Your search keyword '"Daniel P. Cole"' showing total 76 results

1. Understanding compressive strength improvement of high modulus carbon-fiber reinforced polymeric composites through fiber-matrix interface characterization

Author

Sarvenaz Ghaffari, Andrew Makeev, Guillaume Seon, Daniel P. Cole, Daniel J. Magagnosc, and Sanjit Bhowmick

Subjects

Polymer-matrix composites (PMCs), High-modulus carbon fiber, Strength, Interface strength, Scanning electron microscopy (SEM), In-situ nanomechanics, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Low fiber-direction compressive strength of high-modulus (HM) carbon fiber-reinforced polymers (CFRPs) has been their major weakness prohibiting implementation of such materials in aircraft primary structures despite improving mechanical stiffness at a lower weight. A new HM CFRP achieving fiber-direction compressive strength of intermediate-modulus (IM) CFRPs but with more than 30% higher axial modulus has been recently developed. This work looks into fiber-matrix interface shear strength as a potential mechanism driving the compression strength improvement of the new material system. In-situ scanning electron microscopy (SEM) based single fiber push-out experiments addressing standing challenges associated with manufacturing high-quality samples as well as distinguishing same-diameter HM and IM carbon fibers in the hybrid composite system are used to measure fiber-matrix interface shear strength. The experiments show a 29% lower average value of the fiber-matrix interface shear strength for the HM carbon fibers compared to the IM carbon fibers in the new material system. Such a significant reduction corresponds to a 22% lower fiber-direction compressive strength of the HM CFRP without the integrated IM fibers. The results support the idea of integrating off-the-shelf IM carbon fibers with a stronger fiber-matrix interface and a higher shear modulus into HM CFRPs to improve their compressive strength.

Published

2020

2. Two New Methods in Stochastic Electrodynamics for Analyzing the Simple Harmonic Oscillator and Possible Extension to Hydrogen

Author

Daniel C. Cole

Subjects

stochastic electrodynamics, classical physical dynamics, hydrogen, harmonic oscillator, nonlinear dynamics, Physics, QC1-999

Abstract

The position probability density function is calculated for a classical electric dipole harmonic oscillator bathed in zero-point plus Planckian electromagnetic fields, as considered in the physical theory of stochastic electrodynamics (SED). The calculations are carried out via two new methods. They start from a general probability density expression involving the formal integration over all probabilistic values of the Fourier coefficients describing the stochastic radiation fields. The first approach explicitly carries out all these integrations; the second approach shows that this general probability density expression satisfies a partial differential equation that is readily solved. After carrying out these two fairly long analyses and contrasting them, some examples are provided for extending this approach to quantities other than position, such as the joint probability density distribution for positions at different times, and for position and momentum. This article concludes by discussing the application of this general probability density expression to a system of great interest in SED, namely, the classical model of hydrogen.

Published

2023

3. A Hybrid Reliability Model Using Generalized Renewal Processes for Predictive Maintenance in Nuclear Power Plant Circulating Water Systems

Author

Ryan M. Spangler, Vivek Agarwal, and Daniel G. Cole

Subjects

Circulating water system, decision-making, general repair, generalized renewal process, maintenance, Markov model, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The nuclear industry’s economic viability is challenged by significant operations and maintenance (O&M) costs. Although maintenance strategies are often risk-averse, many maintenance programs rely on schedule-based strategies that perform repairs and replacements regardless of the asset’s condition, leading to unnecessary repairs and high costs. Predictive maintenance can help alleviate these costs through condition monitoring and risk-informed decision-making. In this article, we show that the use of improved reliability models can help reduce the total cost of ownership (TCO) for a high-value repairable asset. Current risk-informed methods used in the industry today rely on mean-time-between-failure (MTBF) models that may oversimplify failure likelihood estimation. Improvements can be made by integrating condition monitoring, operational history, and maintenance effectiveness into a hybrid reliability model. In contrast with conventional MTBF methods, the generalized renewal process uses recurrent event analysis and historical repair data to quantify the effectiveness of maintenance repairs and estimate the likelihood of failure. During a case study on a nuclear power plant’s circulating water system, a hybrid reliability model was fitted to the historical data and shown to have improved likelihood estimations when compared to a MTBF model. Monte Carlo simulations were then used to simulate and compare TCO for various maintenance strategies, showing that an extended replacement interval can reduce overall costs by upwards of 10.7%. The successful results of the improved reliability models showcase the ability to aid decision-making and reduce overall operations and maintenance costs in the nuclear power industry.

Published

2023

4. An open-source molecular builder and free energy preparation workflow

Author

Mateusz K. Bieniek, Ben Cree, Rachael Pirie, Joshua T. Horton, Natalie J. Tatum, and Daniel J. Cole

Subjects

Chemistry, QD1-999

Abstract

Automated free energy calculations for the prediction of binding free energies of ligands to a protein target are gaining importance for drug discovery, but building reliable initial binding poses for the ligands is challenging. Here, the authors introduce an open-source workflow for building user-defined congeneric series of ligands in protein binding pockets for input to free energy calculations.

Published

2022

5. Psoriasis coxsackium

Author

Daniel W. Cole, MD, Bo Wang, MD, PhD, Douglas R. Fullen, MD, and Yolanda R. Helfrich, MD

Subjects

coxsackievirus, dermatopathology, psoriasis, Dermatology, RL1-803

Published

2022

6. Biden’s Burden: Cleaning up Trump’s environmental mess

Author

Daniel H. Cole

Subjects

administrative procedure, executive orders, climate change, Law, Political institutions and public administration (General), JF20-2112

Abstract

Before the US can make progress on climate policy or environmental policy more generally, the new administration of President Joseph R. Biden must first undo the damage created by his predecessor in office, who dismantled existing US climate policy, pulled the US from the Paris Agreement, and sought to disable the Environmental Protection Agency (EPA) from regulating polluters. The courts blocked some of the Trump Administration’s more egregious anti-environmental protection policies for violating the 1946 Administrative Procedures Act and/or the express terms of an environmental protection statute (such as the Clean Air Act or Clean Water Act), but the Biden Administration still has a great deal of work to do. Already, Biden has announced that the US will rejoin the Paris Agreement as part of its plans not just to reinstate but to expand on climate policies adopted during the Obama Administration. This essay explains how the Biden Administration plans to achieve these climate policy goals, using mostly the very same administrative tools that the Trump Administration used to undo Obama era climate policies. Inter alia, advantages and disadvantages of pursuing policy goals administratively, rather than through legislative processes, will be addressed.

Published

2021

7. Reduced adaptation of glutamatergic stress response is associated with pessimistic expectations in depression

Author

Jessica A. Cooper, Makiah R. Nuutinen, Victoria M. Lawlor, Brittany A. M. DeVries, Elyssa M. Barrick, Shabnam Hossein, Daniel J. Cole, Chelsea V. Leonard, Evan C. Hahn, Andrew P. Teer, Grant S. Shields, George M. Slavich, Dost Ongur, J. Eric Jensen, Fei Du, Diego A. Pizzagalli, and Michael T. Treadway

Subjects

Science

Abstract

Abstract Stress is a significant risk factor for the development of major depressive disorder (MDD), yet the underlying mechanisms remain unclear. Preclinically, adaptive and maladaptive stress-induced changes in glutamatergic function have been observed in the medial prefrontal cortex (mPFC). Here, we examine stress-induced changes in human mPFC glutamate using magnetic resonance spectroscopy (MRS) in two healthy control samples and a third sample of unmedicated participants with MDD who completed the Maastricht acute stress task, and one sample of healthy control participants who completed a no-stress control manipulation. In healthy controls, we find that the magnitude of mPFC glutamate response to the acute stressor decreases as individual levels of perceived stress increase. This adaptative glutamate response is absent in individuals with MDD and is associated with pessimistic expectations during a 1-month follow-up period. Together, this work shows evidence for glutamatergic adaptation to stress that is significantly disrupted in MDD.

Published

2021

8. Integrating Survival Analysis with Bayesian Statistics to Forecast the Remaining Useful Life of a Centrifugal Pump Conditional to Multiple Fault Types

Author

Abhimanyu Kapuria and Daniel G. Cole

Subjects

machine learning, remaining useful life, condition monitoring, probabilistic estimation, Bayesian networks, survival analysis, Technology

Abstract

To improve the viability of nuclear power plants, there is a need to reduce their operational costs. Operational costs account for a significant portion of a plant’s yearly budget, due to their scheduled-based maintenance approach. In order to reduce these costs, proactive methods are required that estimate and forecast the state of a machine in real time to optimize maintenance schedules. In this research, we use Bayesian networks to develop a framework that can forecast the remaining useful life of a centrifugal pump. To do so, we integrate survival analysis with Bayesian statistics to forecast the health of the pump conditional to its current state. We complete our research by successfully using the Bayesian network on a case study. This solution provides an informed probabilistic viewpoint of the pumping system for the purpose of predictive maintenance.

Published

2023

9. Development and Validation of the Quantum Mechanical Bespoke Protein Force Field

Author

Alice E. A. Allen, Michael J. Robertson, Michael C. Payne, and Daniel J. Cole

Subjects

Chemistry, QD1-999

Published

2019

10. A Qualitative Strategy for Fusion of Physics into Empirical Models for Process Anomaly Detection

Author

Ahmad Y. Al Rashdan, Hany S. Abdel-Khalik, Kellen M. Giraud, Daniel G. Cole, Jacob A. Farber, William W. Clark, Abenezer Alemu, Marcus C. Allen, Ryan M. Spangler, and Athi Varuttamaseni

Subjects

anomaly detection, physics models, empirical models, machine learning, Technology

Abstract

To facilitate the automated online monitoring of power plants, a systematic and qualitative strategy for anomaly detection is presented. This strategy is essential to provide credible reasoning on why and when an empirical versus hybrid (i.e., physics-supported) approach should be used and to determine the ideal mix of these two approaches for a defined anomaly detection scope. Empirical methods are usually based on pattern, statistical, and causal inference. Hybrid methods include the use of physics models to train and test data methods, reduce data dimensionality, reduce data-model complexity, augment data, and reduce empirical uncertainty; hybrid methods also include the use of data to tune physics models. The presented strategy is driven by key decision points related to data relevance, simple modeling feasibility, data inference, physics-modeling value, data dimensionality, physics knowledge, method of validation, performance, data availability, and suitability for training and testing, cause-effect, entropy inference, and model fitting. The strategy is demonstrated through a pilot use case for the application of anomaly detection to capture a valve packing leak at the high-pressure coolant injection system of a nuclear power plant.

Published

2022

11. Probability Calculations Within Stochastic Electrodynamics

Author

Daniel C. Cole

Subjects

stochastic electrodynamics, probabilistic, classical, multivariate, probability density, Physics, QC1-999

Abstract

Several stochastic situations in stochastic electrodynamics (SED) are analytically calculated from first principles. These situations include probability density functions, as well as correlation functions at multiple points of time and space, for the zero-point (ZP) electromagnetic fields, as well as for ZP plus Planckian (ZPP) electromagnetic fields. More lengthy analytical calculations are indicated, using similar methods, for the simple harmonic electric dipole oscillator bathed in ZP as well as ZPP electromagnetic fields. The method presented here makes an interesting contrast to Feynman’s path integral approach in quantum electrodynamics (QED). The present SED approach directly entails probabilities, while the QED approach involves summing weighted paths for the wave function.

Published

2021

12. Purpuric Plaques—Dermoscopic and Histopathological Correlation of Cutaneous Angiosarcoma

Author

Daniel W. Cole, Tomas Huerta, Aleodor Andea, and Trilokraj Tejasvi

Subjects

cutaneous angiosarcoma, dermoscopy, nonmelanocytic skin cancer, histopathology, Dermatology, RL1-803

Published

2020

13. The Importance of Indigenous Cartography and Toponymy to Historical Land Tenure and Contributions to Euro/American/Canadian Cartography

Author

Daniel G. Cole and E. Richard Hart

Subjects

Native Americans, first nations, historic cartography, toponymy, Geography (General), G1-922

Abstract

Indigenous maps are critical in understanding the historic and current land tenure of Indigenous groups. Furthermore, Indigenous claims to land can be seen in their connections via toponymy. European concepts of territory and political boundaries did not coincide with First Nation/American Indian views, resulting in the mistaken view that Natives did not have formal concepts of their territories. And Tribes/First Nations with cross-border territory have special jurisdictional problems. This paper illustrates how many Native residents were very spatially aware of their own lands, as well as neighboring nations’ lands, overlaps between groups, hunting territories, populations, and trade networks. Finally, the Sinixt First Nation serve as a perfect example of a case study on how an Aboriginal people are currently inputting and using a GIS representation of their territory with proper toponymy and use areas.

Published

2021

14. Dissipative preparation of W states in trapped ion systems

Author

Daniel C Cole, Jenny J Wu, Stephen D Erickson, Pan-Yu Hou, Andrew C Wilson, Dietrich Leibfried, and Florentin Reiter

Subjects

entanglement, trapped ions, quantum reservoir engineering, open quantum systems, dissipative control, Science, Physics, QC1-999

Abstract

We present protocols for dissipative entanglement of three trapped-ion qubits and discuss a scheme that uses sympathetic cooling as the dissipation mechanism. This scheme relies on tailored destructive interference to generate any one of six entangled W states in a three-ion qubit space. Using a beryllium–magnesium ion crystal as an example system, we theoretically investigate the protocol’s performance and the effects of likely error sources, including thermal secular motion of the ion crystal, calibration imperfections, and spontaneous photon scattering. We estimate that a fidelity of ∼98% may be achieved in typical trapped ion experiments with ∼1 ms interaction time. These protocols avoid timescale hierarchies for faster preparation of entangled states.

Published

2021

15. High-Strength Liquid Crystal Polymer–Graphene Oxide Nanocomposites from Water

Author

Ryan J. Fox, Maruti Hegde, Daniel P. Cole, Robert B. Moore, Stephen J. Picken, and Theo J. Dingemans

Subjects

General Materials Science

Abstract

We report on the morphology and mechanical properties of nanocomposite films derived from aqueous, hybrid liquid crystalline mixtures of rodlike aggregates of a sulfonated, all-aromatic polyamide, poly(2,2'-disulfonyl-4,4'-benzidine terephthalamide) (PBDT), and graphene oxide (GO) platelets. An isothermal step at 200 °C facilitates in situ partial thermal reduction of GO to reduced GO (rGO) in nanocomposite films. X-ray scattering studies reveal that PBDT-rGO nanocomposites exhibit both higher in-plane alignment of PBDT (the order parameter increases from 0.79 to 0.9 at 1.8 vol % rGO) and alignment along the casting direction (from 0.1 to 0.6 at 1.8 vol % rGO). From dynamic mechanical thermal analysis, the interaction between PBDT and rGO causes the β-relaxation activation energy for PBDT to increase with rGO concentration. Modulus mapping of nanocomposites using atomic force microscopy demonstrates enhanced local stiffness, indicating reinforcement. From stress-strain analysis, the average Young's modulus increases from 16 to 37 GPa at 1.8 vol % rGO and the average tensile strength increases from 210 to 640 MPa. Despite polymer alignment along the casting direction, an average transverse tensile strength of 230 MPa is obtained.

Published

2022

16. Mechanical behavior of 17-4 PH stainless steel processed by atomic diffusion additive manufacturing

Author

Jaret C. Riddick, Daniel P. Cole, Todd C. Henry, Madeline Morales, and Christopher M. Shumeyko

Subjects

0209 industrial biotechnology, Yield (engineering), Materials science, Mechanical Engineering, Young's modulus, 02 engineering and technology, Compression (physics), Industrial and Manufacturing Engineering, Grain size, Computer Science Applications, Shear (sheet metal), symbols.namesake, 020901 industrial engineering & automation, Control and Systems Engineering, Ultimate tensile strength, Shear strength, symbols, Composite material, Software, Electron backscatter diffraction

Abstract

This work explores the multiscale mechanical behavior of 17-4 PH stainless steel structures processed through the atomic diffusion additive manufacturing technique (ADAM). 17-4 PH stainless steel parts were fabricated with a Markforged Metal X 3D printer and characterized with respect to variable printing orientations for samples loaded in tension, shear, and bending. Sections of material were taken from each face of a bending test sample and prepared for microscopy to quantify porosity, grain size, and local stiffness and hardness. Microscale evaluation showed a porosity content of 3.3% on average across all faces. The yz face specifically showed the same sort of packing limitations often seen in other extrusion-based methods leading to greater porosity. An electron backscatter diffraction investigation showed a mean grain size of 6.5 μm with some grain alignment in the z-direction in the xz plane. Bulk material response in tension was dependent upon the print orientation of the sample. Cases where material was extruded entirely in the direction of loading saw a stiffness, strength, and strain to failure improvement of greater that 10% compared with other infill schemes. Shear testing revealed similar increases in strain to failure for samples with material extruded in only one direction compared with cross hatching at alternating orthogonal angles. Bend test results were similar in tension and compression regardless of orientation. For a sample printed with primary loading in the print plane (xy), the tensile modulus was 130–140 GPa, the tensile yield and ultimate strength were 600 MPa and 800 MPa, and the shear strength was 40.6 MPa on average.

Published

2021

17. AMB2018-03: Benchmark Physical Property Measurements for Material Extrusion Additive Manufacturing of Polycarbonate

Author

Jeffrey R. Westrich, Christopher M. Shumeyko, Sara V. Orski, Edward J. Garboczi, Kalman D. Migler, Jonathan E. Seppala, Jeffrey L. Gair, Daniel P. Cole, Todd C. Henry, and Frank Gardea

Subjects

Materials science, Shear thinning, Structural material, Rheology, Ultimate tensile strength, Modulus, General Materials Science, Extrusion, Molding (process), Composite material, Industrial and Manufacturing Engineering, Tensile testing

Abstract

Material extrusion (MatEx) is finding increasing applications in additive manufacturing of thermoplastics due to the ease of use and the ability to process disparate polymers. Since part strength is anisotropic and frequently deviates negatively with respect to parts produced by injection molding, an urgent challenge is to predict final properties of parts made through this method. A nascent effort is underway to develop theoretical and computational models of MatEx part properties, but these efforts require comprehensive experimental data for guidance and validation. As part of the AM-Bench framework, we provide here a thorough set of measurements on a model system: polycarbonate printed in a simple rectangular shape. For the precursor material (as-received filament), we perform rheology, gel permeation chromatography, and dynamical mechanical analysis, to ascertain critical material parameters such as molar mass distribution, glass transition, and shear thinning. Following processing, we conduct X-ray computed tomography, scanning electron microscopy, depth sensing indentation, and atomic force microscopy modulus mapping. These measurements provide information related to pores, method of failure, and local modulus variations. Finally, we conduct tensile testing to assess strength and degree of anisotropy of mechanical properties. We find several effects that lead to degradation of tensile properties including the presence of pore networks, poor interfacial bonding, variations in interfacial mechanical behavior between rasters, and variable interaction of the neighboring builds within the melt state. The results provide insight into the processing–structure–property relationships and should serve as benchmarks for the development of mechanical models.

Published

2020

18. In situ fatigue monitoring investigation of additively manufactured maraging steel

Author

Francis R. Phillips, Todd C. Henry, Robert A. Haynes, Daniel P. Cole, Terrence Johnson, and Edward J. Garboczi

Subjects

0209 industrial biotechnology, Void (astronomy), Digital image correlation, Materials science, Mechanical Engineering, Stiffness, 02 engineering and technology, engineering.material, Plasticity, Durability, Industrial and Manufacturing Engineering, Computer Science Applications, 020901 industrial engineering & automation, Control and Systems Engineering, engineering, medicine, Composite material, medicine.symptom, Porosity, Maraging steel, Software, Microscale chemistry

Abstract

This work describes an experimental validation set for assessing the real-time fatigue behavior of metallic additive manufacturing (AM) maraging steel structures. Maraging steel AM beams were fabricated with laser powder bed fusion (LPBF) and characterized with ex situ studies of porosity through X-ray computed tomography (CT), nano-indentation, and atomic force microscopy, as well as quasi-static testing to evaluate the as-printed state. Microscale evaluation showed void content of 0.34–0.36% with hardness and stiffness variation through the build direction on the order of 5.1–5.6 GPa and 139–154 GPa, respectively. The microscale inhomogeneities created an as-printed state where the compression and tension plasticity behavior at the macroscale was unequal in quasi-static loading, leading to greater yielding in tension. Specimens were subjected to cyclic loads, while the structural behavior was characterized through in situ magnetic permeability, digital image correlation (DIC) strain, and structural compliance measurements. In the range of 3 × 103 to 3 × 104 cycles to failure, magnetic permeability measurements were able to capture the mechanical state as early as 60% of life depending on failure location. Results are discussed with an emphasis on material-property-structure relationships in terms of the multi-scale material state and fatigue validation data for improving the durability of AM parts.

Published

2020

19. Protein-Mediated Synthesis of Au Nanocluster Decorated Reduced Graphene Oxide: A Multifunctional Hybrid Nano-Bio Platform

Author

J. Derek Demaree, Todd C. Henry, Daniel P. Cole, Mark H. Griep, and Shashi P. Karna

Subjects

chemistry.chemical_classification, Materials science, Graphene, Biomolecule, Biophysics, Oxide, Nanoparticle, Nanotechnology, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, law.invention, Nanomaterials, Nanoclusters, 010309 optics, chemistry.chemical_compound, chemistry, law, 0103 physical sciences, Nano, 0210 nano-technology, Hybrid material, Biotechnology

Abstract

The seamless integration of functional biomolecules with advanced nanomaterials not only allows for a hybrid material yielding their combined properties but also can enable novel joint functionality. In this work, the protein bovine serum albumin is used to simultaneously reduce and stabilize graphene oxide, demonstrating complete reduction of the graphene oxide to its reduced graphene oxide form. Where previous work has utilized a protein-reduced graphene oxide hybrid material as an attachment point for subsequent metal nanoparticle binding, this effort establishes an in situ methodology to directly synthesize tailored metal nanoclusters within the stabilizing protein complex. The successful synthesis of gold metal nanoclusters within the protein component of the hybrid system is verified, allowing for the creation of high-density protein-nanocluster ensembles on the graphene substrate. Utilizing the sensitive nature of the high-density protein-nanocluster materials, a protease sensor platform is demonstrated to detect the presence of trypsin, which is a biomarker for acute pancreatitis, at concentrations below 100 ng/mL.

Published

2020

20. USING DATA SCIENCE TO EVALUATE NANO-REINFORCED EPOXY SURFACES

Author

Chowdhury Ashraf, Jonathan Theim, Aniruddh Yashisth, Todd C. Henry, Utkarsh Dubey, Charles E. Bakis, Daniel P. Cole, and Ashutosh Srivastava

Subjects

Fracture toughness, Materials science, visual_art, Composite number, visual_art.visual_art_medium, Micromechanics, Modulus, Particle, Fracture mechanics, Epoxy, Data science, Elastic modulus

Abstract

Toughened composites reinforced with nanofillers show improved mechanical performance such as increased abrasion resistance, fracture toughness, and fracture energy. The degree of these improvements is influenced by the degree of dispersion of the nanofillers which can be analyzed using force microscopy (AFM), a technique that allows for mapping the local height and elastic modulus of a surface. However, current AFM apparatuses can only measure a narrow range of moduli according to the type of tip, which complicates the full-field measurement of moduli in nanocomposites with nanosilica (~72 GPa) embedded in epoxy (0.1 – 5 GPa). Moreover, height mapping can only visualize filler particles exposed at the surface. These limitations make it challenging to determine the 3D location of nanoparticles near the surface of a composite. To overcome these limitations of conventional AFM, we used a combination of data science, micromechanics, and experimental data from AFM to locate the centroidal position of nanosilica (NS) particles relative to the surrounding epoxy surface. Using finite element simulations, a theoretical dataset of modulus values as a function of particle position relative to the epoxy surface was created as a training set. Bayesian optimization determines the “best” particle position that results in minimum error between simulated and experimental modulus contours. The algorithm returns the 3D position of the fully or partially embedded NS particle relative to the epoxy surface. The algorithm has shown the ability to partially produce simulated modulus contours that resemble the experimental modulus contours.

Published

2021

21. Energy dissipation characteristics of additively manufactured CNT/ABS nanocomposites

Author

Jaret C. Riddick, Bryan Glaz, Frank Gardea, and Daniel P. Cole

Subjects

0209 industrial biotechnology, Materials science, Nanocomposite, Mechanical Engineering, Loss factor, Composite number, 02 engineering and technology, Carbon nanotube, Dissipation, 021001 nanoscience & nanotechnology, Industrial and Manufacturing Engineering, Viscoelasticity, law.invention, Stress (mechanics), 020901 industrial engineering & automation, law, Composite material, 0210 nano-technology, Elastic modulus

Abstract

Purpose This study aims to discuss the effect of carbon nanotubes (CNTs) on the mechanical properties of acrylonitrile–butadiene–styrene (ABS) composites fabricated by additive manufacturing (AM). Insight into the energy-dissipation mechanisms introduced and/or enhanced by the addition of CNTs is presented in this study. Design/methodology/approach ABS/CNT filaments were fabricated with different concentrations of CNTs. Using a fused deposition modeling approach, unidirectional specimens were printed using a MakerBot Replicator 2X (MakerBot Industries, Brooklyn, NY, USA). Specimens were tested under static and dynamic conditions, with the loading coinciding with the printing direction, to determine elastic modulus, strength and viscoelastic properties. Findings A CNT reinforcing effect is evident in a 37 per cent increase in elastic modulus. Likewise, the strength of the composite increases by up to 30 per cent with an increase in weight fraction of CNTs. At low dynamic strain amplitudes (0.05 per cent), a correlation between dissipated strain energy of the butadiene phase and strength of the composite is found such that less dissipation, from constraint of the butadiene particles by the CNTs, leads to higher strength of the composite. At higher dynamic strains, the presence of a high concentration of CNT leads to increased energy dissipation, with a maximum measured value of 24 per cent higher loss factor compared to baseline specimens. Because the trend of the composite behavior is similar (with a higher absolute value) to that of neat ABS, this study’s results indicate that well-established polymer/CNT dissipation mechanisms (such as stick-slip) are not significant, but that the CNTs amplify the dissipation of the ABS matrix by formation of crazes through stress concentrations. Originality/value This study provides knowledge of the dissipation behavior in additively manufactured ABS/CNT composites and provides insight into the expansion to new printable materials for dynamics applications.

Published

2019

22. Evaluation of Early Fatigue Signatures in Lightweight Aluminum Alloy 7075

Author

Volker Weiss, Robert A. Haynes, Jon-Erik Mogonye, Sean Fudger, Todd C. Henry, Daniel P. Cole, and Christopher M. Kube

Subjects

Materials science, Mechanical Engineering, Aerospace Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Signal, Durability, law.invention, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, law, Solid mechanics, Eddy current, Ultrasonic sensor, Electrical measurements, Composite material, Current (fluid), 0210 nano-technology, Microscale chemistry

Abstract

The current work investigates early material changes that manifest in aluminum alloy 7075 subjected to fatigue loading. Tension-tension specimens linearly tapered in width were exposed to cyclic loading with compliance and eddy current measurements made in-situ, while nano-indentation, surface potential, x-ray diffraction, and ultrasonic response were made ex-situ. Early stage damage progression was evaluated at various size scales and used to estimate a remaining life in real time. Baseline, in-situ, and post failure measurements were compared and analyzed as a function of fatigue cycles. Eddy current and compliance measurements showed a strong correlation between signal strength and fatigue life with eddy current providing a more precise signal per specimen. Microscale electrical measurements showed a link between surface potential and regions of the specimen that experienced higher tensile stress. Results are discussed with an emphasis on multiscale damage detection and identification due to fatigue cycling, while highlighting the most promising techniques for improving structural durability and real-time state monitoring.

Published

2019

23. Mechanism studies and fabrication for the incorporation of carbon into Al alloys by the electro-charging assisted process

Author

Yujia Liang, Daniel P. Cole, Lourdes Salamanca-Riba, Karen J. Gaskell, Xiaoxiao Ge, Manfred Wuttig, Christopher M. Shumeyko, Christopher J. Klingshirn, and Peter Y. Zavalij

Subjects

Kelvin probe force microscope, Nanotube, Materials science, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Electromigration, 0104 chemical sciences, Condensed Matter::Materials Science, symbols.namesake, Amorphous carbon, X-ray photoelectron spectroscopy, Chemical engineering, Electrical resistivity and conductivity, medicine, symbols, General Materials Science, 0210 nano-technology, Raman spectroscopy, Activated carbon, medicine.drug

Abstract

The incorporation of carbon nanostructures into Al alloys has the potential to further improve the mechanical and electrical properties of these alloys. We report a novel one-step fabrication method of incorporating carbon in aluminum alloys by the application of a high electric current to molten Al metal containing particles of activated carbon at high temperature and under Ar atmosphere. We propose that the mechanism for carbon incorporation is similar to electromigration where the current facilitates ionization of the carbon atoms followed by polymerization of the carbon structures and the formation of graphitic chains and ribbons along preferred directions of the Al lattice. Furthermore, the current induces transformation from amorphous carbon to crystalline graphitic structures that propagate in the metal matrix. The carbon is identified by the C-K edge in electron energy loss spectra, X-ray photoelectron spectroscopy, Raman and Kelvin probe force microscopy. The stiffness is increased in these samples; hardness, on the other hand, decreases for some samples compared to reference Al alloys with no carbon. The electrical conductivity is superior to that of Al-carbon nanotube composites previously reported. The enhanced properties of Al covetics show potential for naval and aerospace applications and power transmission lines.

Published

2019

24. Structural state awareness through integration of global dynamic and local material behavior

Author

Robert A. Haynes, Tomoko Sano, Daniel P. Cole, Todd C. Henry, Ed Habtour, Christopher M. Kube, Tiedo Tinga, and Frank Gardea

Subjects

business.industry, Computer science, Mechanical Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Reliability engineering, 020303 mechanical engineering & transports, 0203 mechanical engineering, General Materials Science, State (computer science), Structural health monitoring, 0210 nano-technology, Aerospace, business, Reliability (statistics)

Abstract

Structural health monitoring and nondestructive inspection techniques typically assess the lifecycle and reliability of high-value aerospace, mechanical, and civil systems. Maintenance and inspection intervals are typically time-based and dependent on the structural health monitoring/nondestructive inspection technique to detect macroscale damage resulting from fatigue or environmental damage. The current work proposes an integrated materials-structures-dynamics approach for providing state awareness of structural health. The proposed approach shifts the conventional structural health monitoring/nondestructive inspection focus of searching for cracks to a health state awareness based on tracking changes in the energetics of the materials-structures-dynamics states. Energy variations are tracked in a cantilevered structure exposed to nonlinear harmonic oscillation, where the strain energy of the beam was derived and used to determine a health state index. Nanoindentation was used to probe the near-surface mechanical properties of the beam to characterize local material variations as a function of fatigue cycles. A nonlinear ultrasonic approach was considered in order to connect the local material behavior changes to the variations in the dynamic performance of the beam. The intent of the investigation was to connect the traditionally detached materials, structural, and dynamics approaches to structural health monitoring/nondestructive inspection, while providing a framework for enabling damage precursor detection.

Published

2019

25. A microrod-resonator Brillouin laser with 240 Hz absolute linewidth

Author

William Loh, Joe Becker, Daniel C Cole, Aurelien Coillet, Fred N Baynes, Scott B Papp, and Scott A Diddams

Subjects

microresonators, lasers, stimulated Brillouin scattering, narrow linewidth, Science, Physics, QC1-999

Abstract

We demonstrate an ultralow-noise microrod-resonator based laser that oscillates on the gain supplied by the stimulated Brillouin scattering optical nonlinearity. Microresonator Brillouin lasers are known to offer an outstanding frequency noise floor, which is limited by fundamental thermal fluctuations. Here, we show experimental evidence that thermal effects also dominate the close-to-carrier frequency fluctuations. The 6 mm diameter microrod resonator used in our experiments has a large optical mode area of ∼100 μ m ^2 , and hence its 10 ms thermal time constant filters the close-to-carrier optical frequency noise. The result is an absolute laser linewidth of 240 Hz with a corresponding white-frequency noise floor of 0.1 Hz ^2 Hz ^−1 . We explain the steady-state performance of this laser by measurements of its operation state and of its mode detuning and lineshape. Our results highlight a mechanism for noise that is common to many microresonator devices due to the inherent coupling between intracavity power and mode frequency. We demonstrate the ability to reduce this noise through a feedback loop that stabilizes the intracavity power.

Published

2016

26. Probability of Water Fixture Use during Peak Hour in Residential Buildings

Author

Toritseju (Toju) Omaghomi, Timothy Wolfe, Steven G. Buchberger, Jason Hewitt, and Daniel P Cole

Subjects

Hydrology, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Geography, Planning and Development, 02 engineering and technology, Management, Monitoring, Policy and Law, Fixture, 01 natural sciences, Peak water, 020801 environmental engineering, Water demand, Binomial distribution, Environmental science, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering

Abstract

The standard method for estimating instantaneous peak water use in premise plumbing systems (PPSs) is Hunter’s (1940) design curve, showing water demand versus fixture units. In recent year...

Published

2020

27. Hierarchical Mechanisms of Lateral Interactions in High-Performance Fibers

Author

Dimitry Papkov, Taylor A. Stockdale, Michael R. Roenbeck, Jeffrey M. Staniszewski, Kenneth E. Strawhecker, Daniel P. Cole, Steve R. Lustig, and Youris A Dzenis

Subjects

chemistry.chemical_classification, Materials science, chemistry, General Materials Science, Nanotechnology, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 0210 nano-technology, 01 natural sciences, 0104 chemical sciences

Abstract

The processing conditions used in the production of advanced polymer fibers facilitate the formation of an oriented fibrillar network that consists of structures spanning multiple length scales. The irregular nature of fiber tensile fracture surfaces suggests that their structural integrity is defined by the degree of lateral (interfacial) interactions that exist within the fiber microstructure. To date, experimental studies have quantified interfacial adhesion between nanoscale fibrils measuring 10-50 nm in width, and the global fracture energy through applying peel loads to fiber halves. However, a more in-depth evaluation of tensile fracture indicates that fiber failure typically occurs at an intermediate length scale, involving fibrillation along interfaces between fibril bundles of a few 100s of nanometers in width. Interaction mechanisms at this length scale have not yet been studied, due in part to a lack of established experimental techniques. Here, a new focused ion beam-based sample preparation protocol is combined with nanoindentation to probe interfaces at the intermediate length scale in two high-performance fibers, a rigid-rod poly(

Published

2020

28. Outcomes and Conclusions from the 2018 AM-Bench Measurements, Challenge Problems, Modeling Submissions, and Conference

Author

Fan Zhang, Erich D. Bain, Jason C. Fox, Brandon M. Lane, Mark R. Stoudt, Thien Q. Phan, Andrew J. Allen, Jonathan E. Seppala, Lyle E. Levine, Daniel P. Cole, Michael R. Hill, Edward J. Garboczi, Richard E. Ricker, Kalman B. Migler, Jarred C. Heigel, Maria Strantza, and Carelyn E. Campbell

Subjects

Test series, AM-Bench, Computer science, Additive manufacturing, Benchmarks, Model validation, Material system, Industrial and Manufacturing Engineering, Benchmark (surveying), Metallic materials, Powder bed, Systems engineering, General Materials Science, Measurement test

Abstract

The Additive Manufacturing Benchmark (AM-Bench) test series was established to provide rigorous measurement test data for validating additive manufacturing (AM) simulations for a broad range of AM technologies and material systems. AM-Bench includes extensive in situ and ex situ measurements, simulation challenges for the AM modeling community, and a corresponding conference series. In 2018, the first round of AM-Bench measurements and the first AM-Bench conference were completed, focusing primarily upon laser powder bed fusion (LPBF) processing of metals, and both LPBF and material extrusion processing of polymers. In all, 46 blind modeling simulations were submitted by the international AM community in comparison with the in situ and ex situ measurements. Analysis of these submissions provides valuable insight into existing AM modeling capabilities. The AM-Bench data are permanently archived and freely accessible online.

Published

2020

29. Using data science to locate nanoparticles in a polymer matrix composite

Author

Jonathan Thiem, Daniel P. Cole, Utkarsh Dubey, Ashutosh Srivastava, Chowdhury Ashraf, Todd C. Henry, Charles E. Bakis, and Aniruddh Vashisth

Subjects

General Engineering, Ceramics and Composites

Published

2022

30. Strong process-structure interaction in stoveable poly(urethane-urea) aligned carbon nanotube nanocomposites

Author

Robert H. Lambeth, Brian L. Wardle, Hugh A. Bruck, Itai Y. Stein, Dale L. Lidston, Mark L. Bundy, Daniel P. Cole, Alex J. Hsieh, Jeffrey L. Gair, and Estelle Kalfon-Cohen

Subjects

Thermogravimetric analysis, Nanocomposite, Materials science, Polymer nanocomposite, General Engineering, 02 engineering and technology, Carbon nanotube, Dynamic mechanical analysis, Nanoindentation, 010402 general chemistry, 021001 nanoscience & nanotechnology, Elastomer, 01 natural sciences, 0104 chemical sciences, law.invention, law, Phase (matter), Ceramics and Composites, Composite material, 0210 nano-technology

Abstract

The exceptional static and dynamic physical properties of poly(urethane-urea) (PUU) elastomers make them prime candidates for impulsive loading structural applications, such as blast protection coatings. Since the theoretical physical properties of carbon nanotubes (CNTs) are among the best for any currently known material, a number of previous studies explored the use of CNTs as nanoscale fillers to enhance the properties of PUU nanocomposites. However, due to the challenges inherent in dispersing CNTs in a PUU matrix and the resulting random orientation of the CNTs, these previous works observed marginal improvements in physical properties, and were unable to establish clear structure-property relations. Here, we report the synthesis of aligned-CNT (A-CNT) reinforced PUU polymer nanocomposites (A-PNCs) by infusing A-CNT forests with a stoveable PUU, and establish process-structure-property relations that quantify the contribution of CNT confinement on the PUU mechanical response. This stoveable process was achieved using blocked isocyanate which prevented polymerization until the blocks were removed with heat. PUUs of two distinct compositions were explored: one with 40 wt% hard-segment content (PUU211) and the other with 66 wt% hard-segment content (PUU541). Thermogravimetric analysis indicates that A-CNTs enhance the thermal stability of the hard-segment phase in PUU A-PNCs at 340 °C by up to 45% over the baseline PUUs. Atomic force microscopy reveals that the elongated nanophase hard-segment formations along the CNT axis observed only in the nanocomposites were of similar characteristic size to the average inter-A-CNT spacing (∼70 nm), indicating a strong influence of A-CNTs on the size and orientation of hard-segment nanophases, as corroborated via small angle X-ray scattering. Nanoindentation testing reveals that PUU A-PNCs possess significant elastic anisotropy, and exhibit enhanced longitudinal effective indentation moduli of ∼460 MPa (>3 × that of the PUU211 baseline) and ∼1350 MPa (∼1.5 × that of the PUU541 baseline) for PUU211 and PUU541 nanocomposites, respectively. This difference in magnitude of CNT reinforcement efficacy indicates that CNT confinement leads to significant hard-segment re-organization in the PUU211 A-PNCs, whereas the interconnected network of hard-segments in the PUU541 is affected by CNT templating to a lesser extent. Dynamic nanoindentation testing results are consistent with these interpretations, where longitudinally-loaded PUU211 A-PNCs are found to exhibit a >3 × enhancement in storage modulus at 1 Hz of ∼730 MPa, whereas the longitudinally-loaded PUU541 A-PNCs exhibit a slightly enhanced storage modulus enhancement at 1 Hz of 2190 MPa (∼1.5 × that of the PUU541 baseline). Reinforcement of PUUs with A-CNTs is a promising way to tune the physical properties of the PNCs; higher A-CNT packing densities, where the inter-CNT spacing could approach the nanophase characteristic diameter, could further enhance the PUU performance in ballistic protection applications.

Published

2018

31. Interrogation of the protein-protein interactions between human BRCA2 BRC repeats and RAD51 reveals atomistic determinants of affinity.

Author

Daniel J Cole, Eeson Rajendra, Meredith Roberts-Thomson, Bryn Hardwick, Grahame J McKenzie, Mike C Payne, Ashok R Venkitaraman, and Chris-Kriton Skylaris

Subjects

Biology (General), QH301-705.5

Abstract

The breast cancer suppressor BRCA2 controls the recombinase RAD51 in the reactions that mediate homologous DNA recombination, an essential cellular process required for the error-free repair of DNA double-stranded breaks. The primary mode of interaction between BRCA2 and RAD51 is through the BRC repeats, which are ∼35 residue peptide motifs that interact directly with RAD51 in vitro. Human BRCA2, like its mammalian orthologues, contains 8 BRC repeats whose sequence and spacing are evolutionarily conserved. Despite their sequence conservation, there is evidence that the different human BRC repeats have distinct capacities to bind RAD51. A previously published crystal structure reports the structural basis of the interaction between human BRC4 and the catalytic core domain of RAD51. However, no structural information is available regarding the binding of the remaining seven BRC repeats to RAD51, nor is it known why the BRC repeats show marked variation in binding affinity to RAD51 despite only subtle sequence variation. To address these issues, we have performed fluorescence polarisation assays to indirectly measure relative binding affinity, and applied computational simulations to interrogate the behaviour of the eight human BRC-RAD51 complexes, as well as a suite of BRC cancer-associated mutations. Our computational approaches encompass a range of techniques designed to link sequence variation with binding free energy. They include MM-PBSA and thermodynamic integration, which are based on classical force fields, and a recently developed approach to computing binding free energies from large-scale quantum mechanical first principles calculations with the linear-scaling density functional code onetep. Our findings not only reveal how sequence variation in the BRC repeats directly affects affinity with RAD51 and provide significant new insights into the control of RAD51 by human BRCA2, but also exemplify a palette of computational and experimental tools for the analysis of protein-protein interactions for chemical biology and molecular therapeutics.

Published

2011

32. Synthesis and characterization of copper-nanocarbon films with enhanced stability

Author

Karen J. Gaskell, Lourdes Salamanca-Riba, H. M. Iftekhar Jaim, Romaine Isaacs, Daniel P. Cole, and Oded Rabin

Subjects

010302 applied physics, Materials science, Electron energy loss spectroscopy, Analytical chemistry, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Copper, Pulsed laser deposition, Carbon film, X-ray photoelectron spectroscopy, chemistry, 0103 physical sciences, General Materials Science, 0210 nano-technology, Carbon, Sheet resistance, Deposition (law)

Abstract

Copper-nanocarbon, called covetic, films made using pulsed laser deposition (PLD) from a target containing nominally 4 wt% carbon in the copper matrix show uniform integration of up to 4.1 ± 0.2 wt.% C. We observe evidence of s p 2 carbon in PLD Cu covetic films in XPS and a peak in the C K-edge in electron energy loss spectroscopy indicative of transitions from the 1s to π * anti-bonding unoccupied state, suggesting that the C incorporated in the film is graphitic in nature. We measure sheet resistance of 1.7 Ohm/sq and transmittance of 25% at 550 nm in a ≈ 27 nm thick PLD Cu covetic film after deposition. These films also show much reduced oxidation by scanning probe techniques and very stable resistance for over 120 days - significantly longer than e-beam films of the same thickness. Cu covetic films made by PLD show good promise as transparent electrodes.

Published

2017

33. Interphase mechanical behavior of carbon fiber reinforced polymer exposed to cyclic loading

Author

Todd C. Henry, Frank Gardea, Daniel P. Cole, and Robert A. Haynes

Subjects

Carbon fiber reinforced polymer, Materials science, business.product_category, Composite number, General Engineering, Shell (structure), 02 engineering and technology, Nanoindentation, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Core (optical fiber), Microfiber, Ceramics and Composites, Interphase, Fiber, Composite material, 0210 nano-technology, business

Abstract

A micro-/nano-scale technique is presented for characterizing early stage damage formation on un-sized individual carbon fibers as well as embedded carbon fibers exposed to cyclic loads. Nanoindentation and atomic force microscopy were used to study the local mechanical properties and morphology of composite constituents before and after cyclic loading. Samples were of the type: 1) un-sized individual carbon fiber and 2) carbon fibers embedded in an epoxy matrix. Contributions from the structural compliance were isolated from the indentations in order to track variations in interphase properties due to global fatigue. When tested in the radial direction, the fiber shell was found to be approximately 50% stiffer than the fiber core. Indentations on fibers within a composite cycled to 100% of fatigue life revealed a compliance effect of roughly 5 GPa with respect to fibers within a control composite. The experimental results are compared to a finite element analysis model in order to help understand the mechanical influence of the interphase in the presence of the elastically-mismatched fibers and matrix. The work is a first step toward understanding damage precursor formation in individual microfibers and composite interphase regions; the work is expected to enable multiscale composite modeling efforts as well as the development of future self-sensing materials.

Published

2017

34. Local Mechanical Behavior of Steel Exposed to Nonlinear Harmonic Oscillation

Author

Daniel P. Cole, Ed Habtour, Anshuman Dasgupta, Sean Fudger, Scott M Grendahl, and T. Sano

Subjects

Diffraction, Materials science, Cantilever, Connecting nonlinearities, Aerospace Engineering, Modulus, 02 engineering and technology, Nanoindentation, 0203 mechanical engineering, Indentation, Composite material, Nondestructive testing, Fatigue, Damage precursor, business.industry, Mechanical Engineering, Micromechanics, Structural engineering, Dissipation, 021001 nanoscience & nanotechnology, Physics::Classical Physics, 020303 mechanical engineering & transports, Mechanics of Materials, Nonlinear dynamics, 0210 nano-technology, business, Electron backscatter diffraction

Abstract

The local mechanical behavior of fatigued steel specimens was probed using nanoindentation. High-carbon steel cantilevers were exposed to nonlinear harmonic oscillation. The indentation modulus on the beam surface and plastic work during indentation decreased as a function of cycles, which was attributed to grain fragmentation and reorientation as well as the continuous reduction in inherent energy dissipation capacity of the material. X-ray diffraction, electron backscatter diffraction, and atomic force microscopy were used to characterize this microstructural evolution during early stages of the beam fatigue life, which altered 1) the local mechanical properties and 2) the global structural dynamic response. The results provide insight into fatigue damage precursors and provides a framework for connecting materials evolution with nonlinear structural dynamics.

Published

2017

35. Characterization of carbon nanostructures in Al and Ag covetic alloys

Author

H. M. Iftekhar Jaim, Daniel P. Cole, and Lourdes Salamanca-Riba

Subjects

Kelvin probe force microscope, Materials science, Graphene, Electron energy loss spectroscopy, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, law.invention, symbols.namesake, X-ray photoelectron spectroscopy, Amorphous carbon, Chemical engineering, chemistry, law, symbols, General Materials Science, 0210 nano-technology, Raman spectroscopy, Carbon, Graphene nanoribbons

Abstract

Electrocharging assisted process is a method for the incorporation of carbon in molten metals under high electric current which results in the formation of networks of carbon nanostructures inside the metal matrix, and gives the new material improved mechanical, electrical and thermal properties. Alloys produced with this method are called covetics. In our previous works, different characterization techniques such X-ray photoelectron spectroscopy (XPS), Raman, X-ray diffraction (XRD), transmission electron microscopy (TEM) and electron energy loss spectroscopy (EELS) confirmed the presence of sp2 crystalline graphene nanoribbons and sheets in Ag and Al-covetic samples. Here, we report on detailed Raman mapping and characterization of Al-6061, Al-7075 and Ag covetics to further investigate the fraction of sp2/sp3 bonding, strain, defects, degree of oxidation, and crystalline sizes of the graphene nanoribbons. Gradual changes of strain are observed in regions with sp2 bonding and some degree of amorphous carbon is revealed by Raman scattering. Different degrees of oxidation of the carbon nanostructures with mostly sp2 bonding are evident by EELS spectrum imaging. Atomic force microscopy (AFM) and Kelvin probe force microscopy (KPFM) also reveal the presence of graphene ribbons and sheets with different lengths and conductivity.

Published

2017

36. Tunable mechanical behavior of graphene nanoribbon-metal composites fabricated through an electrocharge-assisted process

Author

Christopher J. Klingshirn, Lourdes Salamanca-Riba, Christopher M. Shumeyko, Daniel P. Cole, and Xiaoxiao Ge

Subjects

Materials science, Graphene, Mechanical Engineering, 02 engineering and technology, Plasticity, Nanoindentation, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, 01 natural sciences, 0104 chemical sciences, law.invention, Mechanics of Materials, law, Phase (matter), General Materials Science, Composite material, 0210 nano-technology, Nanoscopic scale, Single crystal, Graphene nanoribbons

Abstract

This work investigates the role of a carbon nanophase on the local mechanical behavior of nano-carbon metal composites (NCMCs) produced through an electrocharge-assisted process. Nanoindentation experiments on single crystal Al, Al 1350 parent alloys, and Al 1350 NCMCs revealed variable mechanical properties, caused by an interplay between microstructure and graphitic reinforcements. TEM and AFM studies also reveal nanoscale structural changes based on the incorporation of a carbon nanophase. In order to decouple the effects of the aforementioned mechanical behaviors, molecular dynamics nanoindentation simulations were performed on the (111) surface of Al and Al NCMC samples containing semi-infinite graphene nanoribbons to examine the evolution of plasticity over time. Findings indicate that the arrangement of a finite graphene nanophase within a host matrix can alter plasticity mechanisms and therefore yield strength in near-surface mechanical behaviors with little effect on elastic properties. This understanding should enable further study into tunable bulk properties of Al-based NCMCs while isolating microstructural effects and reinforcement effects of the carbon phase. Such an understanding could lead to application-specific material geometries ranging from high-performing vehicle structures to next-generation electrical devices.

Published

2021

37. Sp2 carbon embedded in Al-6061 and Al-7075 alloys in the form of crystalline graphene nanoribbons

Author

Melburne C. LeMieux, Maija M. Kuklja, Romaine Isaacs, H. M. Iftekhar Jaim, Lourdes Salamanca-Riba, Iwona Jasiuk, Sabrina Nilufar, Sergey N. Rashkeev, and Daniel P. Cole

Subjects

Materials science, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, law.invention, symbols.namesake, law, C/AL, General Materials Science, computer.programming_language, Kelvin probe force microscope, Graphene, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Chemical physics, symbols, Carbide-derived carbon, 0210 nano-technology, Raman spectroscopy, computer, Carbon, Raman scattering, Graphene nanoribbons

Abstract

Electrocharging assisted process has been used to incorporate carbon in Aluminum 6061 and 7075 alloys ensuing significant improvements of the ultimate tensile strength, hardness, and electrical conductivity. This work investigates the presence of carbon, its structure, carbon-metal bonding, surface characterization and dispersion of carbon incorporated in Al alloys by electrocharging assisted process. Networks of Graphene nanoribbons with 3D epitaxy and preferred orientation along the 〈110〉 and 〈112〉 directions of Al are evident by transmission electron microscopy and spectrum imaging of the C K edge electron energy loss spectra. X-ray photoelectron spectroscopy and Raman scattering corroborate sp 2 carbon in Al-6061, and hybrid sp 2 -sp 3 in Al-7075 with added carbon. Kelvin probe force microscopy substantiates the presence of carbon in the Al matrix. Phonon density of states derived from first-principles calculations predicts C Al Raman active modes whilst density functional theory indicates covalent bonding between carbon and Al. This method of incorporation of graphene nanostructures in metals with strong carbon-metal bonding can open up new avenues for incorporation of sp 2 carbon structures in other materials.

Published

2016

38. In situ Synthesis of Fluorescent Gold Nanoclusters by Nontumorigenic Microglial Cells

Author

Shashi P. Karna, Abby L. West, Elizabeth I. Maurer-Gardner, Nicole M. Schaeublin, Alexis M. Fakner, Daniel P. Cole, Saber M. Hussain, and Mark H. Griep

Subjects

In situ, Protein function, Materials science, Metal Nanoparticles, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Fluorescence, 0104 chemical sciences, Nanoclusters, Spectrometry, Fluorescence, Cell culture, Biophysics, General Materials Science, Gold, 0210 nano-technology, Metal nanoparticles, Cellular proteins

Abstract

To date, the directed in situ synthesis of fluorescent gold nanoclusters (AuNCs) has only been demonstrated in cancerous cells, with the theorized synthesis mechanism prohibiting AuNC formation in nontumorigenic cell lines. This limitation hinders potential biostabilized AuNC-based technology in healthy cells involving both chemical and mechanical analysis, such as the direct sensing of protein function and the elucidation of local mechanical environments. Thus, new synthesis strategies are required to expand the application space of AuNCs beyond cancer-focused cellular studies. In this contribution, we have developed the methodology and demonstrated the direct in situ synthesis of AuNCs in the nontumorigenic neuronal microglial line, C8B4. The as-synthesized AuNCs form in situ and are stabilized by cellular proteins. The clusters exhibit bright green fluorescence and demonstrate low (10%) toxicity. Interestingly, elevated ROS levels were not required for the in situ formation of AuNCs, although intracellular reductants such as glutamate were required for the synthesis of AuNCs in C8B4 cells. To our knowledge, this is the first-ever demonstration of AuNC synthesis in nontumorigenic cells and, as such, it considerably expands the application space of biostabilized fluorescent AuNCs.

Published

2016

39. Fractographic analysis of tensile failure of acrylonitrile-butadiene-styrene fabricated by fused deposition modeling

Author

Oluwakayode Bamiduro, Jaret C. Riddick, Ray Von Wahlde, Terrence Johnson, Mulugeta A. Haile, and Daniel P. Cole

Subjects

0209 industrial biotechnology, Materials science, Fabrication, Scanning electron microscope, Biomedical Engineering, Modulus, Young's modulus, 02 engineering and technology, Industrial and Manufacturing Engineering, law.invention, chemistry.chemical_compound, symbols.namesake, 020901 industrial engineering & automation, law, Ultimate tensile strength, General Materials Science, Composite material, Anisotropy, Engineering (miscellaneous), Fused deposition modeling, business.industry, Acrylonitrile butadiene styrene, Structural engineering, 021001 nanoscience & nanotechnology, chemistry, symbols, 0210 nano-technology, business

Abstract

The aim of the present study is to utilize fractographic methods employing scanning electron microscope (SEM) images to investigate the effects of build direction and orientation on the mechanical response and failure mechanism for Acrylonitrile–Butadiene–Styrene (ABS) specimens fabricated by fused deposited modeling (FDM). The material characterized here is ABS-M30 manufactured by Stratasys, Inc. Measurements of tensile strength, elongation-at-break and tensile modulus measurements along with the failure surfaces were characterized on a range of specimens at different build direction and raster orientation: ±45°, 0°, 0/90°, and 90°. The analysis of mechanical testing of the tensile specimens until failure will contribute to advances in creating stronger and more robust structure for various applications. Parameters, such as build direction and raster orientation, can be interdependent and exhibit varying effects on the properties of the ABS specimens. The ABS-M30 specimens were found to exhibit anisotropy in the mechanical response when exposed to axial tensile loading. The stress-strain data was characterized by a monotonic increase with an abrupt failure signifying brittle fracture. In certain combinations of build direction and raster orientation tensile failure was preceded by slight softening. The tensile strength and modulus, and elongation-at-break were found to be highly dependent upon the raster orientation and build direction. The relationship between the mechanical properties and failure was established by fractographic analysis. The fractographic analysis offers insight and provides valuable experimental data for the purpose of building structures in orientations tailored to their exemplified strength. For instance, specimens loaded such that bonds between adjacent rasters are the primary load bearing mechanism offer the least significant failure resistance. Other examples are shown where artifacts of the FDM fabrication process act to enhance tensile strength when configured properly with respect to the load. The results highlighted in this study are fundamental to the development of optimal design of complex ultra-light structure weight with increased structural efficiency. The study also presents a systematic scheme employing analogs to traditional fiber-reinforced polymer composites for the designation of build orientation and raster orientation parameters.

Published

2016

40. Damage precursor detection for structures subjected to rotational base vibration

Author

Ed Habtour, Raman Sridharan, Samuel C. Stanton, Abhijit Dasgupta, and Daniel P. Cole

Subjects

Cantilever, Materials science, Applied Mathematics, Mechanical Engineering, Natural frequency, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Stiffening, Vibration, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, Fictitious force, Structural health monitoring, 0210 nano-technology, Softening, Beam (structure)

Abstract

This paper presents a nonlinear dynamic methodology for monitoring precursors of fatigue damage in metallic structures under variable rotational base excitation. The methodology accounts for important nonlinearities due to the complex loading generated by variable rotation and structural degradation. The sources of the nonlinearities include: structural stiffening due to gyroscopic motion and high-response amplitude at the fundamental mode, softening due to inertial forces and gyroscopic loads, and localized microscopic material damage and micro-plasticity. The loading intensity and number of vibration cycles increase the influence of these effects. The change in the dynamic response due to fatigue damage accumulation is experimentally investigated by exciting a cantilever beam at variable rotational base motions. The observed fatigue evolution in the material microstructure at regions of large stresses (and the resulting progressive structural softening) is tracked by quantifying the growth in the tip response, the change in the fundamental natural frequency of the beam and the skewedness of the stepped-sine response curve. Previous understanding of the structural dynamic behavior is necessary to ascertain the damage precursor location and evolution. Nanoindentation studies near the beam clamped boundary are conducted to confirm the gradual progression in the local mechanical properties as a function of loading cycles, and microstructural studies are conducted to obtain qualitative preliminary insights into the microstructure evolution. This study demonstrates that careful monitoring of the nonlinearities in the structural dynamic response can be a sensitive parameter for detection of damage precursors.

Published

2016

41. Detection of fatigue damage precursor using a nonlinear vibration approach

Author

Mark Robeson, Ed Habtour, Jaret C. Riddick, Volker Weiss, Daniel P. Cole, Abhijit Dasgupta, and Raman Sridharan

Subjects

Cantilever, Materials science, business.industry, Stiffness, 02 engineering and technology, Building and Construction, Structural engineering, 021001 nanoscience & nanotechnology, Stiffening, Vibration, Nonlinear system, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, medicine, Structural health monitoring, medicine.symptom, 0210 nano-technology, business, Softening, Civil and Structural Engineering, Vibration fatigue

Abstract

Summary A nonlinear dynamic methodology is developed for detecting and estimating fatigue damage precursor in isotropic metal structures, prior to fatigue crack initiation, based on measurement of changes in the structure nonlinear response to harmonic base excitation. As an example, a damage precursor feature was extracted for cantilever beams by quantifying the reduction in the nonlinear stiffness because of localized microscopic material softening. The nonlinear dynamic analytical model parametrically tracks changes in the nonlinear structural stiffening as a function of the structural response and the loading cycles. Experimental results are obtained by exciting the base of cantilever beams at various amplitude levels. At high response amplitudes, the beams experience three competing simultaneous nonlinear dynamic mechanisms: (i) stiffening because of high response amplitude at the fundamental mode; (ii) softening because of inertial forces; and (iii) softening because of localized microscopic material damage caused by cyclic micro-plasticity. The third mechanism—a potential precursor to fatigue crack initiation in the structure—resulted in a cumulative softening because of early accumulation of cyclic fatigue damage and is the focus of this study. The loading intensity and the number of cycles influenced the relative contribution of these dynamic mechanisms. Nanoindentation studies near the beam clamped boundary were conducted to confirm the fatigue degradation in the local mechanical properties as a function of loading cycles. The proposed detection method is simple to implement and detects the presence of damage precursors but lacks the resolution to discern spatial distributions of the damage intensity. Based on prior knowledge of the structural dynamic characteristics of the beam and using the proposed methodology, damage level and stiffness reduction can be detected and estimated based on changes in the nonlinear structural response. The nonlinear stiffness term in the equation of motion is found to be very sensitive to the proposed fatigue damage precursor, making it an effective method for monitoring structural degradation prior to crack developments. The proposed methodology provides new insights and constitutes a significant step toward the development of new inspection techniques. Copyright © 2016 John Wiley & Sons, Ltd.

Published

2016

42. Understanding compressive strength improvement of high modulus carbon-fiber reinforced polymeric composites through fiber-matrix interface characterization

Author

Sanjit Bhowmick, Daniel J. Magagnosc, Sarvenaz Ghaffari, Guillaume Seon, Andrew Makeev, and Daniel P. Cole

Subjects

Polymer-matrix composites (PMCs), Scanning electron microscopy (SEM), Materials science, Scanning electron microscope, Composite number, Modulus, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Shear modulus, lcsh:TA401-492, Shear strength, medicine, High-modulus carbon fiber, General Materials Science, Composite material, In-situ nanomechanics, chemistry.chemical_classification, Mechanical Engineering, Stiffness, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Interface strength, Compressive strength, chemistry, Mechanics of Materials, lcsh:Materials of engineering and construction. Mechanics of materials, Strength, medicine.symptom, 0210 nano-technology

Abstract

Low fiber-direction compressive strength of high-modulus (HM) carbon fiber-reinforced polymers (CFRPs) has been their major weakness prohibiting implementation of such materials in aircraft primary structures despite improving mechanical stiffness at a lower weight. A new HM CFRP achieving fiber-direction compressive strength of intermediate-modulus (IM) CFRPs but with more than 30% higher axial modulus has been recently developed. This work looks into fiber-matrix interface shear strength as a potential mechanism driving the compression strength improvement of the new material system. In-situ scanning electron microscopy (SEM) based single fiber push-out experiments addressing standing challenges associated with manufacturing high-quality samples as well as distinguishing same-diameter HM and IM carbon fibers in the hybrid composite system are used to measure fiber-matrix interface shear strength. The experiments show a 29% lower average value of the fiber-matrix interface shear strength for the HM carbon fibers compared to the IM carbon fibers in the new material system. Such a significant reduction corresponds to a 22% lower fiber-direction compressive strength of the HM CFRP without the integrated IM fibers. The results support the idea of integrating off-the-shelf IM carbon fibers with a stronger fiber-matrix interface and a higher shear modulus into HM CFRPs to improve their compressive strength.

Published

2020

43. Damage Precursor Assessment in Aerospace Structural Materials

Author

Yan Chen, Robert A. Haynes, Ke An, Daniel P. Cole, and Todd C. Henry

Subjects

Engineering, Structural material, business.industry, Aerospace, business, Manufacturing engineering

Abstract

The focus of this study was to apply a robust inspection technique for monitoring damage nucleation and propagation in 7075 aluminum alloy specimens exposed to cyclic loading. A previously developed specimen, linearly tapered in width along the length, was subjected to a sinusoidal tension-tension load while conductivity and strain were measured in-situ. Ex-situ measurements of modulus, hardness, surface potential, digital image correlation strain field, and neutron diffraction were made as a function of fatigue cycles. It is hypothesized that varying levels of induced stress along the length due to equal-force but varying area along the length will create a record of damage which can be probed to intuit a temporal history for the specimen. Baseline, intermediate, and failure sensor measurements for several specimens were compared and analyzed as a function of applied stress (varied linearly along the length) and fatigue cycles (constant). Mechanisms of damage nucleation and propagation due to fatigue cycling are discussed with an emphasis on which inspection methods are most promising for improving structural durability and state monitoring.

Published

2018

44. Damage Precursor Indicator for Aluminum 7075-T6 Based on Nonlinear Dynamics

Author

Volker Weiss, Todd C. Henry, Ed Habtour, Antonios Kontsos, Robert A. Haynes, Brian Wisner, and Daniel P. Cole

Subjects

Vibration, Nonlinear system, Materials science, Deflection (engineering), Micromechanics, Natural frequency, sense organs, Structural health monitoring, Shaker, Composite material, Nanoindentation

Abstract

In this work, a damage precursor indicator for aluminum 7075-T6 is proposed based on the nonlinear dynamics of a cantilevered beam system. A shouldered beam specimen is used to move the region of highest stress away from the clamped end. The beam is subject to harmonic base excitation in a uniaxial shaker. Fatigue damage accumulates in the beam with damage forming most quickly in the region of highest stress. By monitoring the tip deflection, changes in the natural frequency and response to a given excitation are correlated to fatigue life. Despite the absence of large-scale cracks, detectable changes in the nonlinear dynamics are discovered. The nonlinear dynamic parameters are estimated capturing the change in the forward and backward nonlinear sine sweeps. These changes could lend themselves to being a trackable damage precursor. The presence of microstructural precursors are confirmed using nanoindentation.

Published

2018

45. Ultrahigh Carbon Nanotube Volume Fraction Effects on Micromechanical Quasi-Static & Dynamic Properties of Poly(Urethane-Urea) Filled Nanocomposites

Author

Daniel P. Cole, Brian L. Wardle, Robert H. Lambeth, Asha Hall, Hugh A. Bruck, Jeffrey L. Gair, Mark L. Bundy, Alex J. Hsieh, Dale L. Lidston, Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Lidston, Dale Leigh, and Wardle, Brian L

Subjects

chemistry.chemical_classification, Materials science, Nanocomposite, Polymer nanocomposite, Modulus, Polymer, Carbon nanotube, Dynamic mechanical analysis, law.invention, chemistry, law, Volume fraction, Composite material, Elastic modulus

Abstract

Poly(urethane-urea) (PUU) has been infused into ultrahigh volume fraction carbon nanotube (CNT) forests using a heat-curable polymer formula. Polymer nanocomposites with carbon nanotube volume-fractions of 1%, 5%, 10%, 20%, and 30% were fabricated by overcoming densification and infusion obstacles. These polymer nanocomposites were nanoindented quasi-statically and dynamically to discern process-structure-(mechanical) property relations of polymerizing PUU in such densely-packed CNT forests. A 100× increase in indentation modulus has been observed, which is attributed not only to CNT reinforcement of the matrix, but also to molecular interactions in the matrix itself. Quasi-static elastic moduli ranging from 10 MPa–4.5 GPa have been recorded. Storage modulus for all materials is found to track well at loadings of 200 Hz, with little effect observed from increasing CNT volume fraction. Keywords: carbon nanotubes; polymer nanocomposites; polyurethane urea; self-assembly, United States. Army Research Office (Contract W911NF-13-D-0001)

Published

2018

46. Formation of Nanofibers from Pure and Mixed Waste Streams Using Electrospinning

Author

Daniel Sweetser, Nicole E. Zander, Margaret Gillan, and Daniel P. Cole

Subjects

chemistry.chemical_classification, Materials science, General Chemical Engineering, Microfiltration, General Chemistry, Polymer, Industrial and Manufacturing Engineering, Electrospinning, law.invention, chemistry.chemical_compound, chemistry, law, visual_art, Nanofiber, Polymer chemistry, visual_art.visual_art_medium, Polyethylene terephthalate, Mixed waste, Polycarbonate, Composite material, Filtration

Abstract

New methods are needed to reprocess the excess of plastics in the waste stream. In this work, bottle-grade polyethylene terephthalate (PET), Styrofoam, and polycarbonate from compact discs (CDs) were spun into nanofibers as fine as ca. 100 nm in diameter using the electrospinning technique. The mechanical properties of the fibers were evaluated using microtensile testing. The elastic moduli ranged from 15 to 60 MPa, and displayed stiffnesses comparable or greater than fibers made from commercial polymers of equivalent molecular weight. Nanofibers were also prepared from blends of Styrofoam and recycled polycarbonate. Recycled PET fibers were tested for application in water filtration and had greater than 99% filtration efficiency of 1 μm particles. Nanofibers from both pure and mixed waste streams are expected to have applications in myriad areas such as ultra/microfiltration, composites, and tissue engineering.

Published

2015

47. Chemical Vapor Deposition of Monolayer Rhenium Disulfide (ReS2)

Author

Chandra Sekhar Tiwary, Bo Li, Yongji Gong, Douglas S. Galvao, Antony George, Amelia H. C. Hart, Kunttal Keyshar, Robert Vajtai, Gustavo Brunetto, Gonglan Ye, Pulickel M. Ajayan, Yongmin He, Ken Hackenberg, Daniel P. Cole, Leonardo D. Machado, Mohamad Kabbani, and Wu Zhou

Subjects

Materials science, business.industry, Mechanical Engineering, Transistor, Inorganic chemistry, technology, industry, and agriculture, chemistry.chemical_element, Chemical vapor deposition, Rhenium, equipment and supplies, law.invention, Characterization (materials science), Semiconductor, chemistry, Mechanics of Materials, law, Microscopy, Monolayer, General Materials Science, Spectroscopy, business

Abstract

The direct synthesis of monolayer and multilayer ReS2 by chemical vapor deposition at a low temperature of 450 °C is reported. Detailed characterization of this material is performed using various spectroscopy and microscopy methods. Furthermore initial field-effect transistor characteristics are evaluated, which highlight the potential in being used as an n-type semiconductor.

Published

2015

48. Gold Nanocluster DNase 1 Hybrid Materials: An Efficient Method for DNA Contamination Sensing

Author

Daniel P. Cole, Abby L. West, Shashi P. Karna, and Mark H. Griep

Subjects

Detection limit, Materials science, Mechanical Engineering, Cellular imaging, Nanotechnology, Biocompatible material, Fluorescence, chemistry.chemical_compound, chemistry, DNA Contamination, Biophysics, Molecule, Electrical and Electronic Engineering, Hybrid material, DNA

Abstract

Protein-encapsulated gold nanocluster (P-AuNC) synthesis was first demonstrated in 2009 [1]. Initially, these P-AuNCs were used as cellular imaging agents as the protein shell surrounding the AuNC made them highly biocompatible. However, recent studies have begun to show that these stabilizing proteins may also retain native biological function, thus giving a dual functionality to these hybrid molecules. Here, we present the synthesis of DNase 1 stabilized AuNCs (DNase 1:AuNCs) with core sizes consisting of either eight or 25 atoms. The DNase 1:Au8NCs exhibit blue fluorescence, whereas the DNase 1:Au25NCs are red emitting. Moreover, in addition to the intense fluorescence emission, the synthesized DNase 1:AuNC hybrids retain the native functionality of the protein, allowing simultaneous detection and digestion of DNA with a detection limit of 2 mg/mL (Figure 1). The DNase 1:AuNCs could be conveniently employed as efficient and fast sensors to augment the current inefficient and time-consuming DNA contamination analysis techniques.

Published

2015

49. Interphase Mechanics in Fatigued Carbon Fiber Composite Materials

Author

Todd C. Henry, Robert A. Haynes, Daniel P. Cole, and Frank Gardea

Subjects

Materials science, Tension (physics), Composite number, medicine, Stiffness, Interphase, Fiber, Bending, Mechanics, medicine.symptom, Composite material, Anisotropy, Reinforcement

Abstract

Carbon fiber composites display considerable heterogeneity in strength and stiffness depending on the respective constituent properties, reinforcement alignments, and interfacial relationships. Typically the inherent material anisotropy and complexity lead to relatively diverse material fatigue failures depending on the loading conditions and carbon fiber reinforcement orientations. The current work seeks to better understand the mechanisms by which fatigue damage precipitates and the smallest scales (sub-micron) at which material phenomena may be observed and tracked before becoming observable on the millimeter scale or larger. Unidirectional IM7-8552 composite samples were fabricated for transverse (90°) and longitudinal (0°) fiber loading. Samples were tested in bending using a three-point set-up and in single axis tension developing the cyclic life response at several loading stresses. Baseline and failed samples were partitioned and polished for instrumented indentation and atomic force microscopy (AFM) which probed the local mechanical and morphological behavior of the composite interphase. Attempts are made to characterize the local material behavior around the fiber-matrix interphase to understand material response of this region with respect to fatigue cycling. The fiber-matrix interphase results are compared to numerical modelling in order to better understand the interphase behavior and fatigue degradation of the composite materials.

Published

2017

50. Strain Energy Dissipation Mechanisms in Carbon Nanotube Composites Fabricated by Additive Manufacturing

Author

Jaret C. Riddick, Frank Gardea, Daniel P. Cole, and Bryan Glaz

Subjects

Carbon nanotube metal matrix composites, Nanocomposite, Materials science, Fused deposition modeling, Crazing, law, Carbon nanotube, Dynamic mechanical analysis, Molding (process), Dissipation, Composite material, law.invention

Abstract

Carbon nanotube (CNT) reinforced acrylonitrile-butadiene-styrene (ABS) composites fabricated using a fused deposition modeling approach were characterized for mechanical strain energy storage and dissipation capabilities. Dynamic mechanical analysis (DMA) was performed to quantify loss factor as a function of applied dynamic strain. In addition, DMA was performed at varying temperatures to give insight into the molecular interactions present in these composites. Insight into the microstructure was provided by atomic force microscopy (AFM). The results are compared to neat ABS and ABS/CNT systems processed through an injection molding technique. Results show large energy dissipation, accompanied by permanent damage, in both injection molded and additively manufactured neat ABS samples. In contrast, the additively manufactured ABS/CNT nanocomposites exhibited strain energy dissipation but reduced the effect of cavitation and crazing by possible reinforcement. This result suggests CNT fillers have the potential to alter the dissipation mechanisms present in additively manufactured structures to control structural damping. This research provides insight into the design and additive manufacturing of materials where energy dissipation is essential to maintain structural stability and functionality under dynamic loading.

Published

2017