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Online since: February 2011
Authors: Xue Zhang, Su Qin Li, Kudureti Ayijamali
Introduction
In recent years, the zero-valent iron nanoparticles for environmental pollution control has become a new kind of pollution control technology[1-3].
Fig. 1 SEM images of nanoscale zero-valent iron prepared at different temperatures In order to further determine the purity of nanoscale zero-valent iron, energy spectrum was used and the results were shown in Fig.2.
Seen from Fig. 1 and Fig. 4, spherical nanoparticles became loose, variable shape with contain pore , indicating that nanoscale zero valent iron participated in the advanced oxidation reaction.
References [1] Lien H.
Chemistry of Materials,2001,13,(2):479~486
Fig. 1 SEM images of nanoscale zero-valent iron prepared at different temperatures In order to further determine the purity of nanoscale zero-valent iron, energy spectrum was used and the results were shown in Fig.2.
Seen from Fig. 1 and Fig. 4, spherical nanoparticles became loose, variable shape with contain pore , indicating that nanoscale zero valent iron participated in the advanced oxidation reaction.
References [1] Lien H.
Chemistry of Materials,2001,13,(2):479~486
Online since: October 2013
Authors: Su Ying Xu
Sectional view of the mechanism shown in Figure 1 .
Therefore, the body's internal cooling is crushed rubber processing requirements[1].
Figure 1.
References [1] Wu Xiulan, Li Guijun.
Advanced Materials Research , vol.424-425 (2012)p1028-1031 [5] Qiu Lijun, Yang Jia, Tire tread cutting machine design exploration, Advanced Materials Research , vol.479--481 (2012)p278-281
Therefore, the body's internal cooling is crushed rubber processing requirements[1].
Figure 1.
References [1] Wu Xiulan, Li Guijun.
Advanced Materials Research , vol.424-425 (2012)p1028-1031 [5] Qiu Lijun, Yang Jia, Tire tread cutting machine design exploration, Advanced Materials Research , vol.479--481 (2012)p278-281
Online since: August 2019
Authors: Prasopchai Patrojanasophon, Praneet Opanasopit, Theerasak Rojanarata, Tanasait Ngawhirunpat, Nitjawan Sahatsapan
Afterwards, DOP at the 1:1 molar ratio to SCS was dropped to the polymer solution.
Mucin stock solution (5% w/v) was newly made in phosphate buffer (PB) pH 7.4, before mixing with the polymer at the volume ratio of 1:1.
The findings are shown in Fig. 4 and Table 1.
References [1] M.
European Journal of Pharmaceutical Sciences, 12, 4 (2001) 479–485
Mucin stock solution (5% w/v) was newly made in phosphate buffer (PB) pH 7.4, before mixing with the polymer at the volume ratio of 1:1.
The findings are shown in Fig. 4 and Table 1.
References [1] M.
European Journal of Pharmaceutical Sciences, 12, 4 (2001) 479–485
Online since: May 2016
Authors: Jintamai Suwanprateeb, Waraporn Suvannapruk
Figure 1: Chemical structure of rifampicin [6].
Samples Vacuum/0 mmHg Drug solution level (percentage of bead’s height) Impregnation duration (minutes) Immersion No NA. 30 1_step Yes NA. 30 2_step Yes NA. 15-15 3_step Yes NA. 10-10-10 1_step_10 Yes 10% 30 1_step_30 Yes 30% 30 1_step_50 Yes 50% 30 1_step_70 Yes 70% 30 1_step_90 Yes 90% 30 · Characterizations.
IR spectra were obtained over the region 400-4000 cm-1 using the KBr pellet technique with a resolution of 4 cm-1.
References [1] J.
Res., 16 (2012) 479-482
Samples Vacuum/0 mmHg Drug solution level (percentage of bead’s height) Impregnation duration (minutes) Immersion No NA. 30 1_step Yes NA. 30 2_step Yes NA. 15-15 3_step Yes NA. 10-10-10 1_step_10 Yes 10% 30 1_step_30 Yes 30% 30 1_step_50 Yes 50% 30 1_step_70 Yes 70% 30 1_step_90 Yes 90% 30 · Characterizations.
IR spectra were obtained over the region 400-4000 cm-1 using the KBr pellet technique with a resolution of 4 cm-1.
References [1] J.
Res., 16 (2012) 479-482
Online since: April 2021
Authors: Azwar Manaf, Leyona Ta, Mas Ayu Elita Hafizah, Yana Taryana
Results of XRD examination of SrFe12-xInxO19 samples with x = 0,05; 0,1; 0,2; and 0,5 are shown in Fig. 1.
Table 1 shows the result of the XRD refined data analysis.
Result of XRD Refined Data Analysis of SrFe12-xInxO19 with x = 0,05; 0,1; 0,2; and 0,5 X Lattice parameters SrFe12O19 (Å) V (Å3) r (g/cm3) Weight Fraction a b c SrFe12O19 Fe2O3 0.05 5.8830(3) 5.8830(3) 23.044(1) 690.7(1) 5.469 100 % 0 % 0.10 5.8852(3) 5.8852(3) 23.053(1) 691.5(1) 5.463 100 % 0 % 0.20 5.8886(3) 5.8886(3) 23.068(2) 692.7(1) 5.453 81.23 % 18.77 % 0.50 5.9020(4) 5.9020(4) 23.131(2) 697.8(1) 5.413 67.91 % 32.09 % Magnetic and Microwave Absorption Properties.
References [1] Z.
Commun., vol. 54, no. 5, pp. 479–482, 2018, doi: 10.1039/c7cc08675j
Table 1 shows the result of the XRD refined data analysis.
Result of XRD Refined Data Analysis of SrFe12-xInxO19 with x = 0,05; 0,1; 0,2; and 0,5 X Lattice parameters SrFe12O19 (Å) V (Å3) r (g/cm3) Weight Fraction a b c SrFe12O19 Fe2O3 0.05 5.8830(3) 5.8830(3) 23.044(1) 690.7(1) 5.469 100 % 0 % 0.10 5.8852(3) 5.8852(3) 23.053(1) 691.5(1) 5.463 100 % 0 % 0.20 5.8886(3) 5.8886(3) 23.068(2) 692.7(1) 5.453 81.23 % 18.77 % 0.50 5.9020(4) 5.9020(4) 23.131(2) 697.8(1) 5.413 67.91 % 32.09 % Magnetic and Microwave Absorption Properties.
References [1] Z.
Commun., vol. 54, no. 5, pp. 479–482, 2018, doi: 10.1039/c7cc08675j
Online since: May 2012
Authors: Jing Li, Da Long Jiang, Xiao Ming Li
(Table 1)
Table 1 The number of various experimental treatments
4 µl/l
10 µl/l
20 µl/l
40 µl/l
1 h
A
B
C
D
2 h
E
F
G
H
4 h
I
J
K
L
3.
Light-curve 1.1.Decide the fixed illumination The light saturation point (LSP) was in approximately 1000μmol• m-2s-1, and the light compensation point (LCP) <20μmol·m-2s-1.
When PPFD was over 1000μmol·m-2s-1, An only rose 9.1% (the value refer to 1000μmolm-2s-1 obtained, similarly hereinafter) in condition I, but gs and E rose 33%, 42.3% separately (Fig. 1-b, c). 1.3.
Plant Physiology, 1980, 65:478-479
Environmental Pollution,1992,77(1):1-5
Light-curve 1.1.Decide the fixed illumination The light saturation point (LSP) was in approximately 1000μmol• m-2s-1, and the light compensation point (LCP) <20μmol·m-2s-1.
When PPFD was over 1000μmol·m-2s-1, An only rose 9.1% (the value refer to 1000μmolm-2s-1 obtained, similarly hereinafter) in condition I, but gs and E rose 33%, 42.3% separately (Fig. 1-b, c). 1.3.
Plant Physiology, 1980, 65:478-479
Environmental Pollution,1992,77(1):1-5
Online since: January 2016
Authors: Juraj Žilinský, Kamil Binek
Confrontation of ceramic bricks and aerated concrete bricks
Those physical characteristics used for graphical representation are introduced in Fig.1.
Savings function is exponential blue-line and the investment return period of 1 year, from 1.98 years and 2.2 years.
References [1] STN 73 0540-2:2012 Thermal protection of buildings.
Renewable and Sustainable Energy Reviews, Vol. 16, Issue 1, January 2012, pp. 415-425 [6] R.
Yüksel: Optimum Insulation Thickness of External Walls for Energy Saving, Applied Thermal Engineering, 23 (2003) pp. 473-479 [13] Joysef Nyers, Slavica Tomić, Arpad Nyers, Economic Optimum of Theraml Insulating Layer for External Wall of Brick, Acta Polytechnica Hungaria Vol.11, NO. 7, (2014) pp. 209 -222.
Savings function is exponential blue-line and the investment return period of 1 year, from 1.98 years and 2.2 years.
References [1] STN 73 0540-2:2012 Thermal protection of buildings.
Renewable and Sustainable Energy Reviews, Vol. 16, Issue 1, January 2012, pp. 415-425 [6] R.
Yüksel: Optimum Insulation Thickness of External Walls for Energy Saving, Applied Thermal Engineering, 23 (2003) pp. 473-479 [13] Joysef Nyers, Slavica Tomić, Arpad Nyers, Economic Optimum of Theraml Insulating Layer for External Wall of Brick, Acta Polytechnica Hungaria Vol.11, NO. 7, (2014) pp. 209 -222.
Online since: August 2013
Authors: Xue Li, Qiong Jia Yuan, Lu Wang
Methods: 60 male mice (3 month old) were randomly divided into 4 groups: control group (group C), exercise group 1-3 (group E1, E2, and E3) with 15 in each group.
Table 1 SOD activity and MDA Content of every group mouse(U/mgprot, ±S,n=6) Group SOD activity MDA Content C 89.32±14.53 4.82±1.24 E1 90.79±7.29 2.01±0.86﹡﹡ E2 191.93±11.10﹡﹡●● 1.36±0.31﹡﹡ E3 143.04±18.69﹡﹡●●▲▲ 1.93±0.25﹡﹡ Note:﹡﹡P<0.01, vs. group C;●●P<0.01, vs. group E1;▲▲P<0.01, vs. group E2.
References [1] Harman D.
Free radical theory of aging: Alzheimer’s disease pathogenesis age [J].1995, 1:97-119
Reprod Toxicol.2006, 22(3): 479-84
Table 1 SOD activity and MDA Content of every group mouse(U/mgprot, ±S,n=6) Group SOD activity MDA Content C 89.32±14.53 4.82±1.24 E1 90.79±7.29 2.01±0.86﹡﹡ E2 191.93±11.10﹡﹡●● 1.36±0.31﹡﹡ E3 143.04±18.69﹡﹡●●▲▲ 1.93±0.25﹡﹡ Note:﹡﹡P<0.01, vs. group C;●●P<0.01, vs. group E1;▲▲P<0.01, vs. group E2.
References [1] Harman D.
Free radical theory of aging: Alzheimer’s disease pathogenesis age [J].1995, 1:97-119
Reprod Toxicol.2006, 22(3): 479-84
Online since: February 2014
Authors: Yan Hui Li, Yan Meng Gong, Shu Zhong Wang, Li Li Qian
Materials and methods
FA (CAS: 479-66-3 ) with purity of 95% was purchased from Shanghai Huayi Bio-technology Co. , Ltd (China). 30 wt% hydrogen peroxide (H2O2) solution was singled out as the oxidant and was obtained from Tianjin Jinbei Fine-chemical Co. , Ltd (China).
Fig.1 shows that increasing residence time and reaction temperature had a positive effect on the TC and TOC removal during SCWO processes of 1% FA aqueous solution.
Fig.1 Effect of residence time on TC (a) and TOC (b) removal (P=25 MPa, α=2 and 1% FA) Effect of oxidation coefficient.
Table 1.
References [1] S.
Fig.1 shows that increasing residence time and reaction temperature had a positive effect on the TC and TOC removal during SCWO processes of 1% FA aqueous solution.
Fig.1 Effect of residence time on TC (a) and TOC (b) removal (P=25 MPa, α=2 and 1% FA) Effect of oxidation coefficient.
Table 1.
References [1] S.
Online since: November 2017
Authors: Alexandru Dimitriu, Olivera Lupescu, Mihail Nagea, Iulian Antoniac
By these reactions, the BAG (and particularly S53P4) have the following actions:
1.
Aureus in 3 cases, Acinetobacter baumanii in 1 case and Ps. aeruginosa in 1 case.
a b c Figure 1.
References [1] MN Rahaman, DE Day, BS Bal, Q Fu, SB Jung, LF Bonewald, et al, Bioactive glass in tissue engineering, Acta Biomaterialia. 7( 2011) 2355–73
Arkudas, A Balzer, G Buehrer, I Arnold, A Hoppe, R Detsch, et al, Evaluation of angiogenesis of bioactive glass in the arteriovenous loop model, Tissue Eng Part C Methods. 19 (2013) 479–86
Aureus in 3 cases, Acinetobacter baumanii in 1 case and Ps. aeruginosa in 1 case.
a b c Figure 1.
References [1] MN Rahaman, DE Day, BS Bal, Q Fu, SB Jung, LF Bonewald, et al, Bioactive glass in tissue engineering, Acta Biomaterialia. 7( 2011) 2355–73
Arkudas, A Balzer, G Buehrer, I Arnold, A Hoppe, R Detsch, et al, Evaluation of angiogenesis of bioactive glass in the arteriovenous loop model, Tissue Eng Part C Methods. 19 (2013) 479–86