Abstract
One-dimensional nanostructures due to their unique properties and applications have generated special interests in MEMS and NEMS applications. There have been numerous methods developed to synthesize such 1D nanostructures. One of the most prominent methods is the electrodeposition into the channels in a porous material. It has been found that applied external magnetic field could improve and direct the growth of one-dimensional nanostructures in certain crystallographic directions. However, the nature and behavior of such structures and the influence of the synthesis parameters are yet to be fully understood. Our present work investigates the effect of the current density along with external magnetic field intensity on the growth direction of the one-dimensional Nickel nanowires. In the present study, Ni nanowires are grown using the electrodeposition assisted anodic alumina template method. The grown nanowires are characterized using XRD to determine the crystallographic properties. SEM was then used to characterize the morphology of the grown structures, while EDS was employed to study the composition. Present results clearly indicate that the morphological and crystallographic properties of synthesized nanowires are influenced by the applied current density and magnetic field intensity. Further studies employing Focused Ion Beam to prepare TEM sample are required to investigate the atomic arrangement of the synthesized Ni nanowires to further conform the present SEM and XRD findings.
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References
Chen J, Wiley BJ, Xia Y (2007) One-dimensional nanostructures of metals: large-scale synthesis and some potential applications. Langmuir 23(8):4120–4129
Xia Y et al (2003) One‐dimensional nanostructures: synthesis, characterization, and applications. Adv Mater 15(5):353–389
Barth S et al (2010) Synthesis and applications of one-dimensional semiconductors. Prog Mater Sci 55(6):563–627
Hernández-Vélez M (2006) Nanowires and 1D arrays fabrication: an overview. Thin Solid Films 495(1–2):51–63
Hu J, Odom TW, Lieber CM (1999) Chemistry and physics in one dimension: synthesis and properties of nanowires and nanotubes. Acc Chem Res 32(5):435–445
Kuchibhatla SV et al (2007) One dimensional nanostructured materials. Prog Mater Sci 52(5):699–913
Law M, Goldberger J, Yang P (2004) Semiconductor nanowires and nanotubes. Annu Rev Mater Res 34:83–122
Lieber CM (1998) One-dimensional nanostructures: chemistry, physics & applications. Solid State Commun 107(11):607–616
Rao CNR et al (2003) Inorganic nanowires. Prog Solid State Chem 31(1–2):5–147
Rao CNR et al (2004) Nanotubes and nanowires. Chem Eng Sci 59(22–23):4665–4671
Wang N, Cai Y, Zhang RQ (2008) Growth of nanowires. Mater Sci Eng R Rep 60(1–6):1–51
Wang ZL (2003) Nanobelts, nanowires, and nanodiskettes of semiconducting oxides—from materials to nanodevices. Adv Mater 15(5):432–436
Weber J et al (2008) One-dimensional nanostructures: fabrication, characterisation and applications. Int Mater Rev 53(4):235–255
Dresselhaus M et al (2007) Nanowires. In: Bhushan B (ed) Springer handbook of nanotechnology. Springer, Berlin, pp 113–160
Cao G (2004) Nanostructures & nanomaterials: synthesis, properties & application. Imperial College Press, London, p 433
Li W et al (2013) Sub-100 nm single crystalline periodic nano silicon wire obtained by modified nanoimprint lithography. Nanosci Nanotechnol Lett 5(7):737–740
Wu SE et al (2008) Fabrication of nanopillars comprised of InGaN/GaN multiple quantum wells by focused ion beam milling. Jpn J Appl Phys 47(6):4906–4908
Ji Y et al (2013) Nickel nanofibers synthesized by the electrospinning method. Mater Res Bull 48(7):2426–2429
Huczko A (2000) Template-based synthesis of nanomaterials. Appl Phys A Mater Sci Process 70(4):365–376
Martin CR (1994) Nanomaterials—a membrane-based synthetic approach. Science 266(5193):1961–1966
Martin CR (1996) Membrane-based synthesis of nanomaterials. Chem Mater 8(8):1739–1746
Hulteen JC, Martin CR (1997) A general template-based method for the preparation of nanomaterials. J Mater Chem 7(7):1075–1087
Cortes A et al (2009) Single-crystal growth of nickel nanowires: influence of deposition conditions on structural and magnetic properties. J Nanosci Nanotechnol 9(3):1992–2000
Aravamudhan S et al (2009) Magnetic properties of Ni-Fe nanowire arrays: effect of template material and deposition conditions. J Phy D Appl Phys 42(11):115008
Gong CH et al (2008) The fabrication and magnetic properties of Ni fibers synthesized under external magnetic fields. Eur J Inorg Chem 18:2884–2891
Fritz SE et al (2004) Structural characterization of a pentacene monolayer on an amorphous SiO2 substrate with grazing incidence X-ray diffraction. J Am Chem Soc 126(13):4084–4085
Smilgies D-M (2009) Scherrer grain-size analysis adapted to grazing-incidence scattering with area detectors. J Appl Crystallogr 42(6):1030–1034
Acknowledgments
This work was supported by Joint School of Nanoscience and Nanoengineering, North Carolina A&T State University. We also thank the Analytical Instrumentation Facility, North Carolina State University for the use of XRD facility.
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Samykano, M., Mohan, R., Aravamudhan, S. (2015). Effect of Current Density and Magnetic Field on the Growth and Morphology of Nickel Nanowires. In: Prorok, B., Starman, L., Hay, J., Shaw, III, G. (eds) MEMS and Nanotechnology, Volume 8. Conference Proceedings of the Society for Experimental Mechanics Series. Springer, Cham. https://doi.org/10.1007/978-3-319-07004-9_9
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DOI: https://doi.org/10.1007/978-3-319-07004-9_9
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