Design, fabrication and characterization of an arrayable all-polymer microfluidic valve employing highly magnetic rare-earth composite polymer

Rahbar, Mona; Shannon, Lesley; Gray, Bonnie L.

doi:10.1088/0960-1317/26/5/055012

Cited by 22 publications

(15 citation statements)

References 46 publications

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“…The special 4 f and 5 d electron orbital brought about the rich electronic gap, the big ionic radius, the strong complexation and the strong coordination ability to rare earth elements, resulting in the diversified chemical and crystal structures of rare earth compounds . Rare earth compounds could catalyze the dehydrogenation, oxidation, crosslinking, carbonization, and other reactions during the thermal decomposition/combustion of polymer, and then influence the thermal stability and flame retardancy of polymers . In order to explore how to improve the flame retardant efficiency of traditional flame retardant, rare earth compounds have emerged in fire safety fields gradually.…”

Section: Introductionmentioning

confidence: 99%

Synergistic flame retardant mechanism of lanthanum phenylphosphonate and decabromodiphenyl oxide in polycarbonate

Ran

Cai³

et al. 2018

Polymer Composites

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Lanthanum phenylphosphonate (LaHPP) was synthesized through solution reflux method with a hydrothermal reaction. The synergistic effect of decabromodiphenyl oxide (DBDPO) and LaHPP on thermal stability and flame retardancy of polycarbonate (PC) were investigated. Transmission electron microscope graphs showed that LaHPP dispersed well in the PC matrix. Thermogravimetric analyses indicated that the addition of LaHPP into PC/DBDPO composites led to better thermal stability. An appropriate content (1 wt%) of LaHPP could improve the UL94 rating (from V-2 to V-0) and limiting oxygen index value (from 32.8 to 40.5%) dramatically, and also brought an effective reduction in peak heat release rate and smoke release rate in cone calorimeter. Investigation of gaseous pyrolysis products and char residues demonstrated that LaHPP promoted the formation of more compact and solid chars, which acted as physical barriers to inhibit heat and oxygen transfer. The inside char layers also provided more space and time for DBDPO to play its flame retardant role in gaseous phases. POLYM.

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Section: Introductionmentioning

confidence: 99%

Synergistic flame retardant mechanism of lanthanum phenylphosphonate and decabromodiphenyl oxide in polycarbonate

Ran

Cai³

et al. 2018

Polymer Composites

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“…As a key component in flow control, valves have been intensively studied, and many different types have been developed, such as pneumatic valves4, phase-change valves5 and burst valves6. Ice valves are of particular interest since they do not require specific on-device architectures and do not leave residues that may influence on-device analytics78.…”

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confidence: 99%

High response speed microfluidic ice valves with enhanced thermal conductivity and a movable refrigeration source

Cao

et al. 2017

Sci Rep

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Due to their ease of fabrication, facile use and low cost, ice valves have great potential for use in microfluidic platforms. For this to be possible, a rapid response speed is key and hence there is still much scope for improvement in current ice valve technology. Therefore, in this study, an ice valve with enhanced thermal conductivity and a movable refrigeration source has been developed. An embedded aluminium cylinder is used to dramatically enhance the heat conduction performance of the microfluidic platform and a movable thermoelectric unit eliminates the thermal inertia, resulting in a faster cooling process. The proposed ice valve achieves very short closing times (0.37 s at 10 μL/min) and also operates at high flow rates (1150 μL/min). Furthermore, the response time of the valve decreased by a factor of 8 when compared to current state of the art technology.

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“…This combination of valving using SAP materials and hydrophobic surface functionalization adds to the set of options in design of passive microfluidic platforms for sweat collection and analysis. By comparison to previous schemes, such as those based on pneumatic, magnetic valves, a key advantage is in operation without external supply of power.…”

Section: Resultsmentioning

confidence: 99%

Super‐Absorbent Polymer Valves and Colorimetric Chemistries for Time‐Sequenced Discrete Sampling and Chloride Analysis of Sweat via Skin‐Mounted Soft Microfluidics

Kim

Zhang

Won

et al. 2018

Small

135

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This paper introduces super absorbent polymer valves and colorimetric sensing reagents as enabling components of soft, skin-mounted microfluidic devices designed to capture, store, and chemically analyze sweat released from eccrine glands. The valving technology enables robust means for guiding the flow of sweat from an inlet location into a collection of isolated reservoirs, in a well-defined sequence. Analysis in these reservoirs involves a color responsive indicator of chloride concentration with a formulation tailored to offer stable operation with sensitivity optimized for the relevant physiological range. Evaluations on human subjects with comparisons against ex situ analysis illustrate the practical utility of these advances.

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Design, fabrication and characterization of an arrayable all-polymer microfluidic valve employing highly magnetic rare-earth composite polymer

Cited by 22 publications

References 46 publications

Synergistic flame retardant mechanism of lanthanum phenylphosphonate and decabromodiphenyl oxide in polycarbonate

Synergistic flame retardant mechanism of lanthanum phenylphosphonate and decabromodiphenyl oxide in polycarbonate

High response speed microfluidic ice valves with enhanced thermal conductivity and a movable refrigeration source

Super‐Absorbent Polymer Valves and Colorimetric Chemistries for Time‐Sequenced Discrete Sampling and Chloride Analysis of Sweat via Skin‐Mounted Soft Microfluidics

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