GridSpace2 Virtual Laboratory Case Study: Implementation of Algorithms for Quantitative Analysis of Grain Morphology in Self-assembled Hexagonal Lattices According to the Hillebrand Method

This work presents the implementation of a method, originally proposed by Hillebrand et al. [1], of quantitative analysis of the grain morphology in self-assembled hexagonal lattices. This method can be effectively used for investigation of structural features as well as regular hexagonal arrangement of nanoporous alumina layers formed on the metal surface during the self-organized anodization process. The method has been implemented as a virtual experiment in the GridSpace2 Virtual Laboratory [15] which is a scientific computing platform developed in the scope of the PL-Grid [9] project. The experiment is a GridSpace2 pilot and therefore made available to the wider community of PL-Grid users. It is both editable and executable through a web portal offered by the GridSpace2 Experiment Workbench [17], dedicated to PL-Grid users. Moreover, since all GridSpace2 experiments are embeddable on arbitrary web sites owing to the Collage [16] feature, the final version of the experiment has been published as an executable publication [18] with execution rights granted to all PL-Grid users.

[1]  Jacek Kitowski,et al.  PL-Grid: Foundations and Perspectives of National Computing Infrastructure , 2012, PL-Grid.

[2]  J. Szeremeta,et al.  Porous anodic alumina formed by anodization of aluminum alloy (AA1050) and high purity aluminum , 2010 .

[3]  Hari Singh Nalwa,et al.  Encyclopedia of nanoscience and nanotechnology , 2011 .

[4]  Tomasz Gubala,et al.  Exploratory programming in the virtual laboratory , 2010, Proceedings of the International Multiconference on Computer Science and Information Technology.

[5]  Leszek Zaraska,et al.  Anodic alumina membranes with defined pore diameters and thicknesses obtained by adjusting the anodizing duration and pore opening/widening time , 2011 .

[6]  Reinald Hillebrand,et al.  Quantitative analysis of the grain morphology in self-assembled hexagonal lattices. , 2008, ACS nano.

[7]  Krzysztof Kurowski,et al.  Parallel Large Scale Simulations in the PL-Grid Environment , 2010 .

[8]  I. Horcas,et al.  WSXM:走査型プローブ顕微鏡観察及びナノテクノロジー用のツールのためのソフトウェア | 文献情報 | J-GLOBAL 科学技術総合リンクセンター , 2007 .

[9]  Leszek Zaraska,et al.  Through-hole membranes of nanoporous alumina formed by anodizing in oxalic acid and their applications in fabrication of nanowire arrays , 2010 .

[10]  Piotr Nowakowski,et al.  The Collage Authoring Environment , 2011, ICCS.

[11]  G. Sulka Highly Ordered Anodic Porous Alumina Formation by Self‐Organized Anodizing , 2008 .

[12]  Marian Bubak,et al.  Managing Entire Lifecycles of e-Science Applications in the GridSpace2 Virtual Laboratory - From Motivation through Idea to Operable Web-Accessible Environment Built on Top of PL-Grid e-Infrastructure , 2012, PL-Grid.

[13]  Krzysztof Kurowski,et al.  New Capabilities in QosCosGrid Middleware for Advanced Job Management, Advance Reservation and Co-allocation of Computing Resources - Quantum Chemistry Application Use Case , 2012, PL-Grid.

[14]  J. Gómez‐Herrero,et al.  WSXM: a software for scanning probe microscopy and a tool for nanotechnology. , 2007, The Review of scientific instruments.