Abstract
This paper presents the high performance nanotechnology software (HPNS) to enable scientific researchers for predicting, visualizing and observing the temperature behavior and some parameters characteristics of nanochip system and nanowire fabrication. The analysis of scientific algorithms and high performance computing are searchable through a user friendly web-based system. This software will involve some mathematical modeling, numerical simulations and high performance computing technology to improve the accuracy of prediction, visualization quality and parallel performance indicators. The parameters involve on the thermal control process of nanowire fabrication are focuses on pressure, density, space, time control. The identification of the parameters influences the process of nanowire fabrication. The next focused are parameters characteristics of nanochip system. The parameters that involve are temperature, electromagnetic wave, space, time and other properties impact of the development of multilayer nanochip system. The implementations of parallel algorithms for solving the Partial Differential Equation of heat transfer and wave motion problems are based on large sparse parabolic and elliptic types. The discretization technique to obtain a large sparse linear system of equations is based on Finite Difference Method. The HPNS will support the supercomputing of numerical simulations and its repository using distributed memory architecture. The performance indicators will investigate the parallel programs using Parallel Virtual Machine (PVM) and C language on Linux operating system in terms of run time, accuracy, convergence, errors, speedup, efficiency and effectiveness. As a conclusion, HPNS will be an alternative software system to support huge computational complexity of the multilayer nanochip system and nanowire fabrication model.
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Hamidinezhad, H., Wahab, Y., Othaman, Z., Ismail, A.K.: Synthesis and analysis of silicon nanowire temperatures using very high frequency plasma enhanced chemical vapor deposition. Appl. Surf. Sci. 257, 9188–9192 (2011)
Hamidinezhad, H., Wahab, Y., Othaman, Z., Ismail, A.K.: Influence of growth time on morphology of nanowires grown by VHF-PECVD. J. Cryst. Growth 332, 7–11 (2011)
Byong, K.K., Ju, J.K., Jeong, O.L.: Temperature-dependent transport properties of an individual GaP nanowire with a Ga2O3 outer shell. J. Korean Phys. Soc. 46, 1262–1265 (2005)
Ahmad, M., Ali, I., Islam, M.U., Rana, M.U.: Investigation of co-substituted nanosized Mn2Y-hexaferrites synthesized by sol-gel autocombustion method. J. Mater. Eng. Perform. 22, 3909–3915 (2013)
Wang, B., Mazumder, P.: Fast thermal analysis for VLSI circuits via semi-analytical Green’s function in multi-layer materials. IEEE Int. Symp. Circ. Syst. 2, 409–412 (2004)
Xia, T., Malasarn, D., Lin, S., Ji, Z., Zhang, H., Miller, R.J., Keller, A.A., Nisbet, R.M., Harthorn, B.H., Godwin, H.A., Lenihan, H.S., Liu, R., Gardea-Torresdey, J., Cohen, Y., Mädler, L., Holden, P.A., Zink, J.I., Nel, A.E.: Implementation of a multidisciplinary approach to solve complex nano EHS problems by the UC center for the environmental implications of nanotechnology. Small 9, 1428–1443 (2013)
Alias, N., Saipol, H.F.S., Asnida, A.G., Mustaffa, M.N.: Parallel performance of group explicit method between parallel virtual machine and Matlab distributed computing for solving large sparse problems. Adv. Sci. Lett. 20, 477–482 (2013)
Zhan, Y., Sapatnekar, S.S.: A high efficiency full-chip thermal simulation algorithm. In: Proceedings of the 2005 IEEE/ACM International conference on Computer-aided design, pp. 635 – 638 (2005)
Hippalgaonkar, K., Huang, B., Chen, R., Sawyer, K., Ercius, P., Majumdar, A.: Fabrication of microdevices with integrated nanowires for investigating low-dimensional phonon transport. Nano Lett. 10(11), 4341–4348 (2010)
Garnett, E.C., Cai, W., Cha, J.J., Mahmood, F., Connor, S.T., GreysonChristoforo, M., Cui, Y., McGehee, M.D., Brongersma, M.L.: Self-limited plasmonic welding of silver nanowire junctions. Nat. Mater. 11(3), 241–249 (2012)
Alias, N., Saipol, H.F.S., Ghani, A.C.A., Mustaffa, M.N.: Parallel performance comparison of alternating group explicit method between parallel virtual machine and matlab distributed computing for solving large sparse partial differential equations. Adv. Sci. Lett. 20(2), 477–482 (2014)
Abu Mansor, N., Zulkifle, A.K, Alias, N., Hasan, M.K., Boyce, M.J.N.: The higher accuracy fourth-order IADE algorithm. J. Appl. Math. 2013, 13 pages (2013). Article number 236548
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This work was supported in part by Universiti Teknologi Malaysia (UTM) and Research Grant (Tier 2 E) No. (Q.J130000.2626.10J33).
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Alias, N., Satam, N., Othman, M.S., Che Teh, C.R., Mustaffa, M.N., Saipol, H.F. (2015). High Performance Nanotechnology Software (HPNS) for Parameter Characterization of Nanowire Fabrication and Nanochip System. In: Fujita, H., Selamat, A. (eds) Intelligent Software Methodologies, Tools and Techniques. SoMeT 2014. Communications in Computer and Information Science, vol 513. Springer, Cham. https://doi.org/10.1007/978-3-319-17530-0_18
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DOI: https://doi.org/10.1007/978-3-319-17530-0_18
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