Army Officer Corps Science, Technology, Engineering and Mathematics (STEM) Foundation Gaps Place Countering Weapons of Mass Destruction (CWMD) Operations at Risk – Part 1

This is the first of three articles from the authors describing the risk to Joint Operations incurred by an Army that is vulnerable to the STEM challenges faced in a great power competition involving CWMD operations. In this article, we describe the problem. In articles two and three of the series, we will elaborate on the problem utilizing the Joint Publication 3-0 as our guide and recommend solutions to address this gap

Impact response of advance combat helmet pad systems

Combat helmets are designed to protect against ballistic threats and fragments of explosive devices. There are numerous types of helmet comfort foams available. However, pad systems have not been evaluated in combat helmets to understand to what extent they mitigate head accelerations. In this work, different pad systems are studied to analyze the ballistic performance of combat helmets using a Hybrid III dummy equipped with longitudinal accelerometers at the head and a neck simulator. The tests are conducted with 9 mm Full Metal Jacket (FMJ) projectiles according to the performance requirements III-A of the NIJ 0106.01 standard. This experimental methodology allows the evaluation of brain and neck injuries. The thicker bicomponent polyurethane foams and the honeycomb configuration provided the best results in terms of mitigating brain damage due to accelerations applying different criteria (PLA, WSTC, HIC). However, it was concluded that there is no cervical injury or cranial fracture risk for any of the cases studied.The authors acknowledge the Ministry of Economy and Competitiveness of Spain and the FEDER program under Projects DPI2017-88166-R and PID2020-118946RB-I00 for the financial support of the work. M. Rodriguez-Millan acknowledges the Spanish Ministry of Universities, the National Program for the Promotion of Talent, and its Employability in Research and Development and Innovation (R&D&I), National Mobility Subprogram of the National Plan for Scientific and Technical Research and Innovation 2021–2023, for the professor’s mobility program (PRX21/00329). It has to thank the funding for APC: Universidad Carlos III de Madrid (Read and Publish Agreement CRUECSIC 2023).Publicad

Experimental and numerical analyses of ballistic resistance evaluation of combat helmet using Hybrid III headform

Combat helmets are the primary system for protecting the head against ballistic impacts. Generally, combat helmets have been evaluated using a ballistic plasticine head surrogate based on international standards. More realistic human head models have recently been introduced to assess combat helmet performance considering biomechanical requirements. In this work, the Hybrid III dummy head and neck has been introduced to evaluate the performance of the combat helmet against the ballistic impact of live ammunition at different impact locations, considering two different thicknesses of the padding system. A numerical model including a helmet and a Hybrid III head and neck, is developed and validated with our experimental data. The results reveal the influence of the location, where the rear impact leads to the highest risk of brain damage. The effect of pad thickness is closely related to the energy absorbed by the helmet, the backface deformation (BFD), the contact force and the acceleration measured on the head.The authors acknowledge the Ministry of Economy and Competitiveness of Spain and FEDER program under Project RTC-2015-3887-8 and Project DPI2017-88166-R for the financial support of the work. M Rodriguez-Millan acknowledges the Spanish Ministry of Universities, National Program for the Promotion of Talent and its Employability in R&D&I, National Mobility Subprogram of the National Plan for Scientific and Technical Research and Innovation 2021-2023, for the professor's mobility program (PRX21/00329)

Inkjet-Printed Carbon Nanotubes for Fabricating a Spoof Fingerprint on Paper.

A spoof fingerprint was fabricated on paper and applied for a spoofing attack to unlock a smartphone on which a capacitive array of sensors had been embedded with a fingerprint recognition algorithm. Using an inkjet printer with an ink made of carbon nanotubes (CNTs), we printed a spoof fingerprint having an electrical and geometric pattern of ridges and furrows comparable to that of the real fingerprint. With this printed spoof fingerprint, we were able to unlock a smartphone successfully; this was due to the good quality of the printed CNT material, which provided electrical conductivities and structural patterns similar to those of the real fingerprint. This result confirms that inkjet-printing CNTs to fabricate a spoof fingerprint on paper is an easy, simple spoofing route from the real fingerprint and suggests a new method for outputting the physical ridges and furrows on a two-dimensional plane

Salt-Templated Platinum-Copper Porous Macrobeams for Ethanol Oxidation

Platinum nanomaterials provide an excellent catalytic activity for diverse applications and given its high cost, platinum alloys and bi-metallic nanomaterials with transition metals are appealing for low cost and catalytic specificity. Here the synthesis of hierarchically porous Pt–Cu macrobeams and macrotubes templated from Magnus’s salt derivative needles is demonstrated. The metal composition was controlled through the combination of [PtCl4]2− with [Pt(NH3)4]2+ and [Cu(NH3)4]2+ ions in different ratios to form salt needle templates. Polycrystalline Pt–Cu porous macrotubes and macrobeams 10’ s–100’ s μm long with square cross-sections were formed through chemical reduction with dimethylamine borane (DMAB) and NaBH4, respectively. Specific capacitance as high as 20.7 F/g was demonstrated with cyclic voltammetry. For macrotubes and macrobeams synthesized from Pt2−:Pt2+:Cu2+ salt ratios of 1:1:0, 2:1:1, 3:1:2, and 1:0:1, DMAB reduced 3:1:2 macrotubes demonstrated the highest ethanol oxidation peak currents of 12.0 A/g at 0.5 mV/s and is attributed to the combination of a highly porous structure and platinum enriched surface. Salt templates with electrochemical reduction are suggested as a rapid, scalable, and tunable platform to achieve a wide range of 3-dimensional porous metal, alloy, and multi-metallic nanomaterials for catalysis, sensor, and energy storage applications

case study

A critical review of PCR primer design algorithms and crosshybridizatio

3D virus scaffolds for energy storage and microdevice applications

Thesis (Sc. D.)--Massachusetts Institute of Technology, Dept. of Biological Engineering, February 2012.Cataloged from PDF version of thesis.Includes bibliographical references.With constantly increasing demand for lightweight power sources, electrode architectures that eliminate the need for conductive and organic additives will increase mass specific energy and power densities. The increased demand for lightweight power is coupled with increasing device miniaturization. As the scale of devices decreases, current battery technologies add mass on the same scale as the device itself. A dual functional electro-mechanical material that serves as both the device structural material and the power source would dramatically improve device integration and range for powered movement. To address the demand for lightweight power with the objective of a dual functional electro-mechanical material, the M 13 bacteriophage was used to create novel 3-dimensional nano-architectures. To synthesize 3-dimensional nanowire scaffolds, the M13 virus is covalently linked into a hydrogel that serves as a 3-dimensional bio-template for the mineralization of copper and nickel nanowires. Control of nanowire diameter, scaffold porosity, and film thickness is demonstrated. The nanowire scaffolds are found to be highly conductive and can be synthesized as free-standing films. To demonstrate the viability of the 3-dimensional nanowire networks for electrical energy storage, copper nanowires were galvanically displaced to a mixed phase copper-tin system. These tin based anodes were used for lithium rechargeable batteries and demonstrated a high storage capacity per square area and stable cycling approaching 100 cycles. To determine the viability of the 3-dimensional nanowire networks as dual functional electro-mechanical materials and the mechanical stability of processing intermediates, phage hydrogels, aerogels, and metal nanowire networks were examined with nano-indentation. The elastic moduli of the metal networks are in the range of open cell metal foams The demonstration of 3-dimensional virus-templated metal nanowire networks as electrically conductive and mechanically robust should facilitate their implementation across a broad array of device applications to include photovoltaics, catalysis, electrochromics, and fuel cells.by F. John Burpo.Sc.D