[1] Z.G.Qu, X.J.Xu, T.S.Wang, W.Q.Tao, T.J.Lu. Thermal transport in metallic porous media (Chapter 8), Heat Transfer – Engineering Application, edited by Vyacheslav S. Vikhrenko. ISBN 979-953-307-656-9, Intech Publisher.

[2] Z. Liu, J. Hu, Z.G.Qu, F. Xu, Paper-based immunoassays (Chapter 8), Handbook of ImmunoassayTechnologies: Approaches, Performances, and Applications. edited by S. Vashist, J. Luong. ISBN:9780128117620. San Diego, California: Academic Press; 2018.

[1] Z.Y. Jiang, Z.G. Qu*. Lithium-ion battery thermal management using heat pipe and phase change material during discharge-charge cycle: A comprehensive numerical study. Applied Energy, 2019, 242: 378-392 [2] H. Wang, J.Q. Bai *, Z.G. Qu*, M. Chang. Numerical study of heat transfer in process of gas adsorption in a Cu-benzene- 1, 3, 5-tricarboxylic acid particle adsorption bed. International Journal of Hydrogen Energy, 2019, 44:11989-12002 [3] X.H. Zhang, Z.G. Qu*, D. Tian, Y. Fang. Acoustic characteristics of continuously graded phononic crystals. Applied Acoustics, 2019, 151: 22-29 [4] J.J. Zhang, Z.G. Qu*, A. Maharjan. Numerical investigation of coupled optical-electrical-thermal processes for plasmonic solar cells at various angles of incident irradiance. Energy, 2019, 174 :110-121 [5] S. Wang, J.G. Qu, L.J. Kong, J.F. Zhang*, Z.G. Qu. Numerical and experimental study of heat-transfer characteristics of needleto-ring-type ionic wind generator for heated-plate cooling. International Journal of Thermal Sciences, 2019, 139: 176-185 [6] Z.G. Qu*, Z.Y. Jiang, Q. Wang. Experimental study on pulse self–heating of lithium–ion battery at low temperature. International Journal of Heat and Mass Transfer, 2019, 135: 696-705 [7] Y. Yin, Z.G. Qu*, J.F. Zhang. Pore-scale prediction of the effective mass diffusivity of heterogeneous shale structure using the lattice Boltzmann method. International Journal of Heat and Mass Transfer, 2019, 133: 976-985. [8] L. Zhou, Z.G. Qu*, G. Chen, J.Y. Huang, J.Y. Miao. One-dimensional numerical study for loop heat pipe with two-phase heat leak model. International Journal of Thermal Sciences. International Journal of Thermal Sciences, 2019, 137:461-487 [9] H.T. Xu, Z.Q. Luo, N. Wang, Z.G. Qu*, J. Chen, L. An. Experimental study of the selective catalytic reduction after-treatment for the exhaust emission of a diesel engine. Applied Thermal Engineering, 2019, 147: 198-204. [10] J. F. Zhang, S. Wang, M. J. Zeng, Z.G.Qu*. Experimental and numerical investigation on flow characteristics of large cross-sectional ionic wind pump with multiple needles-to-mesh electrode. Journal of Fluids Engineering, 2019, 141: 031105 [11] H. Wang, Z.G. Qu*, Y. Yin, J.Q. Bai, B. Yu, Review of Molecular Simulation Method for Gas Adsorption/desorption and Diffusion in Shale Matrix, Journal of thermal sciences, 2019, 28 (1): 1-16. [12] Jin-Ping Wang, Jian-Fei Zhang*, Zhi-Guo Qu*, Wen-Quan. Tao Adaptive inner iteration processes in pressure-based method for viscous compressible flows. Numerical Heat Transfer, Part B: Fundamentals, 2018, 74(3): 603–622 [13] Zhi Liu, Xiaocong He, Jiaxiu Han, Xiuhai Zhang, Fei Li, Ang Li, Zhiguo Qu*, Feng Xu. Liquid wicking behavior in paper-like materials: Mathematical models and their emerging biomedical applications, Microfluidics and Nanofluidics, 2018, 22(110): 132 [14] Xueliang Wang, Xin Wang, Miao Liu, Martin A. Crimp, Yaping Wang, Zhiguo Qu*. Anisotropic thermal expansion coefficient of multilayer graphene reinforced copper matrix composites. Journal of Alloys and Compounds, 2018, 755: 114-122. [15] Liqiang Ren, Shujie Yang, Peiran Zhang, Zhiguo Qu*, Zhangming Mao, Po-Hsun Huang, Yuchao Chen, Mengxi Wu, Lin Wang, Peng Li, and Tony Jun Huang*. Standing Surface Acoustic Wave (SSAW)-Based Fluorescence-Activated Cell Sorter. Small 2018, 14, 40: 1801996 [16] Hongtao Xu, Yubo Miao, Ning Wang, Zhiguo Qu*, Xichun Wang. Experimental investigations of heat transfer characteristics of MPCM during charging. Applied Thermal Engineering, 2018,144: 721-725 [17] Z.G. Qu*, G. Chen, L. Zhou, J.Y. Miao. Numerical study on the operating characteristics of cryogenic loop heat pipes based on a one-dimensional heat leak model. Energy Conversion and Management, 2018, 172: 485-496. [18] J. Guo, Z.G. Qu*. Thermal cloak with adaptive heat source to proactively manipulate temperature field in heat conduction process. International Journal of Heat and Mass Transfer 2018, 127: 1212-1222. [19] Z. Liu, Z.G. Qu*, R.H. Tang, X.C. He, H. Yang, D. Bai, F. Xu*. An improved detection limit and working range of lateral flow assays based on a mathematical model. Analyst, 2018, 143(12): 2775-2783 [20] J.F. Zhang, S. Wang, H.Y. Li, Z.G. Qu*. Parametric study and optimization of flow characteristics of wire-nonparallel plate-type electrostatic air accelerators. Journal of Fluids Engineering, 2018, 140(10), 101105. [21] H. Wang, Z.G. Qu*, J.Q. Bai, Y.S. Qiu. Combined grand canonical Monte Carlo and finite volume method simulation method for investigation of direct air capture of low concentration CO2 by 5A zeolite adsorbent bed. International Communications in Heat and Mass Transfer , 2018, 126: 1219–1235 [22] Z.Y. Jiang, Z.G. Qu*, L. Zhou. Lattice Boltzmann simulation of ion and electron transport during the discharge process in a randomly reconstructed porous electrode of a lithium-ion battery. International Journal of Heat and Mass Transfer, 2018, 123: 500–513. [23] Q. Wang, Z.G. Qu*, Z.Y. Jiang, W.W. Yang. Numerical study on vanadium redox flow battery performance with non-uniformly compressed electrode and serpentine flow field. Applied Energy, 2018, 220: 106-116. [24] H. Wang, Z.G. Qu*, L. Zhou. Coupled GCMC and LBM simulation method for visualizations of CO2/CH4 gas separation through Cu-BTC membranes. Journal of Membrane Science, 2018, 550: 448-461 [25] Z.G. Qu*, Y.D. Fu, Y. Liu, L. Zhou. Approach for predicting effective thermal conductivity of aerogel materials through a modified lattice Boltzmann method. Applied Thermal Engineering, 2018, 132: 730-739. [26] X.B. Feng, Z.G. Qu*. Methane combustion with cobalt-substituted barium-lanthanum hexaaluminate catalysts supported on porous monolithic honeycombs[J]. Journal of Energy Engineering, 2018,144(3): 04018015. [27] Q. Wang, Z.G. Qu*, Z.Y. Jiang, W.W. Yang. Experimental study on the performance of a vanadium redox flow battery with non-uniform compressed carbon felt electrode. Applied Energy, 2018, 213: 293-305. [28] H. Wang, Z.G. Qu*, L. Zhou. A combined GCMC and LBM simulation method for CH4 capture in Cu-BTC particle adsorption bed. International Communications in Heat and Mass Transfer, 2017, 88:48-53. [29] Z.Y. Jiang, Z.G. Qu*, L. Zhou, W.Q. Tao. A microscopic investigation of ion and electron transport in lithium-ion battery porous electrodes using the lattice Boltzmann method. Applied Energy, 2017, 194: 530-539. [30] Y. Yin, Z.G. Qu*, J.F. Zhang. An analytical model for shale gas transport in kerogen nanopores coupled with real gas effect and surface diffusion. Fuel, 2017, 210: 569-577. [31] M. Mohib Ur Rehman, Z.G. Qu*, R. P. Fu. Numerical study on free-surface jet impingement cooling with nanoencapsulated phase-change material slurry and nanofluid, International Journal of Heat and Mass Transfer, 2017, 109: 312-325. [32] H.T. Xu, T.T. Wang, Z.G. Qu*, J. Chen, B.B. Li. Lattice Boltzmann simulation of the double diffusive natural convection and oscillation characteristics in an enclosure filled with porous medium. International Communications in Heat and Mass Transfer. 2017, 81: 104–115. [33] H.T. Xu, X.W. Liao, Z.G. Qu*, Y.Z. Li, J. Chen. Experimental study of the effect of a radiant tube on the temperature distribution in a horizontal heating furnace. Applied Thermal Engineering. 2017, 113: 1-7. [34] Y. Fang, Z.G. Qu*, Y.D. Fu. Experimental study of the thermal characteristics of microencapsulated phase change composite cylinders. Applied Thermal Engineering. 2017, 114, 1256–1264. [35] X.C. He, Z.G. Qu*, Feng Xu; Simulation study of interaction mechanism between peptide and asymmetric membrane, Molecular Simulation. 2017, 43(1): 34-41. [36] Z. Liu, J. Hu, A. Li, S. S. Feng, Z.G Qu*, F. Xu, The effect of report particle properties on lateral flow assays: A mathematical model, Sensors and Actuators B: Chemical, 248 (2017) 699-707. [37] H.B. Gao, X.B. Feng, Z.G. Qu*, Combustion in a Hybrid Porous Burner Packed with Alumina Pellets and Silicon Carbide Foams with a Gap, Journal of Energy Engineering, 143(5), 2017, 04017032. [38] Z. G. Qu*, H. Wang, W. Zhang, Highly efficient adsorbent design using a Cu-BTC/CuO/ carbon fiber paper composite for high CH4/N2 selectivity, [J]. RSC Advances, 2017, 7, 14206-14218. [39] Wang Shuang, Zhang Jianfei, Kong Lingjian, Qu Zhiguo, Tao Wenquan. An numerical investigation on the cooling capacity of needle-ring type electrostatic fluid accelerators for round plate with uniform and non-uniform heat flux. International Journal of Heat and Mass Transfer, 2017, 113, 1-5. [40] Z.D. Li, F. Li, Y. Xing, Z. Liu, M.L. You, Y.C. Li, T. Wen, Z.G. Qu, X.L. Li, F. Xu, Pen-on-Paper Strategy for Point-of-Care Testing: Rapid Prototyping of Fully Written Microfluidic Biosensor, Biosensors and Bioelectronics, 98 (2017) 478-485. [41] R.H. Tang, H. Yang, Y. Gong, Z. Liu, X.J. Li, T. Wen, Z.G. Qu, S.F. Zhang, Q.B. Mei, F. Xu, Improved Analytical Sensitivity of Lateral Flow Assay using Sponge for HBV Nucleic Acid Detection, Scientific Reports, 7(1) (2017) 1360. [42] R.H. Tang, H. Yang, Y. Gong, M.L. You, Z. Liu, J. R. Choi, T. Wen, Z.G. Qu, Q.B. Mei, F. Xu, A Fully Disposable and Integrated Paper-based Device for Nucleic Acid Extraction, Amplification and Detection, Lab on a Chip, 17(7) (2017) 1270-1279. [43] Liu H, Yu QN*, Qu ZG, Yang RZ. Simulation and analytical validation of forced convection inside open cell metal foams, International Journal of Thermal Sciences, 2017, 111:234-245. [44] Z.G. Qu*, A. Li, W.Q. Tao. A numerical study of film condensation on a metallic foam-sintered plate with considering convection and super-cooling effects. International Communications in Heat and Mass Transfer, 2016, 79: 105-113. [45] X.H. Zhang, Z.G. Qu*, X.C. He, et al. Experimental study on the sound absorption characteristics of continuously graded phononic crystals. AIP Advances, 2016, 6(10): 105205. [46] X.B. Feng, Z.G. Qu*. Lean methane premixed combustion over a catalytically stabilized zirconia foam burner. International Journal of Green Energy, 2016 13(14): 1451-1459. [47] M. Mohib Ur Rehman, Z.G. Qu*, R. P. Fu. Three-dimensional numerical study of laminar confined slot jet impingement cooling using slurry of nano-encapsulated phase change material. Journal of Thermal Science. 2016，25(5): 431-439. [48] X.B. Feng, Z.G.Qu*, H.B.Gao, Premixed lean methane/air combustion in a catalytic porous foam burner supported with perovskite LaMn0.4Co0.6O3catalyst with different support materials and pore densities, Fuel Processing Technology, 2016, 150: 117-125. [49] J.J. Zhang, Z.G.Qu*, Y. Liu. Numerical study on the melting thermal characteristics of a microencapsulated phase change plate. Numerical Heat Transfer Part A, 2016, 70 (4): 399-419. [50] H. Wang, Z.G.Qu*, W. Zhang, L. Q. Zhang. A multi-scale porous composite adsorbent with copper benzene-1,3,5-tricarboxylate coating on copper foam. RSC Advances, 2016, 6: 52888-52897. [51] H Liu, QN Yu*, ZC Zhang, ZG Qu, CZ Wang. Analytical solutions for heat transfer efficiency in metallic honeycombs using two-equation method. International Communications in Heat and Mass Transfer, 2016, 75:147-153. [52] J. R. Choi, Z. Liu, J. Hu, R. Tang, Y. Gong, S. Feng, H. Ren, W. Ting, Y. Hui, Z. G. Qu, B. Pingguan-Murphy, F. Xu, Polydimethylsiloxane-Paper Hybrid Lateral Flow Assay for Highly Sensitive Point-of-Care Nucleic Acid Testing, Analytical Chemistry, 2016, 88(12): 6254-6264 [53] H. Liu, Q.N. Yu, Z.C. Zhang, Z.G. Qu, C.Z. Wang. Two-equation method for heat transfer efficiency in metal honeycombs: An analytical solution. International Journal of Heat and Mass Transfer, 2016, 97(201-210). [54] L. Zhou, Z.G. Qu*, T. Ding, J.Y. Miao, Lattice Boltzmann simulation of the gas-solid adsorption process in reconstructed random porous media, Physical Review E, 2016, 93, (4) : 043101 [55] X.C. He, M. Lin, J. Guo, Z. G. Qu*, Feng Xu, Experimental and simulation studies of polyarginines across the membrane of giant unilamellar vesicles, RSC Advances, 2016, 6(36): 30454-30459. [56] H. B. Gao, G. H. Huang, H. J. Li, J. Li, Z.G.. Qu*, Y. J. Zhang, Development of Stove-powered Thermoelectric Generator: A review, Applied Thermal Engineering, 2016, 96:297-310 [57] H. Wang, Qu, Z.G.*, Zhang W., Yu, Q.N., He Y.L. Experimental and numerical study of CO2 adsorption on copper benzene-1,3,5-tricarboxylate (Cu-BTC) metal organic framework. Int J of Heat and Mass Transfer, 2016, 92: 859-863 [58] Z.B. Liu, Y.L. He, Y.S. Li, Z.G. Qu, W.Q. Tao, Heat transfer characteristics of supercritical CO2 flow in metal foam tubes, Journal of Supercritical Fluids, 101 (2015) 36-47. [59] Z.B. Liu, Y.L. He, Z.G. Qu, W.Q. Tao, Experimental study of heat transfer and pressure drop of supercritical CO2 cooled in metal foam tubes, International Journal of Heat and Mass Transfer, 85 (2015) 679-693. [60] W.T. Ji, Z.Y. Li, Z.G. Qu, J.F. Guo, D.C. Zhang, Y.L. He, W.Q. Tao, Film condensing heat transfer of R134a on single horizontal tube coated with open cell copper foam, Applied Thermal Engineering, 76 (2015) 335-343. [61] H.R. Liu, M. Azarpeyvand, J.J. Wei, Z.G. Qu, Tandem cylinder aerodynamic sound control using porous coating, Journal of Sound and Vibration, 334 (2015) 190-201. [62] X.C. He, M. Lin, T.J. Lu, Z.G. Qu*, F. Xu, Molecular analysis of interactions between PAMAM dendrimer-paclitaxel conjugate and biomembrane, Physical Chemistry Chemical Physics, 2015, 17(44):29507-29517. [63] H. Wang, Z.G. Qu*, W. Zhang, W.Q. Tao. Effective thermal conductivity of MOF-5 powder under a hydrogen atmosphere. Computation, 2015, 3, 558-573. [64] Xiaocong He, Min Lin, Baoyong Sha, Shangsheng Feng, Xinghua Shi, Zhiguo Qu*, Feng Xu; Coarse-grained molecular dynamics studies of the translocation mechanism of polyarginines across asymmetric membrane under tension, Scientific Reports, 2015,5:12808. [65] Z. G. Qu*, Y. H. Bai, and L. Pu, One-dimensional numerical study of thermal performance of an organic Rankine cycle system using liquefied natural gas as a cold source for cold energy recovery, Journal of Natural Gas Science and Engineering, 2015, 26: 1399–1413. [66] L. Zhou, Z. G. Qu*, L.Chen, W.Q.Tao, Lattice Boltzmann simulation of gas–solid adsorption processes at pore scale level, Journal of Computational Physics, 2015, 300: 800-813 [67] W.Q. Li, Z.G. Qu*, Experimental study of effective thermal conductivity of stainless steel fiber felt , Applied Thermal Engineering, 2015,86:119-126. [68] Z. G. Qu*, X. B. Feng. Catalytic combustion of premixed methane/air in a two-zone perovskite-based alumina pileup-pellets burner with different pellet diameters. Fuel 2015; 159: 128–140. [69] Z.G. Qu*, W.Q. Li, J.J. Zhang, W.Q. Tao, Numerical study of heat conduction with a chemical reaction at the moving frontal surface for a graphite plate, Numerical Heat Transfer, Part A, 2015,67(2): 189-209. [70] Zhiguo Qu*, Huaibin Gao, Xiangbo Feng, and Wenquan Tao, Premixed combustion in a porous burner with different fuels, Combustion Science and Technology, 2015, 187(3): 489-504. [71] Xiao Cong He, Min Lin, Fei Li, BaoYong Sha, Feng Xu, Zhiguo Qu*, Wang Lin, Advances in studies on nanoparticle-biomembrane interactions, Nanomedicine, 2015, 10(1): 121-141. [72] J. J. Zhang, Z.G. Qu*, R.P. Fu, Y. L.He, Experimental study on the transient thermal characteristics of an integrated deflector under the periodic impingement of a supersonic flame jet, International Journal of Heat and Mass Transfer, 2015.85: 811-823. [73] J.J. Zhang, Z.G. Qu*, R.P Fu, W.Q.Tao, Part II: Numerical study on the flow and thermal characteristics of an integrated deflector under the periodic impingement of a supersonic high temperature jet, International Journal of Heat and Mass Transfer, 2015, 85:1095-1111. [74] Liu Zhi, Hu Jie, Zhao Yimeng, Qu Zhiguo*, Xu Feng*, Experimental and numerical studies on liquid wicking into filter papers for paper-based diagnositcs, Applied Thermal Engineering, 2015,88:280-287. [75] JiaJie Zhang, ZhiGuo Qu*, HuiJin Xu, WenQuan Tao. Semi-analytical solution for fully developed forced convection in metal-foam filled tube with uniform wall temperature. Science China-Technological Sciences, 2014, 57(12): 2487-2499. [76] H .Wang, Z.G. Qu*, W. Zhang, Y.X. Chang, Y. L. He. Experimental and numerical study of CO2 adsorption on Ni/DOBDC metal-organic framework. Applied Thermal Engineering, 2014,73: 1501-1509 [77] Zhi Guo Qu, Hui Wang, Wen Zhang*, Liang Zhou, Ying Xin Chang. Prediction and experimental verification of CO2 adsorption on Ni/DOBDC using a genetic algorithm-back- propagation neural network model. Industrial & Engineering Chemistry Research, 2014,53 (30): 12044-12053. [78] Z.G. Xu, Z.G.Qu*, C.Y. Zhao, W.Q. Tao, Experimental correlation for pool boiling heat transfer on metallic foam surface and bubble cluster growth behavior on grooved array foam surface, International Journal of Heat and Mass Trasnfer, 2014, 77 :1169-1182. [79] J. J. Zhang，Z. G. Qu*，Z.G. Jin，Experimental study on the thermal characteristics of a microencapsulated phase-change composite plate，Energy，2014，71：94-103. [80] XiaoCong He, ZhiGuo Qu,* Feng Xu, Min Lin, JiuLing Wang, XingHua Shi, TianJian Lu, Molecular analysis of interactions between dendrimers and asymmetric membranes at different transport stages, Soft Matter, 2014,10(1): 139-148 [81] H.J. Xu, Z.G. Qu*, W.Q. Tao, Numerical investigation on self-coupling heat transfer in a counter-flow double-pipe heat exchanger filled with metallic foams, Applied Thermal Engineering, 2014, 66:43-54 [82] Wenqiang, Li, ZhiGuo Qu* , Yaling He, Yubing Tao, Experimental study of a passive thermal management system for high-powered lithium ion batteries using porous metal foam saturated with phase change materials, Journal of Power Sources, 2014, 255:9-15. [83] Z.G. Qu*, W.Q.Li, W.Q. Tao, Numerical model of the passive thermal management system for high-power lithium ion battery by using porous metal foam saturated with phase change material, International Journal of Hydrogen Energy, 2014,39(8): 3904-3913 [84] H. B. Gao, Z. G. Qu*, X. B. Feng, W. Q. Tao, Methane/air premixed combustion in a two-layer porous burner with different foam materials，Fuel, 2014,115: 154-161 [85] H. B. Gao, Z. G. Qu*, X. B. Feng, W. Q. Tao, Combustion of methane/air mixtures in a two-layer porous burner: A comparison of alumina foams, beads, and honeycombs, Experimental Thermal and Fluid Science, 2014,52:215-220 [86] L. Pu, Z.G. Qu*, Y.H. Bai, D. Qi, K. Song, P. Yi, Thermal performance analysis of intermediate fluid vaporizer for liquefied natural gas, Applied Thermal Engineering, 2014, 65: 564-574. [87] Adem Ozcelik, Daniel Ahmed, Yuliang Xie, Nitesh Nama, Zhiguo Qu, Ahmad Ahsan Nawaz, Tony Jun Huang, An acoustofluidic micromixer via bubble inception and cavitation from microchannel sidewalls, Analytical Chemistry, 2014, 86 (10), 5083–5088. [88] Jin-Ping Wang, Jian-Fei Zhang*, Zhi-Guo Qu, Ya-Ling He, Wen-Quan Tao, Comparison of robustness and efficiency for SIMPLE and CLEAR algorithms with 13 High-resolution convection schemes in compressible flows, Numerical Heat Transfer, Part B, 2014, 66(2) : 133-161. [89] J.F. Zhang, J.P. Wang, Z.G. Qu, Y.L. He, W.Q. Tao, The study of different discretized schemes for density and convection terms in high speed compressible flow using the pressure-based method, Applied Thermal Engineering, 73 (2014) 1533-1540. [90] C Wei, Z. J. Liu, Z. Y. Li, Z. G. Qu, Y. L. He, W. Q. Tao, Numerical study on some improvements in the passive cooling system of a radio base station base on multiscale thermal modeling methodology-Part I: Confirmation of simplified models, Numerical Heat Transfer, Part A-Applications,2014, 65 (9): 844-862. [91] C Wei, Z. J. Liu, Z. Y. Li, Z. G. Qu, Y. L. He, W. Q. Tao, Numerical study on some improvements in the passive cooling system of a radio base station base on multiscale thermal modeling methodology-Part II: Results of multiscale numerical simulation and subsequent improvements of cooling techniques, Numerical Heat Transfer, Part A-Applications , 2014, 65 (9): 863-884. [92] H. R. Liu, J. J. Wei, Z. G. Qu, The interaction of porous material coating with the near wake of bluff body, ASME Journal of Fluids Engineering, 2014, 136 (2): 021302. [93] BaoYong Sha, Wei Gao, ShuQi Wang, Xingchun Guo, Wei Li, Xuan Liang, ZhiGuo Qu, Feng Xu, TianJian Lu，Oxidative stress increased hepatotoxicity induced by nano-titanium dioxide in BRL-3A cells and Sprague-Dawley rats，Journal of Applied Toxicology, 2014，34 (4): 345-356 [94] ZhiGuo Qu, XiaoCong He, Min Lin, BaoYong Sha, XingHua Shi, TianJian Lu, Feng Xu*; Advances in the understanding of nanomaterial-biomembrane interactions and numerical modeling, Nanomedicine, 2013,8(6),995-1011 [95] Z.G. Qu*, H.J. Xu and W.Q. Tao, Conjugated natural convection in horizontal annuli partially filled with metallic foams by using two-equation model, J of Porous Media, 2013, 16 (11):979-995. [96] W.Q. Li, Z.G. Qu*，B.L. Zhang, K. Zhao, W.Q. Tao, Thermal behavior of porous stainless-steel fiber felt saturated with phase change material，Energy, 2013，55:846-852. [97] Huai-Bin Gao, Zhi-Guo Qu*, Wen-Quan Tao, Yaling He, Experimental investigation of methane/(Ar, N2, CO2)-air mixture combustion in a two-layer packed bed burner, Experimental Thermal and Fluid Science, 2013,44: 599–606. [98] Zhiguo Xu, Zhiguo Qu*, Changying. Zhao, Wenquan. Tao, Experimental study of pool boiling heat transfer on metallic foam surface with U-shaped and V-shaped grooves， Journal of Enhanced Heat Transfer. 2012,19(6):549-559. [99] Gao, Huaibin; Qu, Zhiguo*, Yaling He, Tao Wenquan, Experimental study of combustion in a double-layer burner packed with alumina pellets of different diameters, Applied Energy, 2012, 100: 295–302. [100] Z. G. Qu*, H.J.Xu, W.Q.Tao, Fully developed forced convective heat transfer in an annulus partially filled with metallic foams: An analytical solution, International Journal of Heat and Mass Transfer, 2012, 55(25-26): 7508–7519. [101] Zhiguo Qu*, Tiansong Wang, Wenquan Tao, Tianjian Lu, Experimental study of air natural convection on metallic foam-sintered plate, International Journal of Heat and Fluid Flow, 2012, 38: 126–132. [102] Z.G. Qu*, W. Q. Li, J.L. Wang, W.Q. Tao. Passive thermal management using metal foam saturated with phase change material in a heat sink. International Communications in Heat and Mass Transfer. 2012, 39 (10): 1546–1549. [103] Z. G. Qu* , T. S. Wang, W. Q. Tao, T. J. Lu, A theoretical octet-truss lattice unit cell model for effective thermal conductivity of consolidated porous materials saturated with fluid, Heat and Mass Transfer, 2012, 48(8): 1385-1395. [104] Z. G. Qu*, H. J. Xu, W.Q. Tao, Numerical simulation of non-equilibrium conjugate heat transfer in tubes partially filled with metallic foams, Journal of Thermal Science and Technology, 2012, 7 (1): 151-165. [105] Z.G. Qu*, Z.G. Xu, C.Y. Zhao, W.Q. Tao, Experimental study of pool boiling heat transfer on horizontal metallic foam surface with crossing and single-directional V-shaped groove in saturated water, International Journal of Multiphase Flow, 2012,41: 44-45. [106] Z.G. Qu*, D. G. Li, J. Y. Huang, Z. G. Xu, X. L. Liu, W. Q. Tao, Experimental investigations of pool boiling heat transfer on horizontal plate sintered with metallic fiber felt, International Journal of Green Energy, 2012，9(1): 22–38. [107] W.Q.Li, Z.G. Qu*, Y.L. He, and W.Q. Tao, Experimental and numerical studies on melting phase change heat transfer in open-cell metallic foams filled with paraffin, Applied Thermal Engineering, 2012,37:1-9. [108] Hanru Liu, Jinjia Wei, Zhiguo Qu, Prediction of aerodynamic noise reduction by using open-cell metal foam, Journal of Sound and Vibration, 2012, 331(7): 1483-1497. [109] Y.P. Du, C.Y. Zhao*, Y. Tian., Z. G. Qu, Analytical considerations of flow boiling heat transfer in metal-foam filled tubes, Heat and Mass transfer，2012，48(1):165-173. [110] Tao YB, He YL, Qu ZG. Numerical study on performance of molten salt phase change thermal energy storage system with enhanced tubes, Solar Energy, 2012, 86(5): 1155-1163 [111] Li XY, Yang WW, He YL, Zhao TS, Qu ZG. Effect of anode micro-porous layer on species crossover through the membrane of the liquid-feed direct methanol fuel cells, Applied Thermal Engineering, 2012,48:392-401 [112] Wei C, Liu ZJ, Li ZY, Qu ZG, Tao WQ. Numerical study on some improvements in the passive cooling system of a radio base station. Numerical Heat Transfer Part A, 2012,62(4):319-335 [113] H. J. Xu，Z. G. Qu*，W. Q. Tao, Analytical solution of forced convective heat transfer in tubes partially filled with metallic foam using the two-equation model， International Journal of Heat and Mass Transfer，2011, 54(17-18): 3846-3855. [114] Y. P. Du, Z. G. Qu*, H. J Xu, Z. Y. Li, C. Y. Zhao, W. Q. Tao, Numerical simulation of film condensation on vertical plate embedded in metallic foams, Progress in Computational Fluid Dynamics, 2011, 11(3-4): 198-205. [115] H. J. Xu, Z. G. Qu*, T.J. Lu, Y.L. He, W. Q. Tao, Thermal modeling of forced convection in a parallel-plate channel partially filled with metallic foams, ASME Journal of Heat Transfer, 2011,133(9): 092603. [116] Wen-Tao Ji，Zhi-Guo Qu*,Zeng-Yao Li, Jian-Fei Guo, Ding-Cai Zhang, Wen-Quan Tao, Pool boiling heat transfer of R134a on single horizontal tube surfaces sintered with open-celled foam, International Journal of Thermal Sciences. 2011，50(11): 2248-2255. [117] H. J. Xu，Z. G. Qu*, W. Q. Tao, Thermal transport analysis in parallel-plate channel filled with open-celled metallic foams, International Communications in Heat and Mass Transfer, 2011, 38(7): 868-873. [118] Z. G. Xu，Z. G. Qu*，C.Y. Zhao, W. Q. Tao，Pool boiling heat transfer on open-celled metallic foam sintered surface under saturation condition，International Journal of Heat and Mass Transfer, 2011, 54(17-18): 3856-3867 [119] Gao, Huaibin; Qu, Zhiguo*; Tao, Wenquan; He, Yaling; Zhou, Jian，Experimental study of biogas combustion in a two-layer packed bed burner, Energy and fuels, 2011,25(7): 2887-2895. [120] Y. B. Tao, Y.L. He*, Z.G. Qu, W.Q. Tao, Numerical study on performance and fin efficiency of wavy fin-and-tube heat exchangers, Progress in Computational Fluid Dynamics, 2011, 11(3-4), 246-254. [121] Sun, DL, Tao, WQ*, Xu, JL, Qu, ZG, Implementation of the IDEAL algorithm on nonorthogonal curvilinear coordinates for the solution of 3-D incompressible fluid flow and heat transfer problems, Numerical Heat Transfer Part B-Fundamentals, 2011, 59 (2) : 147-168. [122] Y. P. Du, Z. G. Qu*, C.Y. Zhao, W. Q. Tao. Numerical study of conjugated heat transfer in metal foam filled double-pipe, International Journal of Heat and Mass Transfer, 2010, 53 (21-22): 4899-4907 [123] Zhao, C.Y*, Dai, L.N., Tang, G.H., Qu, Z.G., Li, Z.Y., Numerical study of natural convection in porous media (metals) using Lattice Boltzmann Method (LBM), International Journal of Heat and Fluid Flow, 2010, 31(5): 925-934. [124] Y.L. Lu, W.H. Zhang, P. Yuan, M. D. Xue, Z.G. Qu, W.Q. Tao*, Experimental study of heat transfer intensification by using a novel combined shelf in food refrigerated display cabinets, Applied Thermal Engineering, 2010, 30, (2-3): 85-91. [125] Sun DL, Qu ZG, He YL, Tao WQ*. Implementation of an efficient segregated algorithm-IDEAL on 3D collocated grid system, Chinese Science Bulletin, 2009, 54(6): 929-942. [126] Sun DL, Qu ZG, He YL, Tao WQ*. Performance analysis of IDEAL algorithm for three-dimensional incompressible fluid flow and heat transfer problems. International Journal for Numerical Methods in Fluids, 2009,61(10):1132-1160 [127] D. L. Sun, Z.G. Qu, Y. L. He, W.Q. Tao*. An efficient segregated algorithm for incompressible fluid flow and heat transfer problems-IDEAL (Inner Doubly Iterative efficient algorithm for linked equations) Part1: Mathematical formulation and solution procedure，Numerical Heat Transfer, Part B, 2008, 53(1): 1–17. [128] D. L. Sun, Z.G. Qu, Y. L. He, W.Q. Tao*. An efficient segregated algorithm for incompressible fluid flow and heat transfer problems-IDEAL (Inner Doubly Iterative efficient algorithm for linked equations, Part II: Application examples，Numerical Heat Transfer, Part B, 2008, 53(1): 18–38. [129] Z.G. Wu, Z.G.Qu, Y.L. He, W.Q. Tao*. A comprehensive performance comparison for segregated algorithms of flow and heat transfer in complicated geometries, Progress in Computational Fluid Dynamics, 2008，8（5）：233-247 [130] Huang Jing, Li Ru, He Yaling*, Qu Zhiguo. Solution for variable density low mach number flows with a compressible pressure-based algorithm, Applied Thermal Engineering, 2007, 27(11-12): 2104-2112. [131] Qu Z G, He Y L, Zhao C Y, Tao W Q*. Implementation of CLEAR algorithm on non-orthogonal curvilinear coordinates for solution of incompressible flow and heat transfer. International Journal of Numerical Methods in Fluids. 2007, 53(7): 1077-1105. [132] Qu Z. G.，Tao W Q*, He Y. L. An improved numerical scheme for SIMPLER method on nonorthogonal curvilinear coordinates: SIMPLERM. Numerical Heat Transfer, B, 2007, 51 (1):43-66. [133] Tao W Q, Jin WW, He Y L, Qu Z G, Zhang C C. Optimum design of two-row slotted fin surface with X-shape strip arrangement positioned by “Front Coarse and Rear Dense” principle, Part I: Physical/mathematical models and numerical methods. Numerical Heat Transfer, Part A, 2006,50 (8):731-749. [134] Jin W W, He Y L, Qu Z G, Zhang C C and Tao W Q*. Optimum design of two-row slotted fin surface with X-shape strip arrangement positioned by “Front Coarse and Rear Dense” principle, Part II: Results and discussion. Numerical Heat Transfer, Part A, 2006, 50 (8): 751-771 [135] Qu Z G, Tao W Q, He Y L. Implementation of CLEAR algorithm on collocated grid system and application examples. Numerical Heat Transfer, Par B, 2005, 47(1), 64-96. [136] Tao W Q, He Y L, Li Z Y, Qu Z G. Some recent advances in finite volume approach and their applications in the study of heat transfer enhancement. International Journal of Thermal Sciences, 2005，44(7)：623-643. [137] Tao W Q, He Y L, Qu Z G, Cheng Y P. Applications of the Field synergy principle in developing new type heat transfer enhanced surfaces, Journal of Enhanced Heat Transfer, 2004, 11(4): 438-451. [138] He Y L, Tao W Q, Qu Z G, Chen Z Q. Steady natural convection in a vertical cylindrical envelope with adiabatic lateral wall, International Journal of Heat and Mass Transfer, 2004,47(14-16): 3131-3144. [139] Tao W Q, Qu Z G, He Y L. A novel segregated algorithm for incompressible fluid flow and heat transfer problems - CLEAR (Coupled and Linked Equations Algorithm Revised) part II: Application examples. Numerical Heat Transfer, Part B, 2004. 45 (1): 19-48. [140] Tao W Q, Qu Z G, He Y L. A novel segregated algorithm for incompressible fluid flow and heat transfer problems - CLEAR (Coupled and Linked Equations Algorithm Revised) part I: Mathematical formulation and solution procedure. Numerical Heat Transfer, Part B, 2004.45 (1): 1-17. [141] Cheng Y P, Qu Z G, Tao W Q, He Y L, Numerical design of efficient slotted fin surface based on the field synergy principle. Numerical Heat Transfer, Part A, 2004，45(6): 517-538. [142] Qu Z G, Tao W Q, He Y L. Three-dimensional numerical simulation on laminar heat transfer and fluid flow characteristics of strip fin surface with X-arrangement of strips. ASME Journal of Heat Transfer. 2004, 126(5): 697-707. [143] Tao W Q, He Y L, Wang Q W, Qu Z G, Song F Q. A unified analysis on enhancing single phase convective heat transfer with field synergy principle. International Journal of Heat and Mass Transfer, 2002, 45(24): 4871-4879.