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Online since: July 2015
Authors: Milena Pavlíková, Jaroslav Pokorný, Zbyšek Pavlík
Table 1.
Fig. 1 Particle size distribution of tested raw materials.
Material Matrix density [kg/m3] Bulk density [kg/m3] Open porosity [%] 28 days water curing RP 2 173 1 435 34.1 DB 8 2 198 1 475 33.3 DB 24 2 181 1 456 33.8 HE 8 2 209 1 472 33.5 HE 24 2 163 1 433 34.4 LI 8 2 176 1 473 32.6 LI 24 2 135 1 451 32.9 Table 6.
Basic physical properties of researched materials after 56 days exposure to laboratory conditions and CO2 chamber Material Matrix density [kg/m3] Bulk density [kg/m3] Open porosity [%] Matrix density [kg/m3] Bulk density [kg/m3] Open porosity [%] 56 days laboratory conditions 56 days CO2 chamber RP 2 270 1 556 31.4 2 412 1 735 28.1 DB 8 2 330 1 629 30.1 2 476 1 806 27.1 DB 24 2 323 1 584 31.8 2 411 1 695 29.6 HE 8 2 338 1 617 30.8 2 479 1 792 27.7 HE 24 2 316 1 559 32.7 2 416 1 704 29.5 LI 8 2 326 1 588 31.6 2 484 1 797 27.7 LI 24 2 308 1 572 32.8 2 434 1 712 29.7 From the measured data of basic physical properties, the development of mechanical strength given in Table 7 can be explained.
References [1] S.
Fig. 1 Particle size distribution of tested raw materials.
Material Matrix density [kg/m3] Bulk density [kg/m3] Open porosity [%] 28 days water curing RP 2 173 1 435 34.1 DB 8 2 198 1 475 33.3 DB 24 2 181 1 456 33.8 HE 8 2 209 1 472 33.5 HE 24 2 163 1 433 34.4 LI 8 2 176 1 473 32.6 LI 24 2 135 1 451 32.9 Table 6.
Basic physical properties of researched materials after 56 days exposure to laboratory conditions and CO2 chamber Material Matrix density [kg/m3] Bulk density [kg/m3] Open porosity [%] Matrix density [kg/m3] Bulk density [kg/m3] Open porosity [%] 56 days laboratory conditions 56 days CO2 chamber RP 2 270 1 556 31.4 2 412 1 735 28.1 DB 8 2 330 1 629 30.1 2 476 1 806 27.1 DB 24 2 323 1 584 31.8 2 411 1 695 29.6 HE 8 2 338 1 617 30.8 2 479 1 792 27.7 HE 24 2 316 1 559 32.7 2 416 1 704 29.5 LI 8 2 326 1 588 31.6 2 484 1 797 27.7 LI 24 2 308 1 572 32.8 2 434 1 712 29.7 From the measured data of basic physical properties, the development of mechanical strength given in Table 7 can be explained.
References [1] S.
Online since: June 2004
Authors: H. Maruyama, S. Uekusa
Maruyama
Department of Electrical and Electronic Engineering, Meiji University,
1-1-1 Higashi-mita, Tama-ku, Kawasaki, Kanagawa 214-8571, Japan
Keywords: implantation, Er (Erbium), ESR, crystallinity evaluation
Abstract.
(6)(6)(6)(6) (5)(5)(5)(5) (4)(4)(4)(4) (3)(3)(3)(3) (2)(2)(2)(2) (1)(1)(1)(1) current (μA) current (μA) current (μA) current (μA) voltage (V)voltage (V)voltage (V)voltage (V) (1) 1400℃ 30m in
I-V characteristics of Ni/ 4H-SiC:Er 4 0 0 5 0 0 6 0 0 7 0 0 8 0 0 PL Intensity (arb.units) (c ) (b ) (a) (d ) (a )1 4 0 0 oC (b )1 5 0 0 oC (c )1 6 0 0 oC (d )1 7 0 0 oC V irgin A s- Im p la P L a t 1 5 K 4 H - S iC :E r E r:1 x1 0 1 4c m - 2, 2 M e V E xc itatio n :3 2 5 .0 n m , 2 0 m W A n n e a lin g:3 0 m in .
W ave le n gth (n m ) Journal Title and Volume Number (to be inserted by the publisher) 4 1 5 0 0 1 5 2 0 1 5 4 0 1 5 6 0 1 5 8 0 1 6 0 0 P L a t 1 5 K 4 H - S iC :E r E r :1 x 1 0 1 3 c m - 2 , 2 M e V E x c it a t io n :3 2 5 .0 n m , 2 0 m W A n n e a lin g :3 0 m in . 1 4 0 0 o C 1 5 0 0 o C 1 6 0 0 o C 1 7 0 0 o C PL Intensity (arb.units) W a v e le n g t h ( n m ) Fig.5 the temperature dependence of the Er3+-related PL spectra of n-type 4H-SiC:Er dominant line at 1534.0 nm, 11 peaks and other small peaks.
B, vol. 106 (1995), pp. 477-479
(6)(6)(6)(6) (5)(5)(5)(5) (4)(4)(4)(4) (3)(3)(3)(3) (2)(2)(2)(2) (1)(1)(1)(1) current (μA) current (μA) current (μA) current (μA) voltage (V)voltage (V)voltage (V)voltage (V) (1) 1400℃ 30m in
I-V characteristics of Ni/ 4H-SiC:Er 4 0 0 5 0 0 6 0 0 7 0 0 8 0 0 PL Intensity (arb.units) (c ) (b ) (a) (d ) (a )1 4 0 0 oC (b )1 5 0 0 oC (c )1 6 0 0 oC (d )1 7 0 0 oC V irgin A s- Im p la P L a t 1 5 K 4 H - S iC :E r E r:1 x1 0 1 4c m - 2, 2 M e V E xc itatio n :3 2 5 .0 n m , 2 0 m W A n n e a lin g:3 0 m in .
W ave le n gth (n m ) Journal Title and Volume Number (to be inserted by the publisher) 4 1 5 0 0 1 5 2 0 1 5 4 0 1 5 6 0 1 5 8 0 1 6 0 0 P L a t 1 5 K 4 H - S iC :E r E r :1 x 1 0 1 3 c m - 2 , 2 M e V E x c it a t io n :3 2 5 .0 n m , 2 0 m W A n n e a lin g :3 0 m in . 1 4 0 0 o C 1 5 0 0 o C 1 6 0 0 o C 1 7 0 0 o C PL Intensity (arb.units) W a v e le n g t h ( n m ) Fig.5 the temperature dependence of the Er3+-related PL spectra of n-type 4H-SiC:Er dominant line at 1534.0 nm, 11 peaks and other small peaks.
B, vol. 106 (1995), pp. 477-479
Online since: September 2011
Authors: Wang Sheng Fang, Yu Nan Li, Lu Lu Wu, Rong Zhang
An important issue in research of watermarking is the compromising between imperceptibility and robustness [1].
With Eq.1 toEq.4 can be critical of the visual threshold of wavelet coefficients:
Filtering attacking simulation Attack Gaussian low-pass Median filtering(3×3) Median filtering(4×4) Median filtering(5×5) Median filtering(6×6) Median filtering(7×7) NC 0.93373 0.99453 0.96281 0.92846 0.7974 0.64854 PSNR 36.1019 53.5436 50.1263 47.8976 44.0276 40.9222 Extract watermark Table 5.Cut and rotate attacking simulation Attack Upper left corner cut 1/16 Cut the upper left corner and upper right corner, 1/16 Four corners were cut 1/16 Center cut 1/4 Centre set to cut 1 / 4, the upper right corner cut 1 /16 Rotation 10 degrees NC 1 1 1 1 1 0.9993 PSNR 30.2941 29.2904 27.2827 27.249 27.2435 26.7436 Extract watermark Table 1- 5demonstrates the effects of the extracted watermark from watermarked Lena image which has subjected to various attacks.
References [1] Cong Jin, Junming Ye, Kaihua Xu.
[2] A K Parthasarathy,S Kak.An improved method of content based image watermarking.IEEE Transactions on Broadcasting, 53(2007) 468-479
With Eq.1 toEq.4 can be critical of the visual threshold of wavelet coefficients:
Filtering attacking simulation Attack Gaussian low-pass Median filtering(3×3) Median filtering(4×4) Median filtering(5×5) Median filtering(6×6) Median filtering(7×7) NC 0.93373 0.99453 0.96281 0.92846 0.7974 0.64854 PSNR 36.1019 53.5436 50.1263 47.8976 44.0276 40.9222 Extract watermark Table 5.Cut and rotate attacking simulation Attack Upper left corner cut 1/16 Cut the upper left corner and upper right corner, 1/16 Four corners were cut 1/16 Center cut 1/4 Centre set to cut 1 / 4, the upper right corner cut 1 /16 Rotation 10 degrees NC 1 1 1 1 1 0.9993 PSNR 30.2941 29.2904 27.2827 27.249 27.2435 26.7436 Extract watermark Table 1- 5demonstrates the effects of the extracted watermark from watermarked Lena image which has subjected to various attacks.
References [1] Cong Jin, Junming Ye, Kaihua Xu.
[2] A K Parthasarathy,S Kak.An improved method of content based image watermarking.IEEE Transactions on Broadcasting, 53(2007) 468-479
Online since: March 2010
Authors: José C. Escobedo-Bocardo, E.M. Múzquiz-Ramos, O.A. Herrera-Romero, Dora A. Cortés-Hernández
An aqueous solution of citric acid was
mixed with the metal nitrates solution, the molar ratio betweeen total metal ions and citric acid was
controlled at 1:1, 1:2, and 1:3.
Results and discussion Fig. 1 shows the XRD pattern of cobalt ferrite prepared in a molar ratio of 1:3.
Fig. 1.
-10000 -5000 0 5000 10000 -60 -40 -20 0 20 40 60 300 °C 600 °C 900 °C 1200 °C Magnetization (emu/g) Applied Magnetic Field (Oe) Molar ratio 1:3 -10000 -5000 0 5000 10000 -60 -40 -20 0 20 40 60 1:1 1:2 1:3 Magnetization (emu/g) Applied Magnetic Field (Oe) Molar Ratio Ms Mr Hc 1:1 62.8 24.9 741 1:2 53.0 20.7 752 1:3 68.2 4.85 103 The particle size was determined by the Scherrer equation using the most intense (311) peak [16].
Jadhav: Solid State Commun. 147 (2008) 479- 483
Results and discussion Fig. 1 shows the XRD pattern of cobalt ferrite prepared in a molar ratio of 1:3.
Fig. 1.
-10000 -5000 0 5000 10000 -60 -40 -20 0 20 40 60 300 °C 600 °C 900 °C 1200 °C Magnetization (emu/g) Applied Magnetic Field (Oe) Molar ratio 1:3 -10000 -5000 0 5000 10000 -60 -40 -20 0 20 40 60 1:1 1:2 1:3 Magnetization (emu/g) Applied Magnetic Field (Oe) Molar Ratio Ms Mr Hc 1:1 62.8 24.9 741 1:2 53.0 20.7 752 1:3 68.2 4.85 103 The particle size was determined by the Scherrer equation using the most intense (311) peak [16].
Jadhav: Solid State Commun. 147 (2008) 479- 483
Online since: April 2013
Authors: Hai Hong Gu, Fu Ping Li, Xiang Guan, Yong Li Xu, Ya Jing Liu, Xing Tong Chen, Xiao Hong Wang, Zheng Wang
The Cd, Zn, Cu and Pb concentrations in tested soil were 10, 329, 479, 946 mg kg-1, respectively.
The concentrations of available Si was 4430 mg·kg-1, and the available P concentrations was 1020 mg·kg-1.
The effects of FA on rice growth is shown in Fig. 1.
The concentration of available Cd was 6.7 μg·kg-1 in control, and the amount decreased by 78% at addition of 20 g·kg-1 FA, and the concentration was lower than the detection limit (0.5 μg·kg-1) in the treatment of FA40.
References [1] M.C.
The concentrations of available Si was 4430 mg·kg-1, and the available P concentrations was 1020 mg·kg-1.
The effects of FA on rice growth is shown in Fig. 1.
The concentration of available Cd was 6.7 μg·kg-1 in control, and the amount decreased by 78% at addition of 20 g·kg-1 FA, and the concentration was lower than the detection limit (0.5 μg·kg-1) in the treatment of FA40.
References [1] M.C.
Online since: June 2016
Authors: Satworo Adiwidodo, Mega Nur Sasongko, I.N.G. Wardana, Lilis Yuliati
Fig 1.
Dimension of meso-scale combustor Tabel 1.
Combustor wall temperature at f =1 Fig 7.Combustor inlet temperature at f =1 Fig. 6 shows that the increase in flow velocity at f = 1 effectively raises the temperature of the wall.
References [1] J.
[5] Fan A., Minaev S., Kumar S., Liu W., Maruta K., Regime diagrams and characteristics of flame patterns in radial micochannels with temperature gradients, Combustion and Flame 153 (2008) 479-489
Dimension of meso-scale combustor Tabel 1.
Combustor wall temperature at f =1 Fig 7.Combustor inlet temperature at f =1 Fig. 6 shows that the increase in flow velocity at f = 1 effectively raises the temperature of the wall.
References [1] J.
[5] Fan A., Minaev S., Kumar S., Liu W., Maruta K., Regime diagrams and characteristics of flame patterns in radial micochannels with temperature gradients, Combustion and Flame 153 (2008) 479-489
Online since: July 2016
Authors: Hong Xu Chen, Zheng Guang Zou, Qi Yuan, Zhong Liang Hou
In a typical procedure,1.2g of crystalline V2O5 powder and 0.7g oxalic acid was dispersed in 50ml mixed solution which made up by water and HCl with a volume ratio of 50:0,150:1 and 80:1.
Results and discussion Fig.1.
However, compared the VO-1,VO-2 with VO-0, we found the peaks of the VO-1,VO-2 mildly moved in high-angle, that indicate the crystalline interplanar spacing of the VO-1,VO-2 have decreased.
References [1] Y.
Phys. 126, 476–479 (2011) [10] O.
Results and discussion Fig.1.
However, compared the VO-1,VO-2 with VO-0, we found the peaks of the VO-1,VO-2 mildly moved in high-angle, that indicate the crystalline interplanar spacing of the VO-1,VO-2 have decreased.
References [1] Y.
Phys. 126, 476–479 (2011) [10] O.
Online since: April 2015
Authors: Xin Xin, Wei Hong Zhang, Lian Xu Yu, Fang Liu, Wen Ru Sun, Zhuang Qi Hu, Dan Jia
The as-cast microstructures of the test alloys were shown in Fig. 1.
Fig. 1 Effect of Co on dendritic structure in the as-cast alloys.
(a) No. 1 alloy.
References [1] H.
A Vol. 479(2008): P 148
Fig. 1 Effect of Co on dendritic structure in the as-cast alloys.
(a) No. 1 alloy.
References [1] H.
A Vol. 479(2008): P 148
Online since: August 2011
Authors: Ying Fu, Xin Yu Zhang, Nan Shil, Ji Chao Zhang
Introduction
Coagulant is very important in treating polluted waters[1-3].
And then, some stabilizer M (C4H4O6Na2·2H2O:NaClO=1:6.5) was added and the product PSF (Si/Fe molar ratio equals to 1) was diluted to Fe concentration of 10 g.l-1.
And then, some stabilizer M (C4H4O6Na2·2H2O:NaClO=1.5:6.5) was added and the product OPSF (Si/Fe molar ratio equals to 1) with w(DMDAAC) 7.5% was diluted to Fe concentration of 10 g.l-1.
References [1] W.
Ehara: Europe Patent 479 219(CL.COZF 1/52). (1992) [9] B.Y.
And then, some stabilizer M (C4H4O6Na2·2H2O:NaClO=1:6.5) was added and the product PSF (Si/Fe molar ratio equals to 1) was diluted to Fe concentration of 10 g.l-1.
And then, some stabilizer M (C4H4O6Na2·2H2O:NaClO=1.5:6.5) was added and the product OPSF (Si/Fe molar ratio equals to 1) with w(DMDAAC) 7.5% was diluted to Fe concentration of 10 g.l-1.
References [1] W.
Ehara: Europe Patent 479 219(CL.COZF 1/52). (1992) [9] B.Y.
Online since: July 2014
Authors: Wen Bin Cao
Fig. 1 A three-lane freeway Fig. 2 Relationship between density and overtaking
different ratio under control conditions
As shown in Fig. 1, cars on lane 1 and lane 3 can change to lane 2 while cars on lane 2 can change to both lanes 1 and lane 3.
The distances between car in lane 2 and its adjacent front car in lane 1, lane 2 and lane 3 are defined as,,,.The distances between car in lane 2 and its following car in lane 1 and lane 3 are defined as and .The speed of car in lane 2 is defined as The speed of the following car in lane 1 and lane 3 are and .
Rule 1 Change from lane 1 to lane 2 if ,, (2) Change from lane 2 to lane 1 if ,,, (3) Change from lane 2 to lane 3 if , ,, (4) Change from lane 3 to lane 2 if ,,, (5) Rule 2 (The Keep-Right-Except-To-Pass Rule that is the cars on the passing lane are controlled) We only need to modify part of the Rule 1, and then we can get Rule 2(The Keep-Right-Except-To-Pass Rule), which is mentioned in question given.
Change from lane 1 to lane 2 if , (6) The rest part is the same as Rule 1.
Jiang, A realistic two-lane cellular automata traffic model considering aggressive lane-changing behavior of fast vehicle, Physica A 367 (2006) 479–486
The distances between car in lane 2 and its adjacent front car in lane 1, lane 2 and lane 3 are defined as,,,.The distances between car in lane 2 and its following car in lane 1 and lane 3 are defined as and .The speed of car in lane 2 is defined as The speed of the following car in lane 1 and lane 3 are and .
Rule 1 Change from lane 1 to lane 2 if ,, (2) Change from lane 2 to lane 1 if ,,, (3) Change from lane 2 to lane 3 if , ,, (4) Change from lane 3 to lane 2 if ,,, (5) Rule 2 (The Keep-Right-Except-To-Pass Rule that is the cars on the passing lane are controlled) We only need to modify part of the Rule 1, and then we can get Rule 2(The Keep-Right-Except-To-Pass Rule), which is mentioned in question given.
Change from lane 1 to lane 2 if , (6) The rest part is the same as Rule 1.
Jiang, A realistic two-lane cellular automata traffic model considering aggressive lane-changing behavior of fast vehicle, Physica A 367 (2006) 479–486