Education

Research Description

Dr. Pankow's long-term goal is to contribute to the advancement of our understanding of high impact bio-mechanics with an emphasis on the mechanical effects on the skull-brain system. Dr. Pankow is presently studying the underlying failure mechanisms in blast loading on composite materials. This study is being performed experimentally and is drawing its data largely from high-speed image capture of blast samples. The results can be applied to blast resistant structures (aircraft, buildings, etc). He is also currently studying blast structure-human interaction. This study examines the effects of shock-wave loading on skull-brain systems that vary in their mechanical properties. This research is aimed at applications that reduce the risks of traumatic brain injury.

Publications

A generalized analytical model for predicting the tensile behavior of 3D orthogonal woven composites using finite deformation approach

Midani, Mohamad and Seyam, Abdel-Fattah and Pankow, Mark (2018), JOURNAL OF THE TEXTILE INSTITUTE, 109(11), 1465-1476.

Composition and structure of porcine digital flexor tendon-bone insertion tissues

Chandrasekaran, S. and Pankow, M. and Peters, K. and Huang, H. Y. S. (2017), Journal of Biomedical Materials Research. Part A, 105(11), 3050-3058.

Dynamic polarization microscopy for in-situ measurements of collagen fiber realignment during impact

Wu, X. Y. and Huang, H. Y. S. and Pankow, M. and Peters, K. (2017), Conference Proceedings of the Society for Experimental Mechanics Series, (), 61-66.

Exploring how optimal composite design is influenced by model fidelity and multiple objectives

Joglekar, S. and Von Hagel, K. and Pankow, M. and Ferguson, S. (2017), Composite Structures, 160(), 964-975.

High-speed 3D digital image correlation of low-velocity impacts on composite plates

Flores, M. and Mollenhauer, D. and Runatunga, V. and Beberniss, T. and Rapking, D. and Pankow, M. (2017), Composites. Part B, Engineering, 131(), 153-164.

Interaction of delaminations and matrix cracks in a CFRP plate, Part I: A test method for model validation

McElroy, M. and Jackson, W. and Olsson, R. and Hellstrom, P. and Tsampas, S. and Pankow, M. (2017), Composites. Part A, Applied Science and Manufacturing, 103(), 314-326.

Interaction of delaminations and matrix cracks in a CFRP plate, Part II: Simulation using an enriched shell finite element model

McElroy, M. W. and Gutkin, R. and Pankow, M. (2017), Composites. Part A, Applied Science and Manufacturing, 103(), 252-262.

Interrogation of a spectral profile division multiplexed FBG sensor network using a modified particle swarm optimization method

Guo, G. D. and Hackney, D. and Pankow, M. and Peters, K. (2017), Measurement Science & Technology, 28(5), .

Modeling of 3D woven composites using the digital element approach for accurate prediction of kinking under compressive loads

Joglekar, S. and Pankow, M. (2017), Composite Structures, 160(), 547-559.

A spectral profile multiplexed FBG sensor network with application to strain measurement in a Kevlar woven fabric

Guo, G. D. and Hackney, D. and Pankow, M. and Peters, K. (2017), Proceedings of SPIE-the International Society for Optical Engineering, 10168(), .

Dynamic failure mechanisms in woven ceramic fabric reinforced metal matrix composites during ballistic impact

McWilliams, B. A. and Yu, J. H. and Pankow, M. (2016), Conference Proceedings of the Society for Experimental Mechanics Series, (), 155-159.

Point of impact: the effect of size and speed on puncture mechanics

Anderson, P. S. L. and LaCosse, J. and Pankow, M. (2016), Interface Focus, 6(3), .

Simulation of high rate failure mechanisms in composites during quasi-static testing

Pankow, M. and McWilliams, B. A. (2016), Conference Proceedings of the Society for Experimental Mechanics Series, (), 445-450.

Split Hopkinson bar measurement using high-speed full-spectrum fiber Bragg grating interrogation

Seng, F. and Hackney, D. and Goode, T. and Shumway, L. and Hammond, A. and Shoemaker, G. and Pankow, M. and Peters, K. and Schultz, S. (2016), Applied Optics, 55(25), 7179-7185.

Ballistic impact behavior of woven ceramic fabric reinforced metal matrix composites

McWilliams, B. and Yu, J. and Pankow, M. and Yen, C. F. (2015), International Journal of Impact Engineering, 86(), 57-66.

Characterization of delamination in translaminar reinforced composites due to low velocity impact

Ranatunga, V. and Joglekar, S. and Pankow, M. and Clay, S. (2015), Proceedings of the American Society for Composites: Thirtieth Technical Conference, (), 381-392.

High-speed 3D digital image correlation of low-velocity impacts on composite plates

Flores, M. D. and Mollenhauer, D. and Runatunga, V. and Berbeniss, T. and Rapking, D. and Pankow, M. (2015), Proceedings of the American Society for Composites: Thirtieth Technical Conference, (), 2120-2135.

Modeling of 3D woven composites with realistic geometry for accurate prediction of kinking under compressive loads

Joglekar, S. and Pankow, M. (2015), Proceedings of the American Society for Composites: Thirtieth Technical Conference, (), 593-612.

Student simulation challenge: A competition-based composites education opportunity

Pochiraju, K. and Iarve, E. and Haque, B. and Pankow, M. (2015), Proceedings of the American Society for Composites: Thirtieth Technical Conference, (), 1160-1170.

Top down design using Bayesian network classifiers for composite panels

Von Hagel, K. and Joglekar, S. and Ferguson, S. and Pankow, M. (2015), Proceedings of the American Society for Composites: Thirtieth Technical Conference, (), 468-475.

Hybrid three-dimensional (3-D) woven thick composite architectures in bending

Pankow, M. and Quabili, A. and Yen, C. F. (2014), JOM: the Journal of the Minerals, Metals & Materials Society, 66(2), 255-260.

Comparison of 2D and 3D composites to confined crush loading

Pankow, M. and Yen, C. F. and Waas, A. M. (2013), Proceedings of the American Society for Composites, (), .

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Grants

Dynamic Characterization of Nonwoven Properties - NWI Core Project

NCSU Nonwovens Institute(8/15/18 - 8/14/19)

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Dynamic Characterization of Nonwoven Properties - NWI Core Project

Sponsor: NCSU Nonwovens Institute

Start Date: 8/15/18

End Date: 8/14/19

Abstract

This work is investigating non woven materials under dynamic loading conditions

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MRI: Acquisition of a Nano-Computed Tomography System for Nondestructive 3D Microstructural Imaging

National Science Foundation (NSF)(8/01/18 - 7/31/19)

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MRI: Acquisition of a Nano-Computed Tomography System for Nondestructive 3D Microstructural Imaging

Sponsor: National Science Foundation (NSF)

Start Date: 8/01/18

End Date: 7/31/19

Abstract

We propose to acquire a high-resolution nano-computed tomography (nano-CT) system capable of nondestructive 3D imaging of microstructural features in a wide range of materials. The nano-CT system will produce images with spectacular volumetric detail and enable the evaluation of intricate and often hidden structures in many materials (e.g., bone, vasculature, orthopaedic implants, metals foams and meshes, composites, etc.), providing critical information like porosity, connectivity, and permeability. Existing CT systems in the region provide volumetric images but lack the resolution to capture important sub-micron microstructural features. Other tools that have sufficient resolution, such as scanning electron, atomic force, and transmission electron microscopes, require tedious sample preparation, have very limited field of view, and cannot characterize internal features nondestructively. The proposed nano-CT system will fill this critical gap, and it will be made broadly available to NC State, regional, and national users by locating it within the Analytical Instrumentation Facility, a leading, open-access materials characterization facility. In addition to specific AIF workshops and K-12 outreach programs we have planned, this instrument and image analysis associated with it may be used in many undergraduate and graduate courses within six different engineering and textiles departments.

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Lightweight Strain-Energy Deployed Spacecraft Booms

National Aeronautics & Space Administration (NASA)(6/15/18 - 6/14/19)

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Lightweight Strain-Energy Deployed Spacecraft Booms

Sponsor: National Aeronautics & Space Administration (NASA)

Start Date: 6/15/18

End Date: 6/14/19

Abstract

This proposal will provide NCSU with a flight opportunity for testing of deployable structures.

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Physics-Based Models for Manufacturing of Advanced Materials

US Army - Army Research Laboratory(10/01/17 - 3/01/19)

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Physics-Based Models for Manufacturing of Advanced Materials

Sponsor: US Army - Army Research Laboratory

Start Date: 10/01/17

End Date: 3/01/19

Abstract

Dynamic Characterization of 3D printed metal parts

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TSA Testing of UHMWPE for Chesapeake

Chesapeake Testing (6/01/17 - 10/11/17)

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TSA Testing of UHMWPE for Chesapeake

Sponsor: Chesapeake Testing

Start Date: 6/01/17

End Date: 10/11/17

Abstract

Testing of UHMWPE samples for material characterization

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Multi-Lens Array, PEC Enhancement Project

Oculus(3/01/17 - 12/31/18)

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Multi-Lens Array, PEC Enhancement Project

Sponsor: Oculus

Start Date: 3/01/17

End Date: 12/31/18

Abstract

The purpose of this work is study concepts needed to rapidly create molds for multi-lens arrays of small plastic optics. This project will build on previous work in the PEC sponsored by PEC Affiliates and NSF that led to a NCSU/PEC patent on Nano-coining of sub wave-length plastic features. Because the size of the features for this proposal are 100x larger than in the previous work, the concepts will need to be refined to achieve the larger size. In addition, the details of the shape of the individual lenses may need to be modified to create the desired geometry in the replicated lenses.

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Spectral Profile Multiplexing of FBG Sensors to Enable Low-Power Optical Sensor Networks

National Science Foundation (NSF)(9/01/15 - 8/31/19)

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Spectral Profile Multiplexing of FBG Sensors to Enable Low-Power Optical Sensor Networks

Sponsor: National Science Foundation (NSF)

Start Date: 9/01/15

End Date: 8/31/19

Abstract

We propose to derive and implement a novel multiplexing strategy for large FBG sensor networks that would enable the interrogation of these networks with low-power, low-bandwidth sources. The ultimate goal is to permit the integration of FBG sensor networks into wireless communication systems. The multiplexing strategy is based on identifying the unique spectral profile of each sensor through a rapid, cross-correlation algorithm. The cross-correlation algorithm will be supplemented with penalty functions based on prior information to reduce identification errors. The multiplexing strategy will be demonstrated on two applications: crash testing of automotive composites and lightening strike identification.

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High Repetition-Rate Shape Sensing Using Fiber Bragg Gratings (HISS)

US Dept. of Defense (DOD)(9/09/15 - 12/08/18)

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High Repetition-Rate Shape Sensing Using Fiber Bragg Gratings (HISS)

Sponsor: US Dept. of Defense (DOD)

Start Date: 9/09/15

End Date: 12/08/18

Abstract

The objective of the proposed effort is to develop a technology that will enable high repetition-rate shape sensing in a wide range of settings and can be integrated into the protective materials. The focus of this technology development is to improve the measurement of dynamic back face deformation (BFD) of body armor at a high repetition-rate. This will overcome two deficiencies in existing body armor testing and evaluation. First of all, the measurement system can be embedded into the material that simulates the body and does not require an exposed view of the backing material under test. Furthermore, it enables dynamic measurement of the BFD, not just post impact analysis of the deformed backing material. This allows researchers to perform a more realistic potential blunt force trauma analysis.

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REU Site: Summer Internships in Composites for Extreme Performance

National Science Foundation (NSF)(2/01/15 - 1/31/19)

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REU Site: Summer Internships in Composites for Extreme Performance

Sponsor: National Science Foundation (NSF)

Start Date: 2/01/15

End Date: 1/31/19

Abstract

Advanced composite materials are revolutionizing the fields of transportation (including the aerospace, naval, automotive, and rail industries), alternative energy generation and infrastructures. In this REU Site, the student interns will be paired with individual research mentors and will spend the majority of their experience working in the laboratory. In addition, the interns will attend weekly interactive research training seminars with their cohort and will participate in two site visits to advanced composite industries in North Carolina. As part of their research experience the interns will prepare and present a poster at the Undergraduate Research Symposium at NCSU. To incentivize the poster quality, the top three posters will be selected from the cohort and the winners will be funded by the REU site program to present their research at the SAMPE meeting in the following spring.

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Collaborative Research: Center for Integration of Composites into Infrastructure (CICI)

National Science Foundation (NSF)(11/01/14 - 10/31/19)

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Collaborative Research: Center for Integration of Composites into Infrastructure (CICI)

Sponsor: National Science Foundation (NSF)

Start Date: 11/01/14

End Date: 10/31/19

Abstract

The proposed project has an information technology (IT) component that will be coordinated with CICI university partners (UM and NCSU). The following sections highlight the nature of the project’s data generation, storage, retention, and sharing components as per NCSU. Expected data This research is expected generate datasets similar to those produced by a typical materials/structures laboratory. The types of data include: 􀁸 Experimental measurements from voltage or current measurement devices. These measurements will be converted to useful units through calibration scales. Data will be collected by instruments and sensors such as: strain gauges, load cells, linear variable differential transformers (LVDTs), and displacement transducers. 􀁸 Quantitative information in the form of human or machine readouts from measurement devices such as rulers, meter tapes, volume measurement containers, scales, and environmental gauges. 􀁸 Qualitative information such as experimental behavior, test conditions, or other significant observations. 􀁸 Multimedia data such as photographs, videos, screen captures, audio/video logs captured by cameras, camcorders, or audio recorders, or other multimedia devices. 􀁸 Written documents such as progress logs, journal articles, periodic reports, presentations, or any other document detailing progress, results, or outcomes. Data will be collected for the entire duration of this project. In particular, data is expected to be collected during testing preparation, equipment calibration, testing, personnel training, and demonstrations. Data related to the dissemination of information such as written documents or multimedia data, as it relates to publication or sharing of results, creation of manuscripts for archival publication, presentations, and reports, is expected to be generated following significant milestones in the project, and can be expected on a monthly or longer frequency. The project will result in the creation of a software framework for data management, sharing, analysis, and visualization. The code will be managed by graduate students and will be supervised by the PI. The majority of the code will be uploaded to a code repository such as GITHUB, where the code will be made open source under a GNU license.

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