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41 results on '"Cao, Ji-Lin"'

19. The Phase Diagram and the Application for the Quaternary System K+, NH4+//Cl−, SO42--H2O at 80.0 °C.

Author

Zhao, Xiao-Ling, Zhang, Hong-Qi, Zhao, Bin, Guo, Hong-Fei, and Cao, Ji-Lin

Subjects
PHASE diagrams, ATMOSPHERIC pressure, AMMONIUM, SOLID solutions, DISSOLUTION (Chemistry)
Abstract

The solubilities in the quaternary system K+, NH4+//Cl, SO42--H2O and its two ternary subsystems NH4Cl-KCl-H2O, (NH4)2SO4-K2SO4-H2O at 80.0 °C were measured using the isothermal dissolution equilibrium method under atmospheric pressure, and the corresponding phase diagrams were plotted. In the phase diagram of the NH4Cl-KCl-H2O system, there are three crystalline zones, which correspond to (K1−m,(NH4)m)Cl, ((NH4)n,K1−n)Cl and the co-existence zone of (K1−m,(NH4)m)Cl and ((NH4)n,K1−n)Cl, respectively. In the phase diagram of the (NH4)2SO4-K2SO4-H2O system, there is only one crystalline zone for (K1−t,(NH4)t)2SO4. In the phase diagram of the K+, NH4+//Cl, SO42--H2O system, there are three crystal zones, which correspond to (K1−t,(NH4)t)2SO4, (K1−m,(NH4)m)Cl and ((NH4)n,K1−n)Cl, respectively. According to the analysis and the calculations for the phase diagrams of the K+, NH4+//Cl, SO42--H2O system at 80.0 °C and 50.0 °C, this paper proposes a technological process. In the process, the (K1−t,(NH4)t)2SO4 can be prepared at 80.0 °C and the ((NH4)n,K1−n)Cl can crystallize out at 50.0 °C. The mass fraction of K2SO4 in product L1 (K1−t,(NH4)t)2SO4 (t = 0.1465) is 88.48%. The composition of solid solutions in the K+, NH4+//Cl, SO42--H2O system was experimentally determined and then theoretical calculations about the process can be carried out. [ABSTRACT FROM AUTHOR]

Published
2018
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34. Phase diagrams of Na2SO4–MgSO4–(NH4)2SO4–H2O system at 25°C and their application.

Author

Guo, Hong-Fei, Cao, Ji-Lin, Wang, Jing-Jie, Dou, Shuai-Yong, and Wang, Rui

Subjects
*MAGNESIUM compounds, *PHASE diagrams, *PHASE equilibrium, *NITROGEN compounds, *NITROGEN fertilizers, *ENERGY consumption
Abstract

Highlights: [•] Determination of phase equilibrium of Na2SO4–MgSO4–(NH4)2SO4–H2O system at 25°C. [•] Phase diagram of this system was investigated and analyzed. [•] A new technology to produce Mg–N compound fertilizers was proposed. [•] The advantage of recycling mother liquid, steady production and energy saving. [ABSTRACT FROM AUTHOR]

Published
2014
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36. Determination and Calculation of Phase Equilibriumfor Tetrahydrofuran + Sodium Sulfate + Magnesium Sulfate + Water Systemat 5 °C.

Author

Li, Guo-En, Cao, Ji-Lin, Chen, Pan-Pan, and Zhao, Bin

Subjects
*PHASE equilibrium, *TETRAHYDROFURAN, *SODIUM sulfate, *MAGNESIUM sulfate, *WATER analysis, *THERMODYNAMICS, *LEAST squares
Abstract

In order to develop a new processfor concentrating and separatingsodium sulfate (Na2SO4) and magnesium sulfate(MgSO4) of the bloedite based on tetrahydrofuran (THF)hydrate method, the equilibrium of the ternary systems THF–Na2SO4–H2O and THF–MgSO4–H2O and the quaternary system THF–Na2SO4–MgSO4–H2O were measured at 5 °C, and the phase digrams of these threesystems were investigated. It showed that the mass percentage of Na2SO4(MgSO4) in equilibrium liquid washigher than in feed and we could obtain Na2SO4·10H2O and MgSO4·7H2Oin turn. It proved that THF hydrate could be used to the concentrationand separation of Na2SO4and MgSO4. The extended Pitzer model of the electrolyte–electrolyte–nonelectrolyte–watersystem was derived and applied into THF–Na2SO4–MgSO4–H2O system andits subsystems. The necessary thermodynamic parameters had been derivedfrom a least-squares optimization program. The model calculation valuewas in good agreement with experimental solubility for ternary andquaternary mixtures, which indicated that the Pitzer model could besuccessfully used to predict the phase equilibrium of the electrolyte–electrolyte–nonelectrolyte–watersystems containning THF hydrate. [ABSTRACT FROM AUTHOR]

Published
2013
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37. Li0.95Na0.05Ti2(PO4)3/C with Good Performance as Anode Material for Aqueous Rechargeable Lithium Batteries

Author

Zhu, Jing, Liu, Yong Guang, Tian, Qing Qing, Wang, Ling, and Cao, Ji Lin

Abstract

Li0.95Na0.05Ti2(PO4)3/C nanocomposite was prepared by sol-gel method.The structure and morphology of the samples were characterized by XRD, SEM which showed the particles had typical NASICON structure and diameter range from 400~500nm. The electrochemical performance were tested by cyclic voltammetry and galvanostatic charge–discharge. Results show Li0.95Na0.05Ti2(PO4)3/C nanocomposite exhibitsmuch better electrochemical performance than bare Li0.95Na0.05Ti2(PO4)3.

Published
2014
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38. Phase Equilibrium Study on the Quaternary System H2O-Na2SO4-MgSO4-C3H8 at 0°C and Pressure

Author

Chen, Panpan, Li, Guoen, Guo, Hongfei, and Cao, Ji Lin

Abstract

In order to develop a new technology for separating the bloedite by the method of gas hydrate formation, the phase equilibrium of the H2O-Na2SO4-MgSO4-C3H8 system and its subsystems was studied at 0℃ and pressure.The equilibrium pressure and the composition of solid and liquid above system were investigated.It was found that equilibrium pressure of gas hydrate formation was increasing with the increase of the Na2SO4( or MgSO4) concentration. The addition of anionic surfactant SDS helped to lower the equilibrium pressure of gas hydrate formation. The mother liquor amount entrained in the gas hydrate after liquid separation by sinking was very high when surfactants was not added. But the equilibrium pressure of gas hydrate formation and the mother liquor amount entrained in gas hydrate were decreased when surfactant was added to the system.

Published
2012
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39. Equilibrium Studies on the System H2O-H2O2-CO(NH2)2-C3H8

Author

Gao, Yu Ming, Cao, Ji Lin, Chen, Pan Pan, Guo, Hong Fei, and Tan, Zhao Yang

Abstract

The phase equilibrium of the quaternary system H2O-H2O2-CO(NH2)2-C3H8 with gas hydrate formation had been studied at high pressure and low temperature. The temperature and pressure of gas hydrate formed from different hydrogen peroxide concentration aqueous were determined at adding surfactants and no surfactants separately. It was concluded that the equilibrium pressure of gas hydrate formation was increasing with the increase of the hydrogen peroxide concentration, the urea concentration and the temperature, the mother liquor amount entrained in the gas hydrate after liquid separation by sinking was very high when surfactants was not added, but the equilibrium pressure of gas hydrate formation was decreased and the mother liquor amount entrained in gas hydrate was also decreased when surfactants was added to the system. In addition, the equilibrium pressure of gas hydrate formation in the quaternary system H2O-H2O2-CO(NH2)2-C3H8 was calculated according to Chen-Guo thermodynamic model, improved UNIFAC mathematical equation and Aasberg-Peterson fugacity coefficient model. The calculated data was in agreement with the experiment data.

Published
2011
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40. Optimization of Synthesis Condition for LiFePO4/C Cathode Material

Author

Zhu, Ling Zhi, Han, En Shan, and Cao, Ji Lin

Abstract

This template explains and demonstrates how to prepare your camera-ready paper for Trans Tech Publications. The best is to read these instructions and follow the outline of this text. Common and cheap organic matters (Glucose anhydrous, Citric acid, Vitamin C, Sucrose) were selected for carbon coatings on LiFePO4. The four pre-treatment processes were employed to optimize the carbon coating process, and through solid state-carbothermal reduction synthesis of LiFePO4/C composites. The structure, morphology and electrochemical performance of the material were studied by XRD, SEM and galvanostatic charge-discharge methods. It is observed that the tap density of citric acid coating material can reach 1.44 g/ml. Conductivity increased four orders of magnitude. At room temperature, the initial discharge specific capacity of the materials is as high as 89.6 mAh/g at 5.0 C (corresponding to 850 mA/g). After 30 cycles, the capacity is 83.9 mAh/g and decay only 2.0 %.

Published
2011
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41. Phase diagrams of the quaternary system Mg2+, NH4+//Cl−, SO42− in water at 25 °C and their application.

Author

Dou, Shuai-Yong, Zhao, Bin, and Cao, Ji-Lin

Subjects
*PHASE diagrams, *MAGNESIUM chloride, *AMMONIUM sulfate, *AMMONIUM chloride, *NITROGEN fertilizers
Abstract

Based on the requirement of the new technology for producing Mg–N compound fertilizer by the reaction of MgCl 2 and (NH 4 ) 2 SO 4 , the phase equilibrium of the quaternary system Mg 2+ , NH 4 + //Cl − , SO 4 2− –H 2 O at 25 °C was studied. The solubilities of the quaternary system Mg 2+ , NH 4 + //Cl − , SO 4 2− –H 2 O were measured using isothermal method, and the phase diagram of this system was investigated. According to the phase diagram, there are nine solid phase crystalline zones, which correspond to MgSO 4 ·7H 2 O, MgSO 4 ·6H 2 O, MgSO 4 ·5H 2 O, MgSO 4 ·4H 2 O, (NH 4 ) 2 SO 4 , MgSO 4 ·(NH 4 ) 2 SO 4 ·6H 2 O, MgCl 2 ·6H 2 O, NH 4 Cl and MgCl 2 ·NH 4 Cl·6H 2 O respectively. MgSO 4 ·(NH 4 ) 2 SO 4 ·6H 2 O has the largest crystalline zone among these crystalline zones, which indicates that the double salt MgSO 4 ·(NH 4 ) 2 SO 4 ·6H 2 O is the easiest to crystallize out. Based on the analysis and calculation of the phase diagrams, the suitable conditions for the new technology were determined. The extended Pitzer model was derived and applied to the phase equilibrium calculation of system Mg 2+ , NH 4+ //Cl − , SO 4 2 –H 2 O and its sub-systems at 25 °C. The results showed that the calculated values were consistent with experimental results well. [ABSTRACT FROM AUTHOR]

Published
2015
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