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Online since: June 2014
Authors: Gaelle Pouget, Christophe Sigli
The coarsening kinetics of a stoichiometric precipitate can be described by Eq. 1 [6].
References [1] J.G.
Silcock, The structural ageing characteristics of Al-Cu-Mg alloys with Copper:Magnesium weight ratios of 7:1 and 2,2:1.
Forsyth, Effects of additions of 1% Iron and 1% Nickel on the age-hardening of an Al-2.5Copper-1.2Magnesium alloy.
National Materials Advisory Board (NMAB-479), National Academy Press, Washington D.C. 1996.
References [1] J.G.
Silcock, The structural ageing characteristics of Al-Cu-Mg alloys with Copper:Magnesium weight ratios of 7:1 and 2,2:1.
Forsyth, Effects of additions of 1% Iron and 1% Nickel on the age-hardening of an Al-2.5Copper-1.2Magnesium alloy.
National Materials Advisory Board (NMAB-479), National Academy Press, Washington D.C. 1996.
Online since: August 2013
Authors: Wei Bing Wu, Chang Hong Yang, Hai Tao Wu, Guang Da Hu, Feng Yang
Fig.1.
It is noted that, since Eq.(1) involves the work functions W1 and W2 of metals with free and clean surfaces.
Results and discussions The out-of-plane polarization P-E loops [8] of (001) -oriented ultrathin films for nanoscale (10 nm, 20nm, 50nm) capacitors were simulated under different values of interfacial capacitances ci, equals to (1/cm1 + 1/cm2)-1, to verify the validity of the model, as shown in Fig. 2.
References [1] F.
[19] Values of the materials parameters (in SI units, where the temperature T in ℃) used in the simulation. α1=3.8(T-479)×105, α11=-2.097×108, α111=1.294×109, α123=-2.5×109, α1111=3.863× 1010, Q11=0.1, Q12=-0.034, Q44=0.058, c11=1.78×1011, c12=0.96×1011, c44=1.22×1011, G11=2.786 ×10-10
It is noted that, since Eq.(1) involves the work functions W1 and W2 of metals with free and clean surfaces.
Results and discussions The out-of-plane polarization P-E loops [8] of (001) -oriented ultrathin films for nanoscale (10 nm, 20nm, 50nm) capacitors were simulated under different values of interfacial capacitances ci, equals to (1/cm1 + 1/cm2)-1, to verify the validity of the model, as shown in Fig. 2.
References [1] F.
[19] Values of the materials parameters (in SI units, where the temperature T in ℃) used in the simulation. α1=3.8(T-479)×105, α11=-2.097×108, α111=1.294×109, α123=-2.5×109, α1111=3.863× 1010, Q11=0.1, Q12=-0.034, Q44=0.058, c11=1.78×1011, c12=0.96×1011, c44=1.22×1011, G11=2.786 ×10-10
Online since: March 2011
Authors: Qing Hua Zou
Fig.1 is the CCT continuous cooling transformation curve diagram for carbon steel bar with the same diameters by taking the temperature as Y-coordinate and the diameter of the time as X-coordinate, from which transformation of the structures when carbon steel bar with the same diameters is cooled by the different cooling rate can be read out. [1,2]
1.2 CCT curves and establishment of the dynamic phase diagram
Fig.1.
Take Fig.1 as an example.
The visualized output of the phase diagram are shown as follows: if((pDoc->m_Graphics.m_FeCPhaseArray[j].xArray.GetSize()<1) || (pDoc->m_Graphics.m_FeCPhaseArray[j].yArray.GetSize()<1)) continue; // to judge the array is not empty; nCount =pDoc->m_Graphics.m_FeCPhaseArray[j].yArray.GetSize();// calculate the value of the array //obtain the data at the first point x = pDoc->m_Graphics.m_FeCPhaseArray[j].xArray.GetAt(0); y = pDoc->m_Graphics.m_FeCPhaseArray[j].yArray.GetAt(0); // obtain the data at the first point // scaling, conversion of coordinates,; move to the first point; pDC->MoveTo(c2v(x*pDoc->m_dContentAxisScale, y*pDoc->m_dTmpAxisScale)); …………..
Reference [1] Zou, Q.; Cao, H.; Wang, Z.; Zhang, Z.; Chen, X., Dynamic phase diagrams and non-equilibrium lever principle of carbon steel[J].Materials Technology, 2006,21(1):21-27
[2] Z Qing-Hua, C Hong, C Xiao-Dao, New-Type Dynamical Phase Diagrams and a Nonequilibrium-Lever Rule for Carbon Steels[J].The Physics of Metals and Metallography, 2005,100 (5):472-479
Take Fig.1 as an example.
The visualized output of the phase diagram are shown as follows: if((pDoc->m_Graphics.m_FeCPhaseArray[j].xArray.GetSize()<1) || (pDoc->m_Graphics.m_FeCPhaseArray[j].yArray.GetSize()<1)) continue; // to judge the array is not empty; nCount =pDoc->m_Graphics.m_FeCPhaseArray[j].yArray.GetSize();// calculate the value of the array //obtain the data at the first point x = pDoc->m_Graphics.m_FeCPhaseArray[j].xArray.GetAt(0); y = pDoc->m_Graphics.m_FeCPhaseArray[j].yArray.GetAt(0); // obtain the data at the first point // scaling, conversion of coordinates,; move to the first point; pDC->MoveTo(c2v(x*pDoc->m_dContentAxisScale, y*pDoc->m_dTmpAxisScale)); …………..
Reference [1] Zou, Q.; Cao, H.; Wang, Z.; Zhang, Z.; Chen, X., Dynamic phase diagrams and non-equilibrium lever principle of carbon steel[J].Materials Technology, 2006,21(1):21-27
[2] Z Qing-Hua, C Hong, C Xiao-Dao, New-Type Dynamical Phase Diagrams and a Nonequilibrium-Lever Rule for Carbon Steels[J].The Physics of Metals and Metallography, 2005,100 (5):472-479
Online since: January 2013
Authors: Xi Tao Bao, Shun Chu Li, Dong Dong Gui
(1)
(In the expression, subscript 1 denotes fractured medium, subscript 2 denotes matrix rock medium.)
References [1] LI Shun-chu and HUANG Bing-guang.
Well Testing, 2002.11(5):1~3
Application Mathematics and Mechanics, 2004,25(1):93~99
Journal of Oil, 2011, 32(3):479~483
References [1] LI Shun-chu and HUANG Bing-guang.
Well Testing, 2002.11(5):1~3
Application Mathematics and Mechanics, 2004,25(1):93~99
Journal of Oil, 2011, 32(3):479~483
Online since: February 2008
Authors: Yan Li, Rui Long, Shi Zhong Wei, Wan Hong Zhang, Jian Ping Gao
Interface Microstructure of TiC Cermets/Steel Explosive Cladding
Plate
Li Yan
1,a, Wei Shi-zhong
1, Gao Jian-ping1, Zhang Wan-hong2and Long Rui2
1
Mat.
Fig. 1 (b) is the image to show this characteristic.
References [1] Y.
Vol. 49[1] (2000), p.5
Vol. 479 (2005), p.3855
Fig. 1 (b) is the image to show this characteristic.
References [1] Y.
Vol. 49[1] (2000), p.5
Vol. 479 (2005), p.3855
Online since: September 2016
Authors: Chun Ping Li, Ge Gao, Xin Chen
Table 1.
Fig.1 (b) and (c) present the calculated energy band structures of Zn0.875M0.125O (M=Fe, Co).
Fig. 1 Band structures: (a) Pure ZnO, (b) Fe doped ZnO, (c) Co doped ZnO.
This result somewhat agrees well with the reported theoretical result by Gao X.Q. et al. [1].
Li, et al., Chemical states of gold doped in ZnO films and its effect on electrical and optical properties, Journal of Alloys and Compounds, 585 (2014) 479-484
Fig.1 (b) and (c) present the calculated energy band structures of Zn0.875M0.125O (M=Fe, Co).
Fig. 1 Band structures: (a) Pure ZnO, (b) Fe doped ZnO, (c) Co doped ZnO.
This result somewhat agrees well with the reported theoretical result by Gao X.Q. et al. [1].
Li, et al., Chemical states of gold doped in ZnO films and its effect on electrical and optical properties, Journal of Alloys and Compounds, 585 (2014) 479-484
Online since: February 2014
Authors: Gabriel Ostafe, Ioan Sarbu, Emilian Valea
Copper, iron, stainless steel, or other piping materials may be used to carry the cooling medium [1].
The numerical results obtained are summarized in Tables 1 and 2.
Table 1.
Energy-economical criterion c Econ. crit. y = 0 y = 0.25 y = 0.50 y = 0.75 y = 1.00 EP MW EP MW EP MW EP MW EP MW EP MW 0 1 2 3 4 5 6 7 8 9 10 11 12 0.060 236 334 407 697 351 554 315 479 289 429 270 394 0.065 356 561 323 488 299 444 281 411 0.070 361 568 330 500 309 458 294 428 0.075 365 575 338 511 319 473 306 445 Table 2.
*Corresponding Author Ioan Sarbu, Email: ioan.sarbu@ct.upt.ro, Fax: 0040256403987, Phone: 0040256403991 References [1] R.S.
The numerical results obtained are summarized in Tables 1 and 2.
Table 1.
Energy-economical criterion c Econ. crit. y = 0 y = 0.25 y = 0.50 y = 0.75 y = 1.00 EP MW EP MW EP MW EP MW EP MW EP MW 0 1 2 3 4 5 6 7 8 9 10 11 12 0.060 236 334 407 697 351 554 315 479 289 429 270 394 0.065 356 561 323 488 299 444 281 411 0.070 361 568 330 500 309 458 294 428 0.075 365 575 338 511 319 473 306 445 Table 2.
*Corresponding Author Ioan Sarbu, Email: ioan.sarbu@ct.upt.ro, Fax: 0040256403987, Phone: 0040256403991 References [1] R.S.
Online since: May 2010
Authors: Elisabetta Sagone, Claudia Castiglione, Maria Elvira De Caroli, Orazio Licciardello
Results
Creative performance
The results showed that our sample obtained high mean scores in fluency (M=10,96, sd=1,5) and
flexibility (M=7,75, sd=1,4), scores below the average in elaboration (M=9,75, sd=4,3) and in
production of titles (M=13,79, sd=3,6), scores around the average in originality (M=22,94, sd=4,8).
In general, pupils obtained average scores in total creative performance below standard average (M=65,19, sd=11,1).
Curiosity was positively correlated with complexity (r=.530, p<.001), imagination (r=.507, p<.001), and willingness to take risks (r=.461, p<.001).
Complexity was positively correlated with imagination (r=.479, p=.001) and willingness to take risks (r=.531, p<.001).
References [1] J.P.
In general, pupils obtained average scores in total creative performance below standard average (M=65,19, sd=11,1).
Curiosity was positively correlated with complexity (r=.530, p<.001), imagination (r=.507, p<.001), and willingness to take risks (r=.461, p<.001).
Complexity was positively correlated with imagination (r=.479, p=.001) and willingness to take risks (r=.531, p<.001).
References [1] J.P.