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Online since: June 2024
Authors: Ahmed M. Tahwia, Nirmen Abdelaziz, Ashraf Mohamed Heniegal, Mohamed Amin
Al-Kroom et al. [17] also indicated that adding crushed clay bricks improved the durability of structurally recycled lightweight concrete.
Moreover, Ahmad et al. [9] concluded that plastic aggregate weakens concrete, but plastic fibers can enhance its durability.
In this work, CEM I 52.5 Portland cement is produced by El-Aresh Company Egypt, and its tests were confirmed to comply with BSEN197/1 2011 [37] and ESS ES4756/1 2013 [38].
HRWR has a specific gravity equal al 1.09, and it meets the requirements according to ASTM C 494 Type G [42].
Al-Kroom, M.
Moreover, Ahmad et al. [9] concluded that plastic aggregate weakens concrete, but plastic fibers can enhance its durability.
In this work, CEM I 52.5 Portland cement is produced by El-Aresh Company Egypt, and its tests were confirmed to comply with BSEN197/1 2011 [37] and ESS ES4756/1 2013 [38].
HRWR has a specific gravity equal al 1.09, and it meets the requirements according to ASTM C 494 Type G [42].
Al-Kroom, M.
Online since: April 2013
Authors: Udayanath Aich
Penadés et al.
Barchi et al. synthesized several Thomsen-Friedenreich disaccharide linked gold nanoparticle as biotheraputic agents for cancer treatment [38].
A different synthetic strategy for the synthesis of lactose functionalized glyconanoparticles was reported by Kataoka et al. [41] (Fig. 4B).
Russell et al., developed lactose stabilized gold glyconanoparticle for the detection of Cholera toxin by Colorimetric assay method [77].
El-Boubbou, D.C.
Barchi et al. synthesized several Thomsen-Friedenreich disaccharide linked gold nanoparticle as biotheraputic agents for cancer treatment [38].
A different synthetic strategy for the synthesis of lactose functionalized glyconanoparticles was reported by Kataoka et al. [41] (Fig. 4B).
Russell et al., developed lactose stabilized gold glyconanoparticle for the detection of Cholera toxin by Colorimetric assay method [77].
El-Boubbou, D.C.
Online since: June 2020
Authors: Rovshan Alekberov, Olga Malyugina, Elena Maslova, Timur B. Minasov, Evgenii Kalinin, Dzhamilay Murzaeva
., Kemelman E.L.
[10] Vasilyev A.Yu., Bulanova I.M., Buzhilova A.P., Mednikova M.B. et al.
[11] Sokolova V.N., Potrakhov N.N., Gryaznov A.Yu., Staroverov N.E. et al. 2017.
[12] Potrahov N.N., Gryaznov A.Yu., Zhamova KK, Bessonov A.V. et al.
[10] Vasilyev A.Yu., Bulanova I.M., Buzhilova A.P., Mednikova M.B. et al.
[11] Sokolova V.N., Potrakhov N.N., Gryaznov A.Yu., Staroverov N.E. et al. 2017.
[12] Potrahov N.N., Gryaznov A.Yu., Zhamova KK, Bessonov A.V. et al.
Online since: April 2019
Authors: Emmanuel Opoku Marfo
As for external impacts, Smith et al., in their investigation of illicit timber logging in Indonesia, recommended that local government corruption has a number of effects on CIR (Linkie, et al. [31], [32, 33]) and different researchers proposed that market cost pressure absolutely connects with CIR.
El Akremi, V.
Jarvis, et al., "Spectroscopy of z∼ 7 candidate galaxies: using Lyman α to constrain the neutral fraction of hydrogen in the high-redshift universe★," Monthly Notices of the Royal Astronomical Society, vol. 443, pp. 2831-2842, 2014
Blyth, et al., "Spectral measurement of electron antineutrino oscillation amplitude and frequency at Daya Bay," Physical review letters, vol. 112, p. 061801, 2014
Al-Lawati, "Using PLS-SEM technique to model construction organizations' willingness to participate in e-bidding," Automation in construction, vol. 19, pp. 714-724, 2010
El Akremi, V.
Jarvis, et al., "Spectroscopy of z∼ 7 candidate galaxies: using Lyman α to constrain the neutral fraction of hydrogen in the high-redshift universe★," Monthly Notices of the Royal Astronomical Society, vol. 443, pp. 2831-2842, 2014
Blyth, et al., "Spectral measurement of electron antineutrino oscillation amplitude and frequency at Daya Bay," Physical review letters, vol. 112, p. 061801, 2014
Al-Lawati, "Using PLS-SEM technique to model construction organizations' willingness to participate in e-bidding," Automation in construction, vol. 19, pp. 714-724, 2010
Online since: August 2021
Authors: Agus Purwanto, Hafid Khusyaeri, Dewi Pratiwi, Haris Ade Kurniawan, Anisa Raditya Nurohmah, Cornelius Satria Yudha
According to Jenkins et. al (2014) a total of eight million metric tons of coffee is produced yearly worldwide [6].
In research carried out by Tsai et al. (2019), coffee grounds were rinsed and dried through two stages of carbonization [62].
A scientific study carried out by Tian et al. (2019) [93] regarding the red phosphorus doping method succeeded in increasing the conductivity of hard carbon anodes.
A study carried out by Rangom et.al reported that a good SEI layer can be formed by changing the current during the cells testing process [98].
El Moctar, Q.
In research carried out by Tsai et al. (2019), coffee grounds were rinsed and dried through two stages of carbonization [62].
A scientific study carried out by Tian et al. (2019) [93] regarding the red phosphorus doping method succeeded in increasing the conductivity of hard carbon anodes.
A study carried out by Rangom et.al reported that a good SEI layer can be formed by changing the current during the cells testing process [98].
El Moctar, Q.
Online since: November 2022
Authors: P. Selvakumar, Nixon Poulose, Jibin T. Philip, A. Ananthi, S. Kavitha
Specimen
Conductivity (W/mK)
CTE (ppm/k)
Reference
Matrix Material
Reinforcement
Binder/ Adhesive
Volume fraction, %
1
Cu
Di
Al
0.64
679
6.6
[4]
2
Cu
Di
Al
0.62
684
7
[4]
3
Cu
Di
Al
0.63
759
5.7
[4]
4
Cu
Di
Al
0.73
719
3.4
[4]
5
Cu
Di
Al
0.72
699
3.7
[4]
6
Cu
Di
Al
0.74
724
3.4
[4]
7
Cu
Di
Cr3C2
0.1
679
6.53
[16]
8
Cu
Di
Cr3C2
0.5
660
6.44
[16]
9
Cu
Di
Cr3C2
0.8
669
6.20
[16]
10
Cu
SACNT
-
0.26
406.8
[17]
11
Cu
SACNT
-
0.52
413.5
[17]
12
Cu
SACNT
-
0.78
420.3
[17]
13
Cu
SACNT
-
1.04
427
[17]
14
Al
Cu
Di
0.65
210-330
6
[18]
15
Cu
Di
Cr3C2
0.6
650-680
6.2-6.53
[16]
16
W
Cu
-
0.2
[19]
17
Cu
WC
In
0.62
[20]
18
Cu
CNT
-
0.5
378.5
[21]
19
Cu
SiC
-
0.6
[22]
20
Cu
Di
WC
0.63
715
6.3
[23]
21
Cu
Di
B
0.6
460
7
[24]
22
Al
Di
SiC
0.5
225-259
4.5-6.8
[25]
23
Al
Di
SiC
0.57
500
7.5
[26]
24
Al
Di
TiC
0.6
417
6.4-10
[27]
25
Al
Di
Ti
0.65
[28]
3.1.1.
Cu Di Cr3C2 0.1 400 180 679 6.53 [16] 2 Cu Di Cr3C2 0.5 500 225 660 6.44 [16] 3 Cu Di Cr3C2 0.8 520 200 669 6.20 [16] 4 Cu SACNT - 0.26 142 212.9 406.8 [17] 5 Cu SACNT - 0.52 165 253.6 413.5 [17] 6 Cu SACNT - 0.78 188 347.8 420.3 [17] 7 Cu SACNT - 1.04 208 399.3 427 [17] 8 Cu Di Al 0.64 679 6.6 [4] 9 Cu Di Al 0.62 684 7 [4] 10 Cu Di Al 0.63 759 5.7 [4] 11 Cu Di Al 0.73 719 3.4 [4] 12 Cu Di Al 0.72 699 3.7 [4] 13 Cu Di Al 0.74 724 3.4 [4] 14 Cu Di WC 0.63 121 380 390 146 715 6.3 [23] 15 Cu Di B 0.6 230 460 7 [24] 16 Al Di SiC 0.5 440-470 225-259 4.5-6.8 [25] 17 Al Di SiC 0.57 300 500 7.5 [26] 18 Al Di TiC 0.6 76 417 6.4-10 [27] 19 Al Di Ti 0.65 108 290 290 124 [28] 20 Al Cu Di 0.65 313-437 210-330 6 [18] 21 Cu Di Cr3C2 0.6 400-520 186-225 650-680 6.2-6.53 [16] 22 W Cu - 0.2 131-160 343-381 [19] 23 Cu WC In 0.62 110 [20] 24 Cu CNT - 0.5 371 378.5 [21] 25 Cu SiC - 0.6 260 [22] 3.3.
[38] 35 Cu TiB2 - 0.05,0.1,0.15,0.2 [39] 36 Al Di Ni 0.08, 0.25 [40] 37 Cu Al 0.1,0.2,0.3 [41] 38 Cu Di NiCrB 0.1,0.3 [42] 39 Cu Di NaCl 0.05 [43] 40 Cu Di 0.1,0.5 [34] 41 Al Di Si 0.6,0.65 [45] 42 Cu Di 0.05,0.1,0.15,0.2 [46] 43 Cu W Ni, Fe 0.87,0.95 [47] 44 Cu Di Cr 0.1 [48] 45 Cu Di Cr 0.6 [49] 46 Cu CNT - 0.04 [50] 47 Al Cu W 0.05-0.15 [51] 48 Cu Di, W - - [52] 49 Cu/Cr Di 0.02-0.15 [53] 50 Al TiO2, SiC 0.03-0.12 [54] 51 Al/Cu SiC/Al2O3 - [55] 52 Cu CNT SiC 0.01-0.1 [56] 53 Cu Gr 0.3 [57] 54 Cu ZrO2 0.02-0.4 [58] 55 Cu WC 0.09 [59] 56 Cu W Al2O3 [60] 57 Cu W - [61] 58 Di - - - [62] 59 Al Gr [63] 60 Cu Gr [64] 5.
Al and Cu are the most popular matrix materials.
El-Hadek, S.H.
Cu Di Cr3C2 0.1 400 180 679 6.53 [16] 2 Cu Di Cr3C2 0.5 500 225 660 6.44 [16] 3 Cu Di Cr3C2 0.8 520 200 669 6.20 [16] 4 Cu SACNT - 0.26 142 212.9 406.8 [17] 5 Cu SACNT - 0.52 165 253.6 413.5 [17] 6 Cu SACNT - 0.78 188 347.8 420.3 [17] 7 Cu SACNT - 1.04 208 399.3 427 [17] 8 Cu Di Al 0.64 679 6.6 [4] 9 Cu Di Al 0.62 684 7 [4] 10 Cu Di Al 0.63 759 5.7 [4] 11 Cu Di Al 0.73 719 3.4 [4] 12 Cu Di Al 0.72 699 3.7 [4] 13 Cu Di Al 0.74 724 3.4 [4] 14 Cu Di WC 0.63 121 380 390 146 715 6.3 [23] 15 Cu Di B 0.6 230 460 7 [24] 16 Al Di SiC 0.5 440-470 225-259 4.5-6.8 [25] 17 Al Di SiC 0.57 300 500 7.5 [26] 18 Al Di TiC 0.6 76 417 6.4-10 [27] 19 Al Di Ti 0.65 108 290 290 124 [28] 20 Al Cu Di 0.65 313-437 210-330 6 [18] 21 Cu Di Cr3C2 0.6 400-520 186-225 650-680 6.2-6.53 [16] 22 W Cu - 0.2 131-160 343-381 [19] 23 Cu WC In 0.62 110 [20] 24 Cu CNT - 0.5 371 378.5 [21] 25 Cu SiC - 0.6 260 [22] 3.3.
[38] 35 Cu TiB2 - 0.05,0.1,0.15,0.2 [39] 36 Al Di Ni 0.08, 0.25 [40] 37 Cu Al 0.1,0.2,0.3 [41] 38 Cu Di NiCrB 0.1,0.3 [42] 39 Cu Di NaCl 0.05 [43] 40 Cu Di 0.1,0.5 [34] 41 Al Di Si 0.6,0.65 [45] 42 Cu Di 0.05,0.1,0.15,0.2 [46] 43 Cu W Ni, Fe 0.87,0.95 [47] 44 Cu Di Cr 0.1 [48] 45 Cu Di Cr 0.6 [49] 46 Cu CNT - 0.04 [50] 47 Al Cu W 0.05-0.15 [51] 48 Cu Di, W - - [52] 49 Cu/Cr Di 0.02-0.15 [53] 50 Al TiO2, SiC 0.03-0.12 [54] 51 Al/Cu SiC/Al2O3 - [55] 52 Cu CNT SiC 0.01-0.1 [56] 53 Cu Gr 0.3 [57] 54 Cu ZrO2 0.02-0.4 [58] 55 Cu WC 0.09 [59] 56 Cu W Al2O3 [60] 57 Cu W - [61] 58 Di - - - [62] 59 Al Gr [63] 60 Cu Gr [64] 5.
Al and Cu are the most popular matrix materials.
El-Hadek, S.H.
Online since: May 2016
Authors: Rakshit Ameta, Surbhi Benjamin, Suresh C. Ameta, Dipti Soni, Neelu Chouhan
The fly ash-based mesoporous CdS/Al-MCM-41 nanocomposites were synthesized and uiltilized for hydrogen production by Zhang et al. [76].
Praus et al. [81] prepared ZnS nanoparticles.
Tan et al. [89] synthesized a nanocomposite for CO2 reduction to CO.
Al-Deyab, M.
El-Ballouli, L.
Praus et al. [81] prepared ZnS nanoparticles.
Tan et al. [89] synthesized a nanocomposite for CO2 reduction to CO.
Al-Deyab, M.
El-Ballouli, L.