Stephanie Flynn scite author profile

Stephanie Flynn

3Publications

38Citation Statements Received

60Citation Statements Given

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Dalhousie University

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Exclusion of Salt Solutions from Activated Carbon Pores and the Relationship to Contact Angle on Graphite

et al. 2007

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The exclusion of salts from the pores of activated carbon granules is demonstrated for the first time for the salts K 2 CO 3 , K 2 HPO 4 and K 3 PO 4 . In soaking experiments, the concentrations of solutions of K 2 CO 3 , K 2 -HPO 4 , and K 3 PO 4 inside the pores are less than in the bulk solutions. This phenomenon is observed by measuring the bulk concentration, which increases upon addition of carbon. This suggests that these salts are repelled by the carbon surface. In incipient wetness experiments, the three aforementioned salts do not enter the carbon at concentrations greater than ∼1 M. The contact angles of these three salt solutions on highly oriented pyrolitic graphite and polished resin-impregnated graphite surfaces rise with concentration and approach 90°, which suggests that these solutions would not enter activated carbon pores. By contrast, soaking, incipient wetness, and contact angle measurements for salts like ZnCl 2 and Zn(CH 3 COO) 2 show preferential adsorption by soaking (the salt is depleted from the solution), high imbibing limits (maximum incipient wetness volumes) at high solution concentrations, and a reduction of contact angle with increase in concentration. It is found that the behavior of these solutions on graphite surfaces approximates the solution behavior on an activated carbon that is relatively low in acidic surface functional groups.

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Development of ⟨1 0 0⟩ crystallographic texture in magnetostrictive Fe–Ga wires using a modified Taylor wire method

Farrell¹,

Quigley²,

Avery³

et al. 2009

J. Phys. D: Appl. Phys.

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Magnetostrictive Fe–Ga wires 1–3 mm in diameter have been prepared using an innovative cost-effective approach—based on the Taylor wire method—that couples the advantages of high-temperature directional solidification and selective grain growth. Strict control of drawing processes has been shown to enable the introduction of desirable texture that is critical for achieving large magnetostriction in these polycrystalline Fe–Ga alloys. The procedure for fabricating highly textured ⟨1 0 0⟩ magnetostrictive wires is discussed and the wires are evaluated in terms of microstructure and crystallographic texture. Magnetostriction measurements, in the absence of pre-stress and stress-annealing treatments, indicated a maximum magnetostriction of ∼170 ppm in a saturation field less than 60 mT. A mechanism for texture evolution is proposed. It is speculated that the resultant ⟨1 0 0⟩ texture of the Fe–Ga wires is due to directional solidification and abnormal grain growth resulting from surface effects. The unique properties of wires made with the Taylor-based approach coupled with the low fabrication cost make this an attractive approach for the production of Fe–Ga wire with a specific crystallographic texture.

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Magnetostrictive Fe-Ga Wires with <100> Fiber Texture

Farrell

Quigley²,

Avery

et al. 2008

MRS Proc.

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Recently, low-cost processing approaches that produce textured thin bodies have engendered interest as cost-effective approaches for fabrication of magnetostrictive Fe-Ga alloys. In particular, wire-forming methods that strictly control the solidification direction could lead to some measure of crystallographic texture control. This is critical for development of large magnetostriction in polycrystals and for use of the alloys in actuators, sensors, energy harvesters and other systems. Magnetostrictive Fe-Ga wires have been prepared using an innovative costeffective approach -based on the Taylor wire method -that combines rapid solidification and deformation processes. The procedure for making magnetostrictive wires is discussed and the wires are evaluated in terms of microstructure, crystallographic texture and magnetostriction. Results show that the Taylor-based approach is an effective and versatile means to draw 1-3 mm diameter textured Fe-Ga wire. Experimentation on the influence of drawing technique and quench conditions on texture development resulted with production of a strong <100> fiber texture in the Fe-Ga wire. Magnetostriction measurements, in the absence of prestress, indicated a maximum magnetostriction of ~165 ppm in a saturation field of less than 200 mTesla. This is considered a significant strain for bulk polycrystalline Fe-Ga alloys without a pre-stress or a stress-annealing treatment. The unique properties of wires made with the Taylor-based approach coupled with the low intrinsic cost make this an attractive approach for production of textured magnetostrictive wire for a variety of applications.

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Stephanie Flynn

Exclusion of Salt Solutions from Activated Carbon Pores and the Relationship to Contact Angle on Graphite

Development of ⟨1 0 0⟩ crystallographic texture in magnetostrictive Fe–Ga wires using a modified Taylor wire method

Magnetostrictive Fe-Ga Wires with <100> Fiber Texture

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