Richard D. Dombrowski scite author profile

Drop-based crystallization techniques are used to achieve a high degree of control over crystallization conditions in order to grow high-quality protein crystals for X-ray diffraction or to produce organic crystals with well-controlled size distributions. Simultaneous crystal growth and stochastic nucleation makes it difficult to predict the number and size of crystals that will be produced in a drop-based crystallization process. A mathematical model of crystallization in drops is developed using a Monte Carlo method. The model incorporates key phenomena in drop-based crystallization, including stochastic primary nucleation and growth rate dispersion (GRD) and can predict distributions of the number of crystals per drop and full crystal size distributions (CSD). Key dimensionless parameters are identified to quickly screen for crystallization conditions that are expected to yield a high fraction of drops containing one crystal and a narrow CSD. Using literature correlations for the solubilities, growth, and nucleation rates of lactose and lysozyme, the model is able to predict the experimentally observed crystallization behavior over a wide range of conditions. Model-based strategies for use in the design and optimization of a drop-based crystallization process for producing crystals of well-controlled CSD are identified.

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MMOD Puncture Resistance of EVA Suits with Shear Thickening Fluid (STF) – Armortm Absorber Layers

Cwalina

Dombrowski

McCutcheon

et al. 2015

Procedia Engineering

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Absorber layers comprised of shear thickening fluid (STF) intercalated Kevlar ® (STF-Armor TM ) are integrated within the standard extravehicular activity (EVA) suit and tested for efficacy against both needle puncture and hypervelocity impact (HVI) tests characteristic of micrometeoroids and orbital debris (MMOD). An improvement in puncture resistance against hypodermic needle threats is achieved by substituting STF-Armor TM in place of neoprene-coated nylon as the absorber layer in the standard EVA suit. The prototype lay-ups containing STF-Armor TM have the benefit of being 17% thinner and 13% lighter than the standard EVA suit and the ballistic limit is identified in HVI testing. The results here demonstrate that EVA suit lay-ups containing STF-Armor TM as absorber layers offer meaningful resistance to MMOD threats.

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Richard D. Dombrowski

Crystallization of alpha-lactose monohydrate in a drop-based microfluidic crystallizer

Engineering enhanced cut and puncture resistance into the thermal micrometeoroid garment (TMG) using shear thickening fluid (STF) – Armor™ absorber layers

Modeling the crystallization of proteins and small organic molecules in nanoliter drops

MMOD Puncture Resistance of EVA Suits with Shear Thickening Fluid (STF) – Armortm Absorber Layers

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