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Online since: October 2013
Authors: Sujeeva Setunge, S.A. Hadigheh, R.J. Gravina, S.J. Kim
El Damatty, R.
Cao, et al., ESPI measurement of bond-slip relationships of FRP-concrete interface, Journal of Composites for Construction, Vol. 11 2 (2007) 149-160
Bai, et al., Editors, Melbourne, Australia, (2012) 175-180
Cao, et al., ESPI measurement of bond-slip relationships of FRP-concrete interface, Journal of Composites for Construction, Vol. 11 2 (2007) 149-160
Bai, et al., Editors, Melbourne, Australia, (2012) 175-180
Online since: September 2014
Authors: Wan Jia Zhang, Xiao Min Zhang, Bing Yao, Xia Liu, Xiang En Chen
In [18] Zhang et al. studied the topological properties of Sierpinski network models (also, (C3, C3)-FBGN-models) generated by implementing the edge-to-node operation O(H(e)àG(v)) to two triangles H=C3 and G=C3 (Ref. a model M3 shown in Fig. 3).
In [20] Zhang et al. investigated the scale-free topology and average distance of some (p,H0)-UHN-models.
A node v of T0 holds |N(v)ÈL(T0)|=dT0(v)-1.
In [20] Zhang et al. investigated the scale-free topology and average distance of some (p,H0)-UHN-models.
A node v of T0 holds |N(v)ÈL(T0)|=dT0(v)-1.
Online since: December 2012
Authors: Thierry Keller, Jan Veneman
a b c d e
Fig. 1: Some examples of typical mechanical structures that can be found in gait rehabilitation robotics, figure courtesy of Iñaki Díaz et al [1].
Hoover, Semble EL, C.M.
Richards, et. al., Robot-Assisted Therapy for Long-Term Upper-Limb Impairment after Stroke, N Engl J Med 362 (2010) 1772-1783.
Hoover, Semble EL, C.M.
Richards, et. al., Robot-Assisted Therapy for Long-Term Upper-Limb Impairment after Stroke, N Engl J Med 362 (2010) 1772-1783.
Online since: January 2013
Authors: Wilfried Vervisch, Laurent Ottaviani, Olivier Palais, Stephane Biondo
Dark currents revealed to be lower with Al-implanted diodes (2 pA/cm2 @ - 5 V), giving rise to visible rejection ratios as high as 7x104.
Indeed, the simulated wavelength range (200-300 nm) does not allow the photons to penetrate beyond the interface between the intrinsic layer and the substrate, since Sridhara et al. estimated a penetration depth lower than 7.5 µm for wavelengths lower than 325 nm [11].
El Khakani, F.
Indeed, the simulated wavelength range (200-300 nm) does not allow the photons to penetrate beyond the interface between the intrinsic layer and the substrate, since Sridhara et al. estimated a penetration depth lower than 7.5 µm for wavelengths lower than 325 nm [11].
El Khakani, F.
Online since: March 2015
Authors: Alexandru Ghiban, Brandusa Ghiban, Mihai Buzatu, Cristina Maria Bortun
[3] E.L.
Bertrand et al: Optimization of operator and physical parameters for laser welding of dental materials.
Wang et al., Thermal modeling of laser welding for titanium dental restorations, J Prosthet Dent.
Bertrand et al: Optimization of operator and physical parameters for laser welding of dental materials.
Wang et al., Thermal modeling of laser welding for titanium dental restorations, J Prosthet Dent.
Online since: June 2008
Authors: Tilman Bohn, Clemens Müller, Enrico Bruder
Experimental
The material used in this investigation is a HSLA sheet steel of the grade ZStE 500 (0.07 wt% C,
0.71 wt% Mn, 0.1 wt% Cr, 0.047 wt% Si, 0.034 wt% Nb and 0.016 wt% Al) with a thickness (s0) of
2 mm.
Note: The yield drop of both annealed conditions is an interesting phenomenon that has also been reported for UFG 1100-Al and UFG IF steel produced by accumulative roll bonding [7] but has not been clarified yet.
Landersheim, C. el Dsoki, P.
Note: The yield drop of both annealed conditions is an interesting phenomenon that has also been reported for UFG 1100-Al and UFG IF steel produced by accumulative roll bonding [7] but has not been clarified yet.
Landersheim, C. el Dsoki, P.
Online since: March 2020
Authors: Nova Alviati, Soni Sisbudi Harsono, Henry Ayu Kartikasari, Edy Supriyanto, Agus Geter Edy Sutjipto
[3] Cahya, Eka et al., “Studi Performansi Natural Dye-Sensitized Solar Cell Menggunakan Fotoelektrode TiO2 Nanopartikel”, Institut Teknologi Bandung, 2017
Indonesian Journal of Applied Physics, 6(02), 73–78 (2016) [6] Syafinar, R et al. 79 Energy Procedia Potential of Purple Cabbage, Coffee, Blueberry and Turmeric as Nature Based Dyes for Dye-Sensitized Solar Cell (DSSC), Elsevier B.V. http://dx.doi.org/10.1016/j.egypro.2015.11.569 (2015) [7] Latifataz, Zid., Prajitno, Gontjang., Mulberry Ekstrak Buah Murbei (Morus) sebagai Sensitizer Alami Dye Sensitized Solar Cells (DSSC) menggunakan ITO dengan teknik Pelapisan Spin Coating, Journal of Sains dan Art ITS, Vol. 4, No. 1 (2015) 23337-3520 (2015) [8] Wongcharee, Khwanchit, Vissanu Meeyoo, and Sumaeth Chavadej., Dye-Sensitized Solar Cell Using Natural Dyes Extracted from Rosella and Blue Pea Flowers, 91: 566–71 (2007) [9] Ni, Meng, Michael K H Leung, and Dennis Y C Leung., Theoretical Modelling of the Electrode Thickness Effect on Maximum Power Point of Dye-Sensitized Solar Cell, Canadian Journal of Chemical Engineering 86(1): 35–42 (2008) [10] Lamichhane, P., Prasad, Bhim., Narayan
Journal of Energy and Natural Resources, Doi: 10.11648/j.jenr.20140303.13, ISSN: 2330-7366 (2014) [12] Tayyan, Ahmed A El., Dye-Sensitized Solar Cell: Parameters Calculation and Model Integration, Journal of Electron Devices 11: 616–24 (2011) [13] Norasikin, A., Mahmoud, A., Abu Bakar M., et all., Utilization of Natural Dyes from Zingiber Officinale Leaf and Clitoria Ternatea Flowers to Prepare New Photosensitizers for Dye-Sensitized Solar Cells.
Indonesian Journal of Applied Physics, 6(02), 73–78 (2016) [6] Syafinar, R et al. 79 Energy Procedia Potential of Purple Cabbage, Coffee, Blueberry and Turmeric as Nature Based Dyes for Dye-Sensitized Solar Cell (DSSC), Elsevier B.V. http://dx.doi.org/10.1016/j.egypro.2015.11.569 (2015) [7] Latifataz, Zid., Prajitno, Gontjang., Mulberry Ekstrak Buah Murbei (Morus) sebagai Sensitizer Alami Dye Sensitized Solar Cells (DSSC) menggunakan ITO dengan teknik Pelapisan Spin Coating, Journal of Sains dan Art ITS, Vol. 4, No. 1 (2015) 23337-3520 (2015) [8] Wongcharee, Khwanchit, Vissanu Meeyoo, and Sumaeth Chavadej., Dye-Sensitized Solar Cell Using Natural Dyes Extracted from Rosella and Blue Pea Flowers, 91: 566–71 (2007) [9] Ni, Meng, Michael K H Leung, and Dennis Y C Leung., Theoretical Modelling of the Electrode Thickness Effect on Maximum Power Point of Dye-Sensitized Solar Cell, Canadian Journal of Chemical Engineering 86(1): 35–42 (2008) [10] Lamichhane, P., Prasad, Bhim., Narayan
Journal of Energy and Natural Resources, Doi: 10.11648/j.jenr.20140303.13, ISSN: 2330-7366 (2014) [12] Tayyan, Ahmed A El., Dye-Sensitized Solar Cell: Parameters Calculation and Model Integration, Journal of Electron Devices 11: 616–24 (2011) [13] Norasikin, A., Mahmoud, A., Abu Bakar M., et all., Utilization of Natural Dyes from Zingiber Officinale Leaf and Clitoria Ternatea Flowers to Prepare New Photosensitizers for Dye-Sensitized Solar Cells.