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Journal of Shanghai University >

2019 , Vol. 25 >Issue 5: 754 - 766

DOI: https://doi.org/10.12066/j.issn.1007-2861.1954

Research Paper

Laser-induced aggregation of Rayleigh granular jets

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  • 1. Shanghai Institute of Applied Mathematics and Mechanics, Shanghai University, Shanghai 200072, China
    2. Key Laboratory of Mechanics in Energy Engineering, Shanghai University, Shanghai 200072, China
    3. School of Mechatronic Engineering and Automation, Shanghai University, Shanghai 200444, China
    4. Key Laboratory of Advanced Display and System Applications of Ministry of Education, Shanghai University, Shanghai 200444,China

Received date: 2017-05-22

  Online published: 2019-10-31

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Abstract

Dynamic convergence and stability characteristics of Rayleigh particle jets under laser irradiation are studied. Laser technology has widely applications in particle operation at micro-nano scales such as optical tweezers. While researches of particle behavior under laser irradiation generally focus on optical mapping and measurement of the particle population characteristics, laser-induced particle dynamical behaviors are rarely studied. Based on the analysis of granular gas dynamic simulation and the flow instability theory, the two cases of rarefied granular jet (point source) and granular jet are investigated. For point sources, that laser is effective in making the particle distribution more concentrated in the space by comparing with the classical vacuum deposition theory is found. In the case of granular jet, simulation and theoretical analysis show that the light scattering force can suppress instability of the long and short wavelengths, and effectively gather nanoparticles into jet.

Key words: optical tweezers; Rayleigh particle; granular jets; granular kinetics; flow-stability

Cite this article

Zhenyu NIU, Zhewei ZHOU, Kai HUANG, Jinsong ZHANG, Jianhua ZHANG, Zhiliang WANG . Laser-induced aggregation of Rayleigh granular jets[J]. Journal of Shanghai University, 2019 , 25(5) : 754 -766 . DOI: 10.12066/j.issn.1007-2861.1954

References

[1] Thoroddsen S T, Shen A Q . Granular jets[J]. Physics of Fluids, 2000,13(1):4-6.
[2] Shi Z H, Li W F, Qian W W , et al. Liquid-like granular film from granular jet impact[J]. Chemical Engineering Science, 2016,162:1-9.
[3] Sun K, Wei T, Ahn B Y , et al. 3D Printing of interdigitated Li-ion microbattery architec-tures[J]. Advanced Materials, 2013,25(33):4539-4543.
[4] Taylor A P, Velásquez-García L F . Electrospray-printed nanostructured graphene oxide gas sensors[J]. Nanotechnology, 2015,26(50):505301.
[5] Fuller S B, Wilhelm E J, Jacobson J M . Ink-jet printed nanoparticle microelectromechanical systems[J]. Journal of Microelectromechanical Systems, 2002,11(1):54-60.
[6] Huang Q J, Shen W F, Xu Q S , et al. Room-temperature sintering of conductive Ag films onpaper[J]. Materials Letters, 2014,123:124-127.
[7] Xiao S L, Shen M W, Guo R , et al. Immobilization of zerovalent iron nanoparticles into electrospun polymer nanofibers: synjournal, characterization, and potential environmental applications[J]. Journal of Physical Chemistry C, 2009,113(42):18062-18068.
[8] 花银群, 朱爱春, 陈瑞芳 , 等. 直流磁控溅射铝纳米颗粒膜的微结构及电学特性[J]. 功能材料, 2015,46(4):4071-4075.
[9] 余洁意, 黄昊, 高见 , 等. 直流电弧等离子体制备纳米SiC及其催化特性[J]. 无机材料学报, 2017(4):1-5.
[10] Ashkin A . Acceleration and trapping of particles by radiation pressure[J]. Physical Review Letters, 1970,24(4):156-159.
[11] Ashkin A . Atomic-beam deflection by resonance-radiation pressure[J]. Physical Review Letters, 1970,25(19):1321-1324.
[12] Ashkin A . Trapping of atoms by resonance radiation pressure[J]. Physical Review Letters, 1978,40(12):729-733.
[13] Ashkin A, Dziedzic J M, Bjorkholm J E , et al. Observation of a single-beam gradient force optical trap for dielectric particles.[J]. Optics Letters, 1986,11(5):288-290.
[14] Ren H L, Zhuang L H, Li Y M . Measurement of interaction potential between colloidal particles using dual optical tweezers[J]. Chinese Journal of Lasers, 2008,35(1):151-155.
[15] 王浩威, 刘晓辉, 李银妹 , 等. 应用光学微操作技术分选单条水稻染色体[J]. 生物物理学报, 2004,20(1):50-56.
[16] 黄凯, 王志亮, 周哲玮 , 等. 蒸发微粒气体对光的消光特性[J]. 上海大学学报(自然科学版), 2013,19(6):598-605.
[17] Harada Y, Asakura T . Radiation forces on a dielectric sphere in the Rayleigh scattering regime[J]. Optics Communications, 1996,124(5/6):529-541.
[18] Gouesbet G, Maheu B, Gréhan G . Light scattering from a sphere arbitrarily located in a Gaussian beam, using a Bromwich formulation[J]. Journal of the Optical Society of America A, 1988,5(9):1427-1443.
[19] 黄凯 . 光导颗粒气体射流理论研究[D]. 上海: 上海大学, 2013.
[20] 王涵 . 光导向颗粒气射流理论研究[D]. 上海: 上海大学, 2016.
[21] Plimpton S . Fast parallel algorithms for short-range molecular dynamics[J]. Journal of Computational Physics, 1995,117(1):1-19.
[22] 麻莳立男 . 薄膜制备技术基础 [M]. 北京: 化学工业出版社, 2009: 27-30.
[23] Noguchi H, Kikuchi N, Gompper G . Particle-based mesoscale hydrodynamic techniques[J]. Europhysics Letters, 2006,78(1):10005.
[24] Groot R D, Warren P B . Dissipative particle dynamics: bridging the gap between atomistic and mesoscopic simulation[J]. Journal of Chemical Physics, 1997,107:4423-4435.
[25] Israelachvili J N. Intermolecular and surface forces [M]. Pittsburgh: Academic Press, 2012.
[26] Hamaker H C . The London-van der Waals attraction between spherical particles[J]. Physica, 1937,4(10):1058-1072.
[27] Goldhirsch I . Rapid granular flows[J]. Annual Review of Fluid Mechanics, 2003,35(1):267-293.
[28] Brilliantov N V, Spahn F, Hertzsch J M , et al. Model for collisions in granulargases[J]. Physical Review E Statistical Physics Plasmas Fluids and Related Interdisciplinary Topics, 1996,53(5):5382-5392.
[29] Silbert L E, Erta? D, Grest G S , et al. Geometry of frictionless and frictional spherepackings[J]. Physical Review E Statistical Nonlinear and Soft Matter Physics, 2002,65(1):031304.
[30] Frenkel D. Understanding molecular simulation: from algorithms to applications [M]. Beijing: World Publishing Beijing Corporation, 2010: 74-77.
[31] Ohring M, Zarrabian S, Grogan A. Index---the materials science of thin films [M]. Pittsburgh: Academic Press, 2002: 87-90.
[32] 赵凯华, 罗蔚茵 . 新概念物理教程: 热学 [M]. 北京: 高等教育出版社, 2005: 66-73.
[33] Lun C . Kinetic theory for granular flow of dense, slightly inelastic, slightly rough spheres[J]. Journal of Fluid Mechanics, 1991,233:539-559.
[34] Drazin P G, Reid W H. Hydrodynamic stability [M]. Cambridge: Cambridge University Press, 2004.
[35] Moler C B, Stewart G W . An algorithm for generalized matrix eigenvalue problems[J]. Siam Journal on Numerical Analysis, 1973,10(2):241-256.
[36] Anderson J B, Fenn J B . Velocity distributions in molecular beams from nozzle sources[J]. 1965,8(5):780-787.
[37] Nathanson G M . Molecular beam studies of gas-liquid interfaces[J]. Annual Review of Physical Chemistry, 2004,55:231-255.
[38] Moseler M, Landman U . Formation, stability, and breakup of nanojets[J]. Science, 2000,289(5482):1165-1170.
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