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

Advanced Dual-Pull Mechanism for Deployable Spacecraft Booms

Firth, J. A., & Pankow, M. R. (2019), JOURNAL OF SPACECRAFT AND ROCKETS. https://doi.org/10.2514/1.A34243

High-Speed Interrogation Approach for FBG Sensors Using a VCSEL Array Swept Source

Guo, G., Pankow, M., & Peters, K. (2019), IEEE SENSORS JOURNAL, 19(21), 9766–9774. https://doi.org/10.1109/JSEN.2019.2927901

Soft body armor time-dependent back face deformation (BFD) with ballistics gel backing

Goode, T., Shoemaker, G., Schultz, S., Peters, K., & Pankow, M. (2019), COMPOSITE STRUCTURES, 220, 687–698. https://doi.org/10.1016/j.compstruct.2019.04.025

Strain state dependent anisotropic viscoelasticity of tendon-to-bone insertion

Kuznetsov, S., Pankow, M., Peters, K., & Huang, H.-Y. S. (2019), MATHEMATICAL BIOSCIENCES, 308, 1–7. https://doi.org/10.1016/j.mbs.2018.12.007

The effect of the through-thickness yarn component on the in- and out-of-plane properties of composites from 3D orthogonal woven preforms

Midani, M., Seyam, A.-F., Saleh, M. N., & Pankow, M. (2019), JOURNAL OF THE TEXTILE INSTITUTE, 110(3), 317–327. https://doi.org/10.1080/00405000.2018.1481722

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

Midani, M., Seyam, A.-F., & Pankow, M. (2018), JOURNAL OF THE TEXTILE INSTITUTE, 109(11), 1465–1476. https://doi.org/10.1080/00405000.2018.1425107

High-speed polarization imaging of dynamic collagen fiber realignment in tendon-to-bone insertion region

Wu, X., Pankow, M., Huang, H.-Y. S., & Peters, K. (2018), JOURNAL OF BIOMEDICAL OPTICS, 23(11). https://doi.org/10.1117/1.JBO.23.11.116002

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

Guo, G. D., Hackney, D., Pankow, M., & Peters, K. (2017), In Sensors and smart structures technologies for civil, mechanical, and aerospace systems 2017 (Vol. 10168). https://doi.org/10.1117/12.2260114

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

Chandrasekaran, S., Pankow, M., Peters, K., & Huang, H. Y. S. (2017), Journal of Biomedical Materials Research. Part A, 105(11), 3050–3058. https://doi.org/10.1002/jbm.a.36162

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

Wu, X. Y., Huang, H. Y. S., Pankow, M., & Peters, K. (2017), In Mechanics of biological systems and materials, vol 6 (pp. 61–66). https://doi.org/10.1007/978-3-319-41351-8_9

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Grants

Precision Path Motion for Dynamic Actuation, PEC Core Project 7

PE CONSORTIUM(10/01/19 - 12/31/20)

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Precision Path Motion for Dynamic Actuation, PEC Core Project 7

Sponsor: PE CONSORTIUM

Start Date: 10/01/19

End Date: 12/31/20

Abstract

Develop a platform for studying the motion control of a fast tool servo on an XYZ stage. Investigate the dynamics and control of the system as applied to a step and repeat indentation process.

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Microindentation, PEC Core Project 6

PE CONSORTIUM(7/01/19 - 12/31/20)

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Microindentation, PEC Core Project 6

Sponsor: PE CONSORTIUM

Start Date: 7/01/19

End Date: 12/31/20

Abstract

This project focuses on developing a process to deliver the best form and finish on a mold for making arrays of microscale lenses. The envisioned process will use plastic deformation to replicate lens-like features on a diamond die in the mold. The die will be made with a focused ion beam milling process.

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Develop Machining Processes to Produce Optimal Surface Finish in Pure Metals, PEC Core Project 8

PE CONSORTIUM(10/01/19 - 12/31/20)

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Develop Machining Processes to Produce Optimal Surface Finish in Pure Metals, PEC Core Project 8

Sponsor: PE CONSORTIUM

Start Date: 10/01/19

End Date: 12/31/20

Abstract

Investigate the cycle of chip seizure when turning pure aluminum with both carbide and diamond tools.

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Impact Protection Design Solutions Using AI/Neural Networks

Windpact(10/01/19 - 3/31/20)

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Impact Protection Design Solutions Using AI/Neural Networks

Sponsor: Windpact

Start Date: 10/01/19

End Date: 3/31/20

Abstract

The work will investigate the use of AI for the design and development of padding protection systems. We propose using AI for developing forward models and inverse mapping capabilities.

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In-Space Structure Assembly Concepts

National Institute of Aerospace(8/16/19 - 9/30/20)

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In-Space Structure Assembly Concepts

Sponsor: National Institute of Aerospace

Start Date: 8/16/19

End Date: 9/30/20

Abstract

This proposal will look at In-space structural assembly concepts. They will be investigated to determine how robust they are.

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Experimental Characterization of Textile Composites for Validation of Virtual Weaving

US Air Force (USAF)(5/20/19 - 8/02/21)

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Experimental Characterization of Textile Composites for Validation of Virtual Weaving

Sponsor: US Air Force (USAF)

Start Date: 5/20/19

End Date: 8/02/21

Abstract

Textile composites offer the ability to provide enhanced damage and durability protection for composite materials. The damage is inherently linked to the unique weaving signature’s imperfections and capturing this in a virtual manner will enable woven composites to be explored using an ICME framework through virtual building and testing. This work will build off of the digital element approach implemented through VTMS and developed by the U.S. Air Force Research Laboratory (AFRL). This multi-institution effort will help to develop the capabilities of the VTMS software along with providing a verification and validation of some of the damage initiation and growth analysis for complex textile composites. The results of this effort will help mature some of the methodologies and develop faster, more user friendly capabilities for researchers.

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Composite Origami for Spacecraft Solar Arrays and Deployable Structures

National Aeronautics & Space Administration (NASA)(10/10/19 - 10/09/20)

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Composite Origami for Spacecraft Solar Arrays and Deployable Structures

Sponsor: National Aeronautics & Space Administration (NASA)

Start Date: 10/10/19

End Date: 10/09/20

Abstract

Flight testing of Composite Origami for Solar Arrays

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Braided Thin-Ply Tapes

National Aeronautics & Space Administration (NASA)(8/19/19 - 9/18/20)

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Braided Thin-Ply Tapes

Sponsor: National Aeronautics & Space Administration (NASA)

Start Date: 8/19/19

End Date: 9/18/20

Abstract

Development of thin-ply composite braiding technologies, designs, test approaches, and analysis methods for space structural applications

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Dynamic Characterization of Nonwoven Properties - NWI Core Project

NCSU Nonwovens Institute(1/01/19 - 12/31/19)

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Dynamic Characterization of Nonwoven Properties - NWI Core Project

Sponsor: NCSU Nonwovens Institute

Start Date: 1/01/19

End Date: 12/31/19

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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