enabled these materials to provide enabling mission capabilities, which has been a key factor in their successful deployment in the aerospace, automotive, electronics, defense, and other industries. [ABSTRACT FROM AUTHOR]

Published

2008

40. Multiscale Modeling of Tensile Failure in Fiber-Reinforced Composites.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, Zhenhai Xia, and Curtin, W. A.

Abstract

Fiber-reinforced composites can be engineered to exhibit high strength, high stiffness, and high toughness, and are, thus, attractive alternatives to monolithic polymer, metals, and ceramics in structural applications. To engineer the material for high performance, the relationship between material microstructure and its properties must be established to accurately predict the deformation and failure. Such a relationship between underlying constituent material properties and composite performance can also aid selection and/or optimization of new composite systems. Successful models can yield predictive insight into the origins of damage tolerance, size scaling, and reliability of existing composite systems and can be extended to investigate damage and failure under more complex loading and environmental conditions, such as fatigue and stress rupture. [ABSTRACT FROM AUTHOR]

Published

2008

41. Account for Random Microstructure in Multiscale Models.

Author

Kwon, Young W., Allen, David H., Talreja, Ramesh, and Silberschmidt, Vadim V.

Abstract

The accumulated in last decades knowledge of fibre-reinforced composite materials, their effective properties as well as deformation and damage processes in them confirms a random (probabilistic) character of their failure (see, e.g. [1-4] and references therein). Such a character is determined by the specificity of microstructure of composites - a result of a manufacturing process of embedding of a huge number of reinforcing elements into a matrix. The resulting microscopic heterogeneity linked to randomness in positions of fibres, their bonding with the matrix, presence of microdefects, etc. causes a spatially and temporally non-uniform response to external loading even under macroscopically uniform loading conditions. The resulting pattern of deformation localisation and stress concentrations is neither uniform nor periodic; it defines macroscopic nonuniformity in evolution of various damage mechanisms. [ABSTRACT FROM AUTHOR]

Published

2008

42. Ground Granulated Blast Furnace Slag.

Author

Siddique, Rafat

Published

2008

43. Foundry Sand.

Author

Siddique, Rafat

Published

2008

44. Cement Kiln Dust.

Author

Siddique, Rafat

Published

2008

45. Volcanic Ash.

Author

Siddique, Rafat

Published

2008

46. Wood Ash.

Author

Siddique, Rafat

Published

2008

47. Municipal Solid Waste Ash.

Author

Siddique, Rafat

Published

2008

48. Rice Husk Ash.

Author

Siddique, Rafat

Published

2008

49. Coal Fly Ash.

Author

Siddique, Rafat

Published

2008

50. Waste Glass.

Author

Siddique, Rafat

Published

2008