浓悬浮液中纳米SiO2团聚体的渗透率

夏辉; 杨伟国

doi:10.7498/aps.65.144203

摘要

本文基于悬浮液中渗透性颗粒的短时扩散动力学理论, 采用低相干光纤动态光散射方法, 测量了相同粒径的纳米SiO2团聚体在不同体积分数时的扩散系数, 利用扩散系数随渗透率的变化关系得到纳米SiO2团聚体的渗透率. 结果表明: 恒温条件下, 具有一定渗透率的团聚体颗粒扩散得比硬球颗粒快. 实验测量得到的团聚体渗透率与采用photoshop CS6 对团聚体SEM图像进行处理计算得到的渗透率符合较好.

关键词:

The low coherence optical fiber dynamic light scattering method is used to measure the effective diffusion coefficients of nano SiO2 aggregates suspensions with different volume fractions. The single scattering component can be detected preferentially from the multiply scattered light which is backscattered from the dense suspensions by the low coherence optical fiber dynamic light scattering. Consequently, the measured single-scattering spectrum enables the analysis of the effective diffusion coefficient by the single scattering theory. The numerical calculation results of short-time diffusion dynamics for permeable particles in dense suspension show that the effective diffusion coefficient is a function of particle size and hydrodynamics shielding depth ratio , and the volum fraction . According to the corrected Brinkman theory, the permeability of the nano SiO2 aggregates is obtained. For the volume fraction = 0.01, 0.02, 0.03, 0.04, 0.05 nano SiO2 aggregate suspensions with the average particle diameter 500 nm, the measured effective diffusion coefficients are 4.140.10, 4.060.06, 3.970.06, 3.900.08, 3.800.10 (10-13 m2/s) respectively. While according to the hard sphere model of impermeable particles, which corresponds to = , the calculated effective diffusion coefficients are 3.70, 3.61, 3.52, 3.42, 3.36 (10-13 m2/s) respectively. It can be seen that the measured values are much bigger than the theoretical values of impermeable particles: their difference comes from the influence of permeability of porous aggregates on particle diffusion. It is found that the measured values are consistent with that of = 12, in which the corrsponding permeability of the nano SiO2 aggregates is k = 4.34 10-16 m2. The pixel statistic method by Photoshop CS6 is used to deal with the SEM images of SiO2 aggregates, the calculated permeability of the nano SiO2 aggregates is k = 4.55 10-16 m2, compared with the experimental result, the standard error is 4.87%. The results show that under the condition of constant temperature, the particles of permeable aggregates spread faster than the hard sphere particles. For constant temperature, particle size and permeability, the effective coefficient decreases with the increase of the volume fraction. The measured permeability of SiO2 aggregates in concentrated suspension is consistent with that obtained from the pixel statistics by Photoshop CS6. As a result, the low coherent optical fiber dynamic light scattering can effectively measure the permeability of porous nano particles in concentrated suspension, showing high potential application in the field of chemical engineering and nano materials preparation.

Keywords:

作者及机构信息

夏辉,
杨伟国

1.
中南大学物理与电子学院, 长沙 410083

通信作者: 夏辉, xhui73@csu.edu.cn

Authors and contacts

1.
School of Physics and Electronics, Central South University, Changsha 410083, China

Corresponding author: Xia Hui, xhui73@csu.edu.cn

参考文献

[1]	Gustavo C A, Bogdan C, Maria L E, Gerhard N, Eligiusz W 2010 J. Chem. Phys. 133 084906
[2]	Hijazi A, Atwi A, Khater A 2014 Inter. J. Comp. Theor. Eng. 6 401
[3]	Huang C L, Feng Y H, Zhang X X, Li W, Yang M, Li J, Wang G 2012 Acta Phys. Sin. 61 154402 (in Chinese) [黄丛亮, 冯妍卉, 张欣欣, 李威, 杨穆, 李静, 王戈 2012 物理学报 61 154402]
[4]	de la Mora M B, Bornacelli J, Nava R, Zanella R, Reyes-Esqueda J A 2014 J. Lumin. 146 247
[5]	Purnomo E H, van den Ende D, Vanapalli S A, Mugele F 2008 Phys. Rev. Lett. 101 238301
[6]	Dhont J K G 1996 An Introduction to Dynamics of Colloids (Amsterdam: Elsevier) pp327-329
[7]	Brene B J, Pecora R 1976 Dynamic Light Scattering (New York: John Wiley and sons) pp1-6
[8]	Xia H, Ishii K, Iwaii T, Li H J Yang B C 2008 Appl. Opt. 47 1257
[9]	Xia H, Miao C X, Cheng J W, Tao S H, Pang R Y, Wu X Y 2012 Appl. Opt. 51 3263
[10]	Xia H, Li H J, Yang B C, Ishii K, Iwai T 2008 Opt. Commun. 281 1331
[11]	Ishii K, Yoshida R, Iwai T 2005 Opt. Lett. 30 555
[12]	Zhong C, Chen Z Q, Yang W G, Xia H 2013 Acta Phys. Sin. 62 214207 (in Chinese) [钟诚, 陈智全, 杨伟国, 夏辉 2013 物理学报 62 214207]
[13]	Yang W G, Zhong C, Xia H 2014 Acta Phys. Sin. 63 214705 (in Chinese) [杨伟国, 钟诚, 夏辉 2014 物理学报 63 214705]
[14]	Brinkman H C 1949 Appl. Sci. Res. 1 27
[15]	Vanni M 2000 Chem. Eng. Sci. 55 685

施引文献

[1]	Gustavo C A, Bogdan C, Maria L E, Gerhard N, Eligiusz W 2010 J. Chem. Phys. 133 084906
[2]	Hijazi A, Atwi A, Khater A 2014 Inter. J. Comp. Theor. Eng. 6 401
[3]	Huang C L, Feng Y H, Zhang X X, Li W, Yang M, Li J, Wang G 2012 Acta Phys. Sin. 61 154402 (in Chinese) [黄丛亮, 冯妍卉, 张欣欣, 李威, 杨穆, 李静, 王戈 2012 物理学报 61 154402]
[4]	de la Mora M B, Bornacelli J, Nava R, Zanella R, Reyes-Esqueda J A 2014 J. Lumin. 146 247
[5]	Purnomo E H, van den Ende D, Vanapalli S A, Mugele F 2008 Phys. Rev. Lett. 101 238301
[6]	Dhont J K G 1996 An Introduction to Dynamics of Colloids (Amsterdam: Elsevier) pp327-329
[7]	Brene B J, Pecora R 1976 Dynamic Light Scattering (New York: John Wiley and sons) pp1-6
[8]	Xia H, Ishii K, Iwaii T, Li H J Yang B C 2008 Appl. Opt. 47 1257
[9]	Xia H, Miao C X, Cheng J W, Tao S H, Pang R Y, Wu X Y 2012 Appl. Opt. 51 3263
[10]	Xia H, Li H J, Yang B C, Ishii K, Iwai T 2008 Opt. Commun. 281 1331
[11]	Ishii K, Yoshida R, Iwai T 2005 Opt. Lett. 30 555
[12]	Zhong C, Chen Z Q, Yang W G, Xia H 2013 Acta Phys. Sin. 62 214207 (in Chinese) [钟诚, 陈智全, 杨伟国, 夏辉 2013 物理学报 62 214207]
[13]	Yang W G, Zhong C, Xia H 2014 Acta Phys. Sin. 63 214705 (in Chinese) [杨伟国, 钟诚, 夏辉 2014 物理学报 63 214705]
[14]	Brinkman H C 1949 Appl. Sci. Res. 1 27
[15]	Vanni M 2000 Chem. Eng. Sci. 55 685

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