Yuwen Zhang, FAAAS, FASME
Curators' Distinguished Professor
Huber and Helen Croft Chair in Engineering
Mechanical and Aerospace Engineering
E3408 Lafferre Hall
Columbia, MO 65211
Email: zhangyu@missouri.edu
Journal Articles
332. Kek, H., Tan, H., Othman, M.H.D., Chong, W.T., Nakakuma, B.B., Bazgir, A., Zhang, Y., and Wong, K.Y, 2024, "Is Thermal-Guided Mobile Air Supply a Practical Measure in Burn Isolation Wards? Potential Future Applications," J. Therm. Anal. Calorim., doi: 10.1007/s10973-024-13045-3 (PDF).
331. Kek, H., Bazgir, A., Tan, H., Lee, C.T., Hong, T., Othman, M.H.D., Fan, Y.V., Mat, M.N.H., Zhang, Y., and Wong, K.Y, 2024, "Particle Dispersion for Indoor Air Quality Control Considering Air Change Approach: A Novel Accelerated CFD-DNN Prediction," Energy & Buildings, 306, p. 113938 (PDF).
330. Lage, J.L., Worek, W.M.,..., Zhang, Y., and Zhang, Z., 2023, “Professor Adrian Bejan on his 75th Birthday,” Int. Comm. Heat Mass Transfer, 149, p. 107162 (PDF).
329. Tayeb, R., and Zhang, Y., 2023, “A Machine Learning Approach to Model Oxidation of Toluene in a Bubble Column Reactor,” J. Heat Mass Transfer, 145(5), p. 052003 (PDF).
328. Liu, W., Yang, M., Zhang, Y., Liu, G., Ling, L., and Ying, X., 2023, "Asymmetric Phenomenon of Flickering Flame Under Different Co-Flow Velocities," Frontiers in Heat and Mass Transfer, 20, p. 15 (PDF).
327. Liu, W., Yang, M., Zhang, Y., Li, Y., Ying, X., and Huang, W., 2023, "Improving the Asymmetric Phenomenon Effects on the Combustion Characteristics in an Opposed-Fired Pulverized Coal Boiler," Numer. Heat Transfer, A., 83(7), pp. 790-813 (PDF).
326. Zhang, K., Chen, Y., Wang, L., and Zhang, Y., 2022, “A New Implicit Finite Difference Method with a Compact Correction Term for Solving Unsteady Convection Diffusion Equations,” Numer. Heat Transfer, B., 82(1-2), pp. 1-17 (PDF).
325. Hu, J. J., Yang, Z. W., Li, Y. L., Jin, Y. L., Huang, Z., and Zhang, Y. W., 2022, “Dynamic Flowfield of a Close-Range Impinging Jet in a Cylindrical Pool,” Fluid Dynamics, 57(3), pp. 401–411 (PDF).
324. Hu, Z., Wang, D., Lu, W., Chen, J., and Zhang, Y., 2022, “Performance of Vertical Axis Water Turbine with Eye-Shaped Baffle for Pico Hydropower,” Front. Energy, 16(4), pp. 683-696 (PDF).
323. Tayeb, R., and Zhang, Y., 2021, “Evaporation Induced Self-Assembly of Rough Colloids: A Multiscale Simulation Study,” Int. J. Heat Mass Transfer, 179, p. 121681 (PDF).
322. Li, Y., Yang, M., and Zhang, Y., 2021, “Bifurcation Analysis of Coupling Thermosolutal Convection Induced by a Thermal and Solutal Source in a Horizontal Cavity,” Int. Comm. Heat Mass Transfer, 126, p. 105455 (PDF).
321. Li, Y., Yang, M., and Zhang, Y., 2021, “Asymmetric Phenomenon of Flow and Mass Transfer in Symmetric Cylindrical and Semi-Cylindrical Shallow Chambers,” Int. Comm. Heat Mass Transfer, 123, p. 105174 (PDF).
320. Hu, J., Guo, M., Guo, J., Zhang, G., and Zhang, Y., 2020, “Numerical and Experimental Investigation of Solar Air Collector with Internal Swirling Flow,” Renewable Energy, 162, pp. 2259-2271 (PDF).
319. Mohammadian, S.K., and Zhang, Y., 2020, “Thermal Management of Li-ion Batteries by Embedding Microgrooves inside the Electrodes: A Thermal Lattice Boltzmann Method Study,” J. Heat Transfer, 142(5), p. 052902 (PDF).
318. Choi, J., and Zhang, Y., 2020, “Numerical Simulation of Oscillatory Flow and Heat Transfer in Pulsating Heat Pipes with Multi-turns Using OpenFOAM,” Numer. Heat Transfer, A., 77(8), pp. 761-781 (PDF).
317. Chen, T., Yin, Y., Zhang, Y., Zhang, X., 2020, “A Molecular Dynamics Study on Interaction Contributions of Components in Liquid-Vapor Systems between LiBr Aqueous Solutions and Air during Absorption,” Appl. Therm. Eng., 166, p. 114732 (PDF).
316. Liu, Y., Li, L., Zhang, Y., 2020, “Numerical Simulation of Non-Fourier Heat Conduction in Fins by Lattice Boltzmann Method,” Appl. Therm. Eng., 166, p. 114670 (PDF).
315. Hu, Z., Li, R., Yang, X., Yang, M., and Zhang, Y., 2020, “Numerical Simulation for Three-Dimensional Flow in a Vortex Tube with Different Turbulence Models,” Numer. Heat Transfer A, 77(2), pp. 121-133 (PDF).
314. Rassoulinejad-Mousavi, S.M., Azamat, J., Khataee, A., and Zhang, Y., 2020, “Molecular Dynamics Simulation of Water Purification using Zeolite MFI Nanosheets,” Sep. Purif. Technol., 234, p. 116080 (PDF).
313. Zhou, J., and Zhang, Y., 2019, “A Multigrid Approach for Three-Dimensional Inverse Heat Conduction Problems,” International Journal of Mechanical and Mechatronics Engineering, 13(3), pp. 164-169 (PDF).
312. Chen, T., Yin, Y., Zhang, Y., Zhang, X., 2019, “Model Evaluation of Lithium Bromide Aqueous Solution and Characteristics of Water Transport Behaviors in Liquid-Vapor Systems by Molecular Dynamics,” Int. J. Refrig., 107, pp. 165-173 (PDF).
311. Zhang, B., Mei, J., Zhang, C., Cui, M., Gao, X., and Zhang, Y., 2019, “A General Method for Predicting the Bank Thickness of a Smelting Furnace with Phase Change,” Appl. Therm. Eng., 162, p. 114219 (PDF).
310. Mohammadian, S.K., and Zhang, Y., 2019, “Convection Heat Transfer with Internal Heat Generation in Porous Media: Implementation of Thermal Lattice Boltzmann Method,” Numer. Heat Transfer A, 76(3), pp. 101-114 (PDF).
309. Zhang, B., Mei, J., Cui, M., Gao, X.W., and Zhang, Y., 2019, “A General Approach for Solving Three-Dimensional Transient Nonlinear Inverse Heat Conduction Problems in Irregular Complex Structures,” Int. J. Heat Mass Transfer, 140, pp. 909-917 (PDF).
308. Afrin, N., and Zhang, Y., 2019, “Surrogate-Based Optimization of Thermal Damage to Living Biological Tissues by Laser Irradiation,” Frontiers in Heat and Mass Transfer, 12, p. 27 (PDF).
307. Feng, Z., Dong, H., Ju, S. Wen, B., Zhang, Y., and Melnik, R., 2019, “High Bond Difference Parameters-Induced Low Thermal Transmission in Carbon allotropes with sp2 and sp3 Hybridization,” Phys. Chem. Chem. Phys., 21, pp. 12611-12619 (PDF).
306. Zhang, H., Xi, H., He, Y.L., and Zhang, Y.W, Ning, B., 2019, “Experimental Study of the Organic Rankine Cycle under Different Heat and Cooling Conditions,” Energy, 307, pp. 678-688 (PDF).
305. Tayeb, R., Mao, Y., and Zhang, Y., 2019, “Smoothed Particle Hydrodynamics Simulation of Granular System under Cyclic Compressions,” Powder Technol., 353, pp. 84-97 (PDF).
304. Zhang, W., Yang, M., and Zhang, Y., 2019, “Numerical Study of Periodically Fully-Developed Flow and Heat Transfer in Channels with Periodic Semi-Circular Tube,” Frontiers in Heat and Mass Transfer, 12, p. 18 (PDF).
303. Song, B.Y., He, Y., He, Y.L., Huang, D., and Zhang, Y.W., 2019, “Experimental Study on Anode Components Optimization for Direct Glucose Fuel Cells,” Energy, 176, pp. 15-22 (PDF).
302. Qian, N., Fu, Y., Zhang, Y., Chen, J., and Xu, J., 2019, “Experimental Investigation of Thermal Performance of the Oscillating Heat Pipe for the Grinding Wheel,” Int. J. Heat Mass Transfer, 136, pp. 911-923 (PDF).
301. Xia, T., He, Y.L., Zhang, Y., and Ning, B., 2019, “Numerical Simulation of the Growth Characteristics of Laser Chemical Vapor Deposition of Silicon Carbide,” Numer. Heat Transfer, A, 75(4), pp. 242-253 (PDF).
300. Zhang, K., Wang, L.B., Zhang, Y., 2019, “Compact Scheme Based on the SIMPLER Algorithm for Steady Incompressible Flow Problems,” J. Thermophys. Heat Transfer, 33(1), pp. 225-233 (PDF).
299. Mao, Y., Han, X., and Zhang, Y., 2018, “Cryoprotective Mechanism of Using Ficoll for Cell Cryopreservation at Non-Cryogenic Temperatures: A Molecular Dynamics Study,” Int. J. Heat Mass Transfer, 127A, pp. 319-325 (PDF).
298. Rong, Y., Ji, P., He, M., Zhang, Y., and Tang, Y., 2018, “Multiscale Investigation of Femtosecond Laser Pulses Processing Aluminum in Burst Mode,” Nanoscale Microscale Thermophys. Eng., 22(4), pp. 324-347 (PDF).
297. Rong, Y., Ji, P., He, M., Zhang, Y., and Tang, Y., 2018, “Atomistic Insights into the Exothermic Self-sustained Alloying of Al-shell /Ni-core Nanoparticle Triggered by Laser Irradiation,” Phys. Chem. Chem. Phys., 20, pp. 20398-20405 (PDF).
296. Lage, J.L., Minkowycz, W.J.,..., and Zhang, Y., 2018, “Celebration of Professor Adrian Bejan on his 70th Birthday,” Int. J. Heat Mass Transfer, 126A, pp. 1377-1378 (PDF).
295. Zhao, M., Yu, D.M., and Zhang, Y., 2018, “Evolution to Chaotic Natural Convection in a Horizontal Annulus with an Internally Slotted Circle,” Int. J. Heat Mass Transfer, 126B, pp. 95-108 (PDF).
294. Rassoulinejad-Mousavi, S.M., Mao, Y., and Zhang, Y., 2018, “Reducing Greenhouse Gas Emissions in Sandia Methane-Air Flame by Using a Biofuel,” Renewable Energy, 128, pp. 313-323 (PDF).
293. Cui, M., Xu, B.B., Lv, J., Gao, X.W., and Zhang, Y., 2018, “Numerical Solution of Multi-dimensional Transient Nonlinear Heat Conduction Problems with Heat Sources by an Extended Element Differential Method,” Int. J. Heat Mass Transfer, 126A, Part A, pp. 1111-1119 (PDF).
292. Yang, M., Wang, X., Wang, Z., Li, Z., and Zhang, Y., 2018, “Correlation for Turbulent Convection Heat Transfer in Elliptical Tubes by Numerical Simulations,” Frontiers in Heat and Mass Transfer, 11, p. 7 (PDF).
291. Ling, C., Min, C., Wang, Y., and Zhang, Y., 2018, “Economic Evaluation of Reverse Osmosis Desalination System Coupled with Tidal Energy,” Front. Energy, 12(2), pp. 297-304 (PDF).
290. Cui, M., Peng, H.F., Xu, B.B., Gao, X.W., and Zhang, Y., 2018, “A New Radial Integration Polygonal Boundary Element Method for Solving Heat Conduction Problems,” Int. J. Heat Mass Transfer, 123, pp. 251-260 (PDF).
289. Qiu, G., Yang, M., Wang, J., and Zhang, Y., 2018, “Double-Diffusive Natural Convection of Low Prandtl Number Liquids with Soret and Dufour Effects,” Frontiers in Heat and Mass Transfer, 10, p. 24 (PDF).
288. Sun, Y., Chen, L., Cui, L., Zhang, Y., and Du, X., 2018, “Molecular Dynamics Simulation of the Effect of Oxygen-containing Functional Groups on the Thermal Conductivity of Reduced Graphene Oxide,” Comput. Mater. Sci., 148, pp. 176–183 (PDF).
287. Cui, M., Mei, J., Zhang, B.W., Xu, B.B., Zhou, L., and Zhang, Y., 2018, “Inverse Identification of Boundary Conditions in a Scramjet Combustor with a Regenerative Cooling System,” Appl. Therm. Eng., 134, pp. 555-563 (PDF).
286. Rassoulinejad-Mousavi, S.M., and Zhang, Y., 2018, “Interatomic Potentials Transferability for Molecular Simulations: A Comparative Study for Platinum, Gold and Silver,” Sci. Rep., 8(1), 2424 (PDF).
285. Lei, Z., Zhang, Y., Lei, X., 2018, “Improving Temperature Uniformity of a Lithium-ion Battery by Intermittent Heating Method in Cold Climate,” Int. J. Heat Mass Transfer, 121, pp. 275-281 (PDF).
284. Mao, Y., Afrin, N., Chen, J.K., and Zhang, Y., 2018, “Numerical Simulation of Complex Flow and Heat Transfer Induced by Localized Laser Heating on a Urethane-Coated Substrate,” Numer. Heat Transfer, Part B, 73(2), pp. 63-77 (PDF).
283. Cui, M., Xu, B.B., Feng, W.Z., Zhang, Y., Peng, H.F., and Gao, X.W., 2018, “A Radial Integration Boundary Element Method for Solving Transient Heat Conduction Problems with Heat Sources and Variable Thermal Conductivity,” Numer. Heat Transfer, Part B, 73(1), pp. 1-18 (PDF).
282. Ji, P., Rong, Y., Zhang, Y., Tang, Y., 2018, “Impacts of Cone-Structured Interface and Aperiodicity on the Nanoscale Thermal Transport in Si/Ge Superlattices,” Front. Energy, 12(1), pp. 137-142 (PDF).
281. Sun, Y., Chen, L., Cui, L., Zhang, Y., and Du, X., 2018, “Molecular Dynamics Simulation of Cross-linked Epoxy Resin and its Interaction Energy with Graphene under Two Typical Force Fields,” Comput. Mater. Sci., 143, pp. 240-247 (PDF).
280. Mohammadian, S.K., and Zhang, Y., 2018, “Improving Wettability and Preventing Li-Ion Batteries from Thermal Runaway Using Microchannels,” Int. J. Heat Mass Transfer, 118, pp. 911-918 (PDF).
279. Lei, Z., Zhang, Y., and Lei, X., 2018, “Temperature Uniformity of a Heated Lithium-Ion Battery Cell in Cold Climate,” Appl. Therm. Eng., 129, pp. 148-154 (PDF).
278. Pouryoussefi, S.M., and Zhang, Y., 2018, “Numerical Investigation of Icing Effects on Vortex Shedding in a Cascade of Stator Blades,” Heat Transfer Research, 49(1), pp. 1-14 (PDF).
277. Zhang, Y., and Faghri, A., 2017, “Heat Transfer Enhancement in Latent Heat Thermal Energy Storage System,” J. Enhanced Heat Transfer, 24(1-6), pp. 173-182 (PDF).
276. Han, Y., Xu, C., Xu, G., Zhang, Y., and Yang, Y., 2017, “An Improved Flexible Solar Thermal Energy Integration Process for Enhancing the Coal-Based Energy Efficiency and NOx Removal Effectiveness in Coal-Fired Power Plants under Different Load Conditions,” Energies, 10(10), 1485 (PDF).
275. Dong, H., Wen, B., Zhang, Y., and Melnik, R., 2017, “Low Thermal Conductivity in Si/Ge Hetero-Twinned Superlattices,” RSC Adv., 7, pp. 29959-29965 (PDF).
274. Zhou, B., Yang, M., Li, Z., Wang, Z., and Zhang, Y., 2017, “ Numerical Simulations of Forced Convection Across a Single Tube to Evaluate Applicability of the DNS, LES and RSM Methods,” Appl. Therm. Eng., 123, pp. 123-130 (PDF).
273. Dong, H., Wen, B., Zhang, Y., and Melnik, R., 2017, “Thermal Conductivity of Diamond/SiC Nano-Polycrystalline Composites and Phonon Scattering at Interfaces,” ACS OMEGA, 2(5), pp. 2344–2350 (PDF).
272. Mao, Y., Zhang, B., Chen, C.L., and Zhang, Y., 2017, “Hybrid Atomistic-Continuum Simulation of Nanostructure Defect-Induced Bubble Growth,” J. Heat Transfer, 139(10), 104503 (PDF).
271. Ji, P., and Zhang, Y., 2017, “Melting and Thermal Ablation of a Silver Film Induced by Femtosecond Laser Heating: A Multiscale Modeling Approach,” Appl. Phys. A-Mater, 123, 671 (PDF).
270. Afrin, N., and Zhang, Y., 2017, “Uncertainty Analysis of Thermal Damage to Living Biological Tissues by Laser Irradiation Based on a Generalized Duel-Phase Lag Model,” Numer. Heat Transfer, Part A, 71(7), pp. 693-706 (PDF).
269. Mohammadian, S.K., and Zhang, Y., 2017, “Cumulative Effects of Using Pin Fin Heat Sink and Porous Metal Foam on Thermal Management of Lithium-ion Batteries,” Appl. Therm. Eng., 118, pp. 375-384 (PDF).
268. Shi, H., Fan, S., and Zhang, Y., 2017, “Design and Optimization of Slit-Resonant Beam in a MEMS Pressure Sensor Based on Uncertainty Analysis,” Microsyst. Technol., 23(12), pp. 5545-5559 (PDF).
267. Zhang, B., Mao, Y., Chen, C.L., and Zhang, Y., 2017, “A Hybrid Atomistic-Continuum Simulation of Nucleate Boiling with Domain Re-decomposition Method,” Numer. Heat Transfer, Part B, 71(3), pp. 217-235 (PDF).
266. Yang, M., Ding, Z., Lou, Q., Wang, Z., and Zhang, Y., 2017, “Lattice Boltzmann Method Simulation of Natural Convection Heat Transfer in Horizontal Annulus,” J. Thermophys. Heat Transfer, 31(3), pp. 700-711 (PDF).
265. Pouryoussefi, S.M., and Zhang, Y., 2017, “Analysis of Chaotic Flow in a 2D Multi-Turn Closed-Loop Pulsating Heat Pipe,” Appl. Therm. Eng., 126, pp. 1069-1076 (PDF).
264. Qi, X., Yang, M., and Zhang, Y., 2017, “Numerical Analysis of NOx Production under the Air Staged Combustion,” Frontiers in Heat and Mass Transfer, 8, p. 3 (PDF).
263. Ji, P., and Zhang, Y., 2017, “Multiscale Modeling of Femtosecond Laser Irradiation on a Copper Film with Electron Thermal Conductivity from ab initio Calculation,” Numer. Heat Transfer, Part A, 71(2), pp. 128-136 (PDF).
262. Xi, H., Li, M.J., He, Y.L., Zhang, Y.W., 2017, “Economical Evaluation and Optimization of Organic Rankine Cycle with Mixture Working Fluids Using R245fa as Flame Retardant,” Appl. Therm. Eng., 113, pp. 1056-1070 (PDF).
261. Dai, L., Zhou, Q., Zhang, Y., Yao, S., Kang, S., and Wang, X., 2017, “Analysis of Wind Turbine Blades Aeroelastic Performance under Yaw Conditions,” J. Wind Eng. Ind. Aerod., 171, pp. 273-287 (PDF).
260. Li, Z., Yang, M., He, Y.L., and Zhang, Y., 2017, “Mass Balance in Lattice Boltzmann Method with Dirichlet Velocity Boundary Condition,” Heat Transfer Research, 48(9), pp. 811-826 (PDF).
259. Ji, P., and Zhang, Y., 2017, “Electron-Phonon Coupled Heat Transfer and Thermal Response Induced by Femtosecond Laser Heating of Gold,” J. Heat Transfer, 139(5), 052001 (PDF).
258. Shi, H., Fan, S., and Zhang, Y., 2017, “Analysis of Phase Drift Based on Uncertainty Analysis in Electro-Thermal Excited MEMS Resonant Sensor,” Microsyst. Technol., 23(6), pp. 2043-2053 (PDF).
257. Mohammadian, S.K., and Zhang, Y., 2016, “Effects of Size of Microchannels on Thermo-Electrical Performance of an Internally Cooled Li-Ion Battery Cell,” J. Electrochem. En. Conv. Stor., 13(4), 044501 (PDF).
256. Ma, X., Yang, M., and Zhang, Y., 2016, “Analysis of Combustion Mechanism and Combustion Optimization of a 300MW Pulverized Coal Boiler,” Frontiers in Heat and Mass Transfer, 7, p. 36 (PDF).
255. Talkhoncheh, F.K., Xu, H.T., Wang, Z., Yang, M., and Zhang, Y., 2016, “Numerical Simulation of Transient Forced Convection in a Square Enclosure Containing Two Heated Circular Cylinders,” Int. J. Numer. Methods Heat Fluid Flow, 26(1), pp. 307-327 (PDF).
254. Pouryoussefi, S.M., and Zhang, Y., 2016, “Nonlinear Analysis of Chaotic Flow in a Three-Dimensional Closed-Loop Pulsating Heat Pipe,” J. Heat Transfer, 138(12), 122003 (PDF).
253. Mohammadian, S.K., and Zhang, Y., 2016, “Temperature Uniformity Improvement of an Air-Cooled High-Power Lithium-Ion Battery Using Metal and Nonmetal Foams,” J. Heat Transfer, 138(11), 114502 (PDF).
252. Rassoulinejad-Mousavi, S.M., Mao, Y., and Zhang, Y., 2016, “Evaluation of Copper, Aluminum and Nickel Interatomic Potentials on Predicting the Elastic Properties,” J. Appl. Phys., 119, 245102 (PDF).
251. Zhang, K., Wang, L.B., Zhang, Y., 2016, “Improved Finite Difference Method with a Compact Correction Term for Solving Poisson's Equations,” Numer. Heat Transfer, Part B, 70(5), pp. 393-405 (PDF).
250. Afrin, N., Mao, Y., and Zhang, Y., Chen, J.K., Ritter R., Lampson, A., Stohs, J., 2016, “Multicomponent Gas-Particle Flow and Heat/Mass Transfer Induced by a Localized Laser Irradiation on a Urethane-Coated Stainless Steel Substrate,” Frontiers in Heat and Mass Transfer, 7, p. 7 (PDF).
249. Yang, Y., Chen, Z., Zhang, Y., 2016, “Melt Flow and Heat Transfer in Laser Drilling,” Int. J. Therm. Sci., 107, pp. 141-152 (PDF).
248. Li, L., Ji, P., and Zhang, Y., 2016, “Molecular Dynamics Simulation of Condensation on Nanostructured Surface in a Confined Space,” Appl. Phys. A-Mater, 122, p. 496 (PDF).
247. Shen, C., Yang, M., Zhang, Y., and Li, Z., 2016, "Effects of Slotted Structures on the Nonlinear Characteristics of Natural Convection in a Cylinder with an Internal Concentric Slotted Annulus,” Numer. Heat Transfer, Part A, 70(5), pp. 447-459 (PDF).
246. Wang, J., Yang, M., He, Y.L., and Zhang, Y., 2016, “Oscillatory Double-Diffusive Convection in a Horizontal Cavity with Soret and Dufour Effects,” Int. J. Therm. Sci., 106, pp. 57-69 9 (PDF).
245. Ji, P., and Zhang, Y., 2016, “Ab Initio Determination of Effective Electron-Phonon Coupling Factor in Copper,” Phys. Lett. A, 380(17), pp. 1551-1555 (PDF).
244. Afrin, N., Zhang, Y., and Chen, J.K., 2016, “Uncertainty Analysis of Melting and Resolidification of Gold Film Irradiated by Nano- to Femtosecond Lasers Using Stochastic Method,” J. Heat Transfer, 138(6), p. 062301 (PDF).
243. Rajabifar, B., Seyf, H.R., Zhang, Y., Khanna, S.K., 2016, “Flow and Heat Transfer in Micro Pin Fin Heat Sinks with Nano-Encapsulated Phase Change Materials,” J. Heat Transfer, 138(6), p. 062401 (PDF).
242. Ji, P., and Zhang, Y., 2016, “Continuum-Atomistic Simulation of Picosecond Laser Heating of Copper with Electron Heat Capacity from ab initio Calculation,” Chem. Phys. Lett., 648, pp. 109-113 (PDF).
241. Li, Z., Yang, M., and Zhang, Y., 2016, “Double MRT Thermal Lattice Boltzmann Method for Simulating Natural Convection of Low Prandtl Number Fluids,” Int. J. Numer. Methods Heat Fluid Flow, 26(6), pp. 1809-1909 (PDF).
240. Pouryoussefi, S.M., and Zhang, Y., 2016, “Numerical Investigation of Chaotic Flow in a 2D Closed-Loop Pulsating Heat Pipe,” Appl. Therm. Eng., 98, pp. 617-627 (PDF).
239. Fu, T., Mao, Y., Tang, Y., and Zhang, Y., Yuan, W., 2016, “Effect of Nanostructure on Rapid Boiling of Water on a Hot Copper Plate: a Molecular Dynamics Study,” Heat and Mass Transfer, 52(8), pp. 1469-1478 (PDF).
238. Tayeb, R., Dou, X., Mao, Y., and Zhang, Y., 2016, “Analysis of Cohesive Micro-Sized Particle Packing Structure Using History-Dependent Contact Models,” J. Manuf. Sci. Eng., 138(4), p. 041005 (PDF).
237. Wang, K., He, Y.L., Qiu, Y., Zhang, Y.,2016, “A Novel Integrated Simulation Approach Couples MCRT and Gebhart Methods to Simulate Solar Radiation Transfer in a Solar Power Tower System with a Cavity Receiver,” Renewable Energy, 89, pp. 93-107 (PDF).
236. Zhao, M., Zhu, T., Wang, C., Chen, H., and Zhang, Y., 2016, “Numerical Simulation on the Thermal Performance of Hydraulic Floor Heating System with Phase Change Materials,” Appl. Therm. Eng., 93, pp. 900-907 (PDF).
235. Li, Z., Yang, M., and Zhang, Y., 2016, “Lattice Boltzmann Method Simulation of 3-D Natural Convection with Double MRT Model,” Int. J. Heat Mass Transfer, 94, pp. 222-238 (PDF).
234. Karimi, F., Xu, H.T., Wang, Z., Yang, M., and Zhang, Y., 2016, “Numerical Simulation of Steady Mixed Convection around Two Heated Circular Cylinders in a Square Enclosure,” Heat Transfer Eng., 37(1), pp. 64-75 (PDF).
233. Li, Z., Yang, M., Zhang, Y., and Montgomery-Smith, S., 2015, “Investigation on Oscillatory Flow in an Oscillating Heat Pipe with Random Initial Conditions,” J. Enhanced Heat Transfer, 22(6), pp. 485-502 (PDF).
232. Kim, Y., Choi, J., Kim, S., and Zhang, Y., 2015, “Effects of Mass Transfer Time Relaxation Parameters on Condensation in a Thermosyphon,” J. Mech. Sci. Technol., 29(12), pp. 5497-5505 (PDF).
231. Mohammadian, S.K., Rassoulinejad-Mousavi, S.M., and Zhang, Y., 2015, “Thermal Management Improvement of an Air-Cooled High-Power Lithium-ion Battery by Embedding Metal Foam,” J. Power Sources, 296, pp. 305-313 (PDF).
230. Hanafizadeh, P., Pouryoussefi, S.M., Fathpour, M., and Zhang, Y., 2015, “Identification of Two-Phase Water-Air Flow Patterns in a Vertical Pipe Using Fuzzy Logic and Genetic Algorithm,” Appl. Therm. Eng., 85, pp. 195-206 (PDF).
229. Li, Z., Yang, M., and Zhang, Y., 2015, “Numerical Simulation of Melting Problems Using the Lattice Boltzmann Method with the Interfacial Tracking Method,” Numer. Heat Transfer, Part A, 68(11), pp. 1175-1197 (PDF).
228. Shi, H., Fan, S., Zhang, Y., and Sun, J., 2015, “Nonlinear Dynamics Study Based on Uncertainty Analysis in Electro-Thermal Excited Mems Resonant Sensor,” Sensor Actuat. A-Phys., 232, pp. 103-114 (PDF).
227. Li, Z., Yang, M., and Zhang, Y., 2015, “A Hybrid Lattice Boltzmann and Monte Carlo Method for Natural Convection Simulation,” Int. J. Multiscale Comput. Eng., 13(4), pp. 297-309 (PDF).
226. Pouryoussefi, S.M., and Zhang, Y., 2015, “Experimental Study of Air-Cooled Parallel Plate Fin Heat Sinks with and without Circular Pin Fins between the Plate Fins,” J. Applied Fluid Mechanics, 8(3), pp. 515-520 (PDF).
225. Mohammadian, S.K., He, Y.L., and Zhang, Y., 2015, “Internal Cooling of a Lithium-Ion Battery using Electrolyte as Coolant through Microchannels Embedded inside the Electrodes,” J. Power Sources, 293, pp. 458-466 (PDF).
224. Wang, J., Yang, M., and Zhang, Y., 2015, “Coupling-Diffusive Effects on Thermosolutal Buoyancy Convection in a Horizontal Cavity,” Numer. Heat Transfer, Part A, 68(6), pp. 583-597 (PDF).
223. Mao, Y., Zhang, Y., and Chen, C.L., 2015, “Atomistic-Continuum Hybrid Simulation of Heat Transfer between Argon Flow and Copper Plates,” J. Heat Transfer, 137(9), p. 091011 (PDF).
222. Li, L., Du, X., Zhang, Y., Yang, L., and Yang, Y., 2015, “Numerical Simulation on Flow and Heat Transfer of Fin-and-Tube Heat Exchanger with Longitudinal Vortex Generators,” Int. J. Therm. Sci., 92, pp. 85-96 (PDF).
221. Fu, T., Mao, Y., Tang, Y., and Zhang, Y., Yuan, W., 2015, “Molecular Dynamics Simulation on Rapid Boiling of Thin Water Films on Cone-Shaped Nanostructure Surfaces,” Nanoscale Microscale Thermophys. Eng., 19(1), pp. 17-30 (PDF).
220. Deng, X., Fu, J., and Zhang, Y., 2015, “A Predictive Model for Temperature Rise of Spindle-Bearing Integrated System,” J. Manuf. Sci. Eng., 137(2), p. 021014 (PDF).
219. Li, L., Zhou, L., Shan, Y., Zhang, Y., 2015, “Investigation on Heat Transfer Mechanism of Ultrashort Laser Interaction with Metals,” Int. J. Thermophys., 36(1), pp. 183-203 (PDF).
218. Yue, Y., Mohammadian, S.K., Zhang, Y., 2015, “Analysis of Performances of a Manifold Microchannel Heat Sink with Nanofluids,” Int. J. Therm. Sci., 89, pp. 305-313 (PDF).
217. Rajabi Far, B., Mohammadian, S.K., Khanna, S.K., Zhang, Y., 2015, “Effects of Tip-Clearance on the Performance of an Enhanced Microchannel Heat Sink with Oblique Fins and Phase Change Material Slurry,” Int. J. Heat Mass Transfer, 83, pp. 136-145 (PDF).
216. Mohammadian, S.K., and Zhang, Y., 2015, “Thermal Management Optimization of an Air-Cooled Li-ion Battery Module Using Pin-Fin Heat Sinks for Hybrid Electric Vehicles,” J. Power Sources, 273, pp. 431-439 (PDF).
215. Shi, H., Fan, S., Zhang, Y., and Sun, J., 2015, “Design and Optimization Based on Uncertainty Analysis in Electro-Thermal Excited MEMS Resonant Sensor,” Microsyst. Technol., 21(4), pp. 757-771 (PDF).
214. Wei, B., Yang, M., Wang, Z., Xu, H., and Zhang, Y., 2015, “Flow and Thermal Performance of a Water-Cooled Periodic Transversal Elliptical Microchannel Heat Sink for Chip Cooling,” J. Nanosci. Nanotechno., 15(4), pp. 3061-3066 (PDF).
213. Lu, H., Seyf, H.R., Zhang, Y., and Ma, H.B., 2015, “Heat Transfer Enhancement of Backward-Facing Step Flow by Using Nano-Encapsulated Phase Change Material Slurry,” Numer. Heat Transfer, Part A, 67(4), pp. 381-400 (PDF).
212. Wang, J., Yang, M., and Zhang, Y., 2015, “A Nonequilibrium Thermal Model for Direct Metal Laser Sintering,” Numer. Heat Transfer, Part A, 67(3), pp. 249-267 (PDF).
211. Wang, J., Yang, M., and Zhang, Y., 2015, “A Multiscale Nonequilibrium Model for Melting of Metal Powder Bed Subjected to Constant Heat Flux,” Int. J. Heat Mass Transfer, 80, pp. 309-318 (PDF).
210. Zhang, K., Yang, M., and Zhang, Y., 2014, “Two- and Three-Dimensional Numerical Simulations of Natural Convection in a Cylindrical Envelope with an Internal Concentric Cylinder with Slots,” Int. J. Heat Mass Transfer, 70, pp. 434-438 (PDF).
209. Tang, Y., Fu, T., Mao, Y., Zhang, Y., Yuan, W., 2014, “Molecule Dynamics Simulation of Heat Transfer between Argon Flow and Parallel Copper Plates,” J. Nanotechnol. Eng. Med., 5(3), p. 034501 (PDF).
208. Li, Z., Yang, M., and Zhang, Y., 2014, “A Hybrid Lattice Boltzmann and Finite Volume Method for Melting with Natural Convection,” Numer. Heat Transfer, Part B, 66(4), pp. 307-325 (PDF).
207. Wang, J., Yang, M., and Zhang, Y., 2014, “Onset of Double-Diffusive Convection in Horizontal Cavity with Soret and Dufour Effects,” Int. J. Heat Mass Transfer, 78, pp. 1023-1031 (PDF).
206. Wang, P., Yang, M., Wang, Z., and Zhang, Y., 2014, “A New Heat Transfer Correlation for Turbulent Flow of Air with Variable Properties in Noncircular Ducts,” J. Heat Transfer, 136(10), p. 101701 (PDF).
205. Zhou, L., Li, L., Zhang, Y., Shan, Y.G., 2014, “Source Distribution Based on Mie’s Scattering Theory for Heat Conduction in Nanoparticle Subject to Ultrashort Laser Irradiation,” Numer. Heat Transfer, Part A, 66(6), pp. 605-621 (PDF).
204. Liu, W., Liu, L., Huang, J., Zhang, Y., Xu, G. and Yang, Y., 2014, “Analysis and Optimization of a Compressed Air Energy Storage – Combined Cycle System,” Entropy, 16, pp. 3103-3120 (PDF).
203. Mohammadian, S.K., and Zhang, Y., 2014, “Analysis of Nanofluid Effects on Thermoelectric Cooling by Micro-Pin-Fin Heat Exchangers,” Appl. Therm. Eng., 70(1), pp. 282-290 (PDF).
202. Feng, Z.C., and Zhang, Y., 2014, “Safety Monitoring of Exothermic Reactions Using Time Derivatives of Temperature Sensors,” Appl. Therm. Eng., 66(1-2), pp. 346-354 (PDF).
201. Zhu, G., and Zhang, Y., 2014, “Analysis of Casting Roll Temperature Distribution and Thermal Deformation in Twin-Roll Continuous Strip Casting,” J. Manuf. Sci. Eng., 136(3), p. 034501 (PDF).
200. Yang, M., Zhou, Y., Zhang, Y., Li, Z., 2014, “Lattice Boltzmann Method Simulation of Flows in Cylinder with Internal Slotted Hollow,” J. Thermophys. Heat Transfer, 28(2), pp. 279-286 (PDF).
199. Huang, J., Gruzdev, V.E., Zhang, Y., and Chen, J.K., 2014, “Sintering of Titanium and Nickel Nanopowders with a Nd:YAG Nanosecond Laser,” Frontiers in Heat and Mass Transfer, 5, p. 1 (PDF).
198. Xu, H.T., Xiao, R., Karimi, F., Yang, M., and Zhang, Y., 2014, “Numerical Study of Double Diffusive Mixed Convection around a Heated Cylinder in an Enclosure,” Int. J. Therm. Sci., 78, pp. 169-181 (PDF).
197. Xu, H.T., Wang, Z.Y., Karimi, F., Yang, M., and Zhang, Y., 2014, “Numerical Simulation of Double Diffusive Mixed Convection in an Open Enclosure with Different Cylinder Locations,” Int. Commun. Heat Mass Transfer, 52, pp. 33-45 (PDF).
196. Dou, X., Mao, Y., and Zhang, Y., 2014, “Effects of Contact Force Model and Size Distribution on Microsized Granular Packing,” J. Manuf. Sci. Eng., 136(2), p. 021003 (PDF).
195. Li, L., Zhou, L., and Zhang, Y., 2014, “Thermal Wave Superposition and Reflection Phenomena during Femtosecond Laser Interaction with Thin Gold Film,” Numer. Heat Transfer, Part A, 65(12), pp. 1139-1153 (PDF).
194. Li, Z., Yang, M., and Zhang, Y., 2014, “Hybrid Lattice Boltzmann and Finite Volume Methods for Fluid Flow Problems,” Int. J. Multiscale Comput. Eng., 12(3), pp. 177-192 (PDF).
193. Seyf, H.R., Wilson, M., Zhang, Y., and Ma, H.B., 2014, “Flow and Heat Transfer of Nanoencapsulated Phase Change Material Slurry Past a Unconfined Square Cylinder,” J. Heat Transfer, 136(5), p. 051902 (PDF).
192. Li, Z., Yang, M., and Zhang, Y., 2014, “Hybrid Lattice Boltzmann and Finite Volume Method for Simulation of Natural Convection,” J. Thermophys. Heat Transfer, 28(1), pp. 68-77 (PDF).
191. Karimi, F., Xu, H.T., Yang, M., and Zhang, Y., 2014, “Numerical Simulation of Unsteady Natural Convection from Heated Horizontal Circular Cylinders in a Square Enclosure,” Numer. Heat Transfer, Part A, 65(8), pp. 715-731 (PDF).
190. Peng, Q., He, Y.L., and Zhang, Y., 2014, “Numerical Simulation of Heat and Mass Transfer during Nanosecond Laser Chemical Vapor Deposition on a Particle Surface,” Numer. Heat Transfer, Part A, 65(7), pp. 662-678 (PDF).
189. Feng, Z.C., and Zhang, Y., 2014, “Thermal Runaway due to Symmetry Breaking in Parallel-Connected Battery Cells,” Int. J. Energy Research, 38(6), pp. 813-821 (PDF).
188. Li, Z., Yang, M., and Zhang, Y., 2014, “A Coupled Lattice Boltzmann and Finite Volume Method for Natural Convection Simulation,” Int. J. Heat Mass Transfer, 70, pp. 864–874 (PDF).
187. Zhang, K., Yang, M., Wang, J., and Zhang, Y., 2014, “Three-Dimensional Numerical Simulations of Natural Convection in a Cylindrical Envelope with an Internal Concentric Cylinder with Slots,” J. Engineering Thermophys., 35(1), pp. 128-131 (PDF).
186. Mao, Y., and Zhang, Y., 2014, “Molecular Dynamics Simulation on Rapid Boiling of Water on a Hot Copper Plate,” Appl. Therm. Eng., 62(2), pp. 607-612 (PDF).
185. Zhang, K., Yang, M., Wang, J., and Zhang, Y., 2014, “Experimental Study on Natural Convection in a Cylindrical Envelope with an Internal Concentric Cylinder with Slots,” Int. J. Therm. Sci., 76, pp. 190-199 (PDF).
184. Mohammadian, S.K., Seyf, H.R., and Zhang, Y., 2014, “Performance Augmentation and Optimization of Aluminum Oxide-Water Nanofluid Flow in a Two-Fluid Microchannel Heat Exchanger,” J. Heat Transfer, 136(2), p. 021701 (PDF).
183. Afrin, N., Zhang, Y., and Chen, J.K., 2014, “Dual-Phase Lag Behavior of a Gas-Saturated Porous-Medium Heated by a Short-Pulsed Laser,” Int. J. Therm. Sci., 75, pp. 21-27 (PDF).
182. Li, L., Du, X., Zhang, Y., Xu, C., Yang, L., and Yang, Y., 2013, “Experimental and Numerical Study of Heat Transfer over a Finned Elliptical Flat Tube Fitted with Longitudinal Vortex Generators on the Rectangular Fin Surface,” J. Enhanced Heat Transfer, 20(5), pp. 427-441 (PDF).
181. Ji, P., Zhang, Y., and Yang, M., 2013, “Structural, Dynamic, and Vibrational Properties during Heat Transfer in Si/Ge Superlattices: A Car-Parrinello Molecular Dynamics Study,” J. Appl. Phys., 114, p. 234905 (PDF).
180. Ji, P., and Zhang, Y., 2013, “Femtosecond Laser Processing of Germanium: An Ab Initio Molecular Dynamics Study,” J. Phys. D: Appl. Phys., 46(49), p. 495108 (PDF).
179. Seyf, H.R., and Zhang, Y., 2013, “Molecular Dynamics Simulation of Normal and Explosive Boiling on Nanostructured Surface,” J. Heat Transfer, 135(12), p. 121503 (PDF).
178. He, Y.L., Chu, P., Tao, W.Q., Zhang, Y., Xie, T., 2013, “Analysis of Heat Transfer and Pressure Drop for Fin-and-Tube Heat Exchangers with Rectangular Winglet-Type Vortex Generators,” Appl. Therm. Eng., 61(2), pp. 770-783 (PDF).
177. Shen, C.Y., Yang, M., Wang, J., Zhang, K., Zhang, Y., 2013, “Natural Convection Heat Transfer Characteristics of a Circle with an Internal Concentric Round Slotted in Different Direction,” J. Univ. of Shanghai for Sci. and Tech., 35(5), pp. 425-429 (PDF).
176. Mao, Y., and Zhang, Y., 2013, “Evaluation of Turbulent Models for Natural Convection of Compressible Air in a Tall Cavity,” Numer. Heat Transfer, Part B, 64(5), pp. 351-364 (PDF).
175. Li, Z., Yang, M., Chen, Q., and Zhang, Y., 2013, “Numerical Solution of Melting in a Discretely Heated Enclosure using an Interfacial Tracking Method,” Numer. Heat Transfer, Part A, 64(11), pp. 841-857 (PDF).
174. Seyf, H.R., and Zhang, Y., 2013, “Effect of Nanotextured Array of Conical Features on Explosive Boiling over a Flat Substrate: A Nonequilibrium Molecular Dynamics Study,” Int. J. Heat Mass Transfer, 66, pp. 613-624 (PDF).
173. Jiang, S., Zhang, Y., Gan, Y., Chen, Z., and Peng, H., 2013, “Molecular Dynamics Study of Neck Growth in Laser Sintering of Hollow Silver Nanoparticles with Different Heating Rates,” J. Phys. D: Appl. Phys., 46(33), p. 335302 (PDF).
172. Seyf, H.R., Kim, S., and Zhang, Y., 2013, “Thermal Performance of an Al2O3-Water Nanofluid Pulsating Heat Pipe,” J. Electron. Packaging, 135(3), p. 031005 (PDF).
171. Mao, Y., Chen, C.L., and Zhang, Y., 2013, “Molecular Dynamic Study on Contact Angle of Water Droplet on a Single-Wall Carbon Nanotube (SWCNT) Plate,” Appl. Phys. A-Mater., 111(3), pp. 747-754 (PDF).
170. Kim, S., Zhang, Y., and Choi, J., 2013, “Effects of Fluctuations of Heating and Cooling Section Temperatures on Performance of a Pulsating Heat Pipe,” Appl. Therm. Eng., 58(1-2), pp. 42-51 (PDF).
169. Ren, Y., Cheng, C.W., Chen, J.K., Zhang, Y., Tzou, D.Y., 2013, “Thermal Ablation of Metal Films by Femtosecond Laser Bursts,” Int. J. Therm. Sci., 70, pp. 32-40 (PDF).
168. Peng, Q., Zhang, Y., He, Y.L., Mao, Y., 2013, “Thermal Modeling of Chemical Vapor Deposition on the Particle Surface Subjected to Nanosecond Laser Heating,” Int. J. Heat Mass Transfer, 61, pp. 675-683 (PDF).
167. Afrin, N., Feng, Z.C., Zhang, Y., and Chen, J.K., 2013, “Inverse Estimation of Front Surface Temperature of a Locally Heated Plate with Temperature-Dependent Conductivity via Kirchhoff Transformation,” Int. J. Therm. Sci., 69, pp. 53-60 (PDF).
166. Peng, H., Zhang, Y., Pai, P.F., 2013, “Uncertainty Analysis of Solid-Liquid-Vapor Phase Change of a Metal Particle Subject to Nanosecond Laser Heating,” J. Manuf. Sci. Eng., 135(2), p. 021009 (PDF).
165. Mao, Y., and Zhang, Y., 2013, “Nonequilibrium Molecular Dynamics Simulation of Nanobubble Growth and Annihilation in Liquid Water,” Nanoscale Microscale Thermophys. Eng., 17(2), pp. 79-91 (PDF).
164. Ji, P., and Zhang, Y., 2013, “First-Principles Molecular Dynamics Investigation of the Atomic-Scale Energy Transport: From Heat Conduction to Thermal Radiation” Int. J. Heat Mass Transfer, 60, pp. 69-80 (PDF).
163. Mao, Y., Zhang, Y., and Chen, J.K., 2013, “Melting, Vaporization, and Resolidification in a Thin Gold Film Irradiated by Multiple Femtosecond Laser Pulses,” J. Manuf. Sci. Eng., 135(2), p. 021007 (PDF).
162. Seyf, H.R., Zhou, Z., Ma, H.B., and Zhang, Y., 2013, “Three Dimensional Numerical Study of Heat-Transfer Enhancement by Nano-Encapsulated Phase Change Material Slurry in Microtube Heat Sinks with Tangential Impingement,” Int. J. Heat Mass Transfer, 56(1-2), pp. 561-573 (PDF).
161. Ren, Y., Zhang, Y., Chen, J.K., and Feng, Z.C., 2013, “Inverse Estimation of the Front Surface Temperature of a 3-D Finite Slab Based on the Back Surface Temperature Measured at Coarse Grids,” Numer. Heat Transfer, Part B, 63(1), pp. 1-17 (PDF).
160. Kim, S., Zhang, Y., and Choi, J., 2013, “Entropy Generation Analysis for a Pulsating Heat Pipe,” Heat Transfer Research, 44(1), pp.1-30 (PDF).
159. Mao, Y., and Zhang, Y., 2012, “Prediction of the Temperature-Dependent Thermal Conductivity and Shear Viscosity for Rigid Water Models,” J. Nanotechnol. Eng. Med., 3(3), p. 031009 (PDF).
158. Li, Z., Yang, M., Wang, Z., Zhang, Y., 2012, “A Corrected Method to Solve the Convective-Diffusion Equation Based on SIMPLE,” J. Engineering Thermophys., 33(9), pp. 1563-1566 (PDF).
157. Mao, Y., and Zhang, Y., 2012, “Thermal Conductivity, Shear Viscosity and Specific Heat of Rigid Water Models,” Chem. Phys. Lett., 542, pp. 37-41 (PDF).
156. Jia, T., Zhang, Y., Ma, H.B., and Chen, J.K., 2012, “Investigation of the Characteristics of Heat Current in a Nanofluid Based on Molecular Dynamics Simulation,” Appl. Phys. A-Mater., 108(3), pp. 537-544 (PDF).
155. Kang, H., Zhang, Y., Yang, M., and Li, L., 2012, “Molecular Dynamics Simulation on Effect of Nanoparticle Aggregation on Transport Properties of a Nanofluid,” J. Nanotechnol. Eng. Med., 3(2), p. 021001 (PDF).
154. He, Y. L., Han, H., Tao, W.Q., and Zhang, Y.W., 2012, “Numerical Study of Heat-Transfer Enhancement by Punched Winglet-Type Vortex Generator Arrays in Fin-and-Tube Heat Exchangers,” Int. J. Heat Mass Transfer, 55(21-22), pp. 5449-5458 (PDF).
153. Bian, E.-J., Yang, M., Li, L., Zhang, Y.W., 2012, “Simulation and Nonlinear Analysis for the Rayleigh-Benard Convection with the Lattice-Boltzmann Method,” J. Engineering Thermophys., 33(4), pp. 685-688 (PDF).
152. Afrin, N., Zhou, J., Zhang, Y., Tzou, D.Y., and J., Chen, J.K., 2012, “Numerical Simulation of Thermal Damage to Living Biological Tissues Induced by Laser Irradiation based on a Generalized Dual Phase Lag Model,” Numer. Heat Transfer, Part A, 61(7), pp. 483-501 (PDF).
151. Ren, Y., Chen, J.K., and Zhang, Y., 2012, “Heat Transfer in Metal Films Irradiated by Combined Nanosecond Laser Pulse and Femtosecond Pulse Train,” Frontiers in Heat and Mass Transfer, 3(2), p. 023001 (PDF).
150. Zhou, J., Zhang, Y., Chen, J.K., and Feng, Z.C., 2012, “Three-Dimensional Inverse Heat Transfer in a Composite Target Subject to High-Energy Laser Irradiation,” J. Heat Transfer, 134(11), p. 111201 (PDF).
149. Wang, Z., Yang, M., Li, L., and Zhang, Y., 2012, “Oscillation and Chaos in Combined Heat Transfer by Natural Convection, Conduction, and Surface Radiation in an Open Cavity,” J. Heat Transfer, 134(9), p. 094501 (PDF).
148. Zhang, K. Yang, M., and Zhang, Y., 2012, “A Compact Finite-Difference Scheme Based on the Projection Method for Natural-Convection Heat Transfer,” Numer. Heat Transfer, Part B, 61(4), pp. 259 – 278 (PDF).
147. Huang, J., Zhang, Y., Chen, J.K., and Yang, M., 2012, “Ultrafast Solid-Liquid-Vapor Phase Change of a Thin Gold Film Irradiated by Femtosecond Laser Pulses and Pulse Trains,” Front. Energy,6(1), pp. 1–11 (PDF).
146. Choi, J. and Zhang, Y., 2012, “Numerical Simulation of Laminar Forced Convection Heat Transfer of Al2O3-Water Nanofluid in a Pipe with Return Bend,” Int. J. Therm. Sci., 55, 90-102 (PDF).
145. Jia, T., Zhang, Y., Chen, J.K., He, Y.L., 2012, “Dynamic Simulation of Granular Packing of Fine Cohesive Particles with Different Size Distributions,” Powder Technol., 218, pp. 76-85 (PDF).
144. Zhou, J., Zhang, Y., Chen, J.K., and Feng, Z.C., 2012, “Inverse Estimation of Surface Temperature Induced by a Moving Heat Source in a 3-D Object Based on Back Surface Temperature with Random Measurement Errors,” Numer. Heat Transfer, Part A, 61(2), pp. 85-100 (PDF).
143. Jung, S., Seo, D., Lombardo, S.L., Feng, Z.C., Chen, J.K., and Zhang, Y., 2012, “Fabrication Using Filler Controlled Pyrolysis and Characterization of Polysilazane PDC RTD Arrays on Quartz Wafers,” Sensor Actuat. A-Phys., 175, pp. 53-59 (PDF).
142. Ren, Y., Chen, J.K., and Zhang, Y., 2012, “Modeling of Ultrafast Phase Changes in Metal Films Induced by an Ultrashort Laser Pulse Using a Semi-Classical Two-Temperature Model,” Int. J. Heat Mass Transfer, 55(5-6), pp. 1620-1627 (PDF).
141. Yang, L., Gan, Y., Zhang, Y., and Chen, J.K., 2012, “Molecular Dynamics Simulation of Neck Growth in Laser Sintering of Different-Sized Gold Nanoparticles under Different Heating Rates,” Appl. Phys. A-Mater., 106(3), pp. 725-735 (PDF).
140. Damronglerd, P., and Zhang, Y., Yang, M., 2012, “Numerical Simulation of Solidification of Liquid Copper Saturated in Porous Structures Fabricated by Sintered Steel Particles,” Int. J. Numer. Methods Heat Fluid Flow, 22(1), pp. 94-111 (PDF).
139. Kang, H., Zhang, Y., Yang, M., and Li, L., 2012, “Nonequilibrium Molecular Dynamics Simulation of Coupling between Nanoparticles and Base-Fluid in a Nanofluid,” Phys. Lett. A, 376(4), pp. 521-524 (PDF).
138. Zhou, J., Zhang, Y., Chen, J.K., and Feng, Z.C., 2012, "Inverse Estimation of Front Surface Temperature of a Plate with Laser Heating and Convection-Radiation Cooling,” Int. J. Therm. Sci., 52(1), pp. 22-30 (PDF).
137. Jia, T., Zhang, Y., and Chen, J.K., 2012, “Simulation of Granular Packing of Particles with Different Size Distributions,” Comput. Mater. Sci., 51(1), pp. 172-180 (PDF).
136. Huang, J., Zhang, Y., and Chen, J.K., 2012, “Size Effects during Femtosecond Laser Interaction with Nanosized Metal Particles,” J. Heat Transfer, 134(1), p. 012401 (PDF).
135. Ren, Y., Chen, J.K., and Zhang, Y., 2011, “Optical Properties and Thermal Response of Copper Films Induced by Ultrashort-Pulsed Lasers,” J. Appl. Phys., 110(11), p. 113102 (PDF).
134. Zhao, M., Yang, M., Lu, M., and Zhang, Y., 2011, “Evolution to Chaotic Mixed Convection in a Multiple Ventilated Cavity,” Int. J. Therm. Sci., 50(12), pp. 2464-2472 (PDF).
133. Wang, Z., Yang, M., Li, L., and Zhang, Y., 2011, “Combined Heat Transfer by Natural Convection – Conduction and Surface Radiation in an Open Cavity under Constant Heat Flux Heating,” Numer. Heat Transfer, Part A, 60(4), pp. 289-304 (PDF).
132. Chen, Q., Yang, M., Zhang, Y., and, He, Y.L., 2011, “Numerical Simulation of Melting in Porous Media via an Interfacial Tracking Model,” J. Thermophys. Heat Transfer, 25(3), pp. 401-407 (PDF).
131. Shao, W., and Zhang, Y., 2011, “Effects of Capillary and Gravitational Forces on Performance of an Oscillating Heat Pipe,” Frontiers in Heat Pipes, 2(2), p. 023003 (PDF).
130. Yang, L., Zhang, Y., and Chen, J.K., 2011, “Molecular Dynamics Simulation of Deposition of Nickel Nanocluster on Copper Surface,” J. Nanopart. Res., 13(10), pp. 4479-4489 (PDF).
129. Avedisian, C.T., Bejan, A., Cao, Y., Dhir, V., Howell, J.R., Incropera, F.P., Minkowycz, W. J., Peterson, G.P., Viskanta, R., and Zhang, Y., 2011, “In Celebration: Professor Amir Faghri on his 60th Birthday,” Int. J. Heat Mass Transfer, 54(21-22), pp. 4459-4461 (PDF).
128. Kang, H., Zhang, Y., and Yang, M., 2011, “Molecular Dynamics Simulation of Thermal Conductivity of Cu-Ar Nanofluid Using EAM potential for Cu-Cu Interactions,” Appl. Phys. A-Mater., 103(4), pp. 1001-1008 (PDF).
127. Feng, Z.C., Chen, J.K., Zhang, Y., and Griggs, J.L., 2011, “Estimation of Front Surface Temperature and Heat Flux of a Locally Heated Plate from Distributed Sensor Data on the Back Surface,” Int. J. Heat Mass Transfer, 54(15-16), pp. 3431-3439 (PDF).
126. Zhang, K., Yang, M., and Zhang, Y., 2011, “Numerical Analysis of Natural Convection in a Cylindrical Envelope with an Internal Concentric Cylinder with Slots,” Numer. Heat Transfer, Part A, 59(10), pp. 739-754 (PDF).
125. Faghri, A., and Zhang, Y., 2011, “A Tribute in Memory of Professor Ralph L. Webb (1934–2011),” Frontiers in Heat and Mass Transfer, 2(2), p. 021001b (PDF).
124. Ren, Y., Chen, J.K., Zhang, Y., and Huang, J., 2011, “Ultrashort Laser Pulse Energy Deposition in Metal Films with Phase Changes,” Appl. Phys. Lett., 98(19), p. 191105 (PDF).
123. Jia, T., Zhang, Y., and Chen, J.K., 2011, “Dynamic Simulation of Particle Packing with Different Size Distributions,” J. Manuf. Sci. Eng., 133(2), p. 021011 (PDF).
122. Afrin, N., Zhang, Y., and J., Chen, J.K., 2011, “Thermal Lagging in Living Biological Tissue Based on Nonequilibrium Heat Transfer between Tissue, Arterial and Venous Bloods,” Int. J. Heat Mass Transfer, 54(11-12), pp. 2419-2426 (PDF).
121. Huang, J, Zhang, Y., and Chen, J.K., 2011, “Superheating in Liquid and Solid Phases during Femtosecond-Laser Pulse Interaction with Thin Metal Film,” Appl. Phys. A-Mater., 103(1), pp. 113-121 (PDF).
120. Chen, Q., Zhang, Y., and Yang, M., 2011, “An Interfacial Tracking Model for Convection-Controlled Melting Problems,” Numer. Heat Transfer, Part B, 59(3), pp. 209-225 (PDF).
119. Seo, D., Jung, S., Lombardo, S.L., Feng, Z.C., Chen, J.K., and Zhang, Y., 2011, “Fabrication and Electrical Properties of Polymer-Derived Ceramic (PDC) Thin Films for High-Temperature Heat Flux Sensors,” Sensor Actuat. A-Phys., 165(2), pp. 250-255 (PDF).
118. Huang, J., Baheti, K., Chen, J.K., and Zhang, Y., 2011, “An Axisymmetric Model for Solid-Liquid-Vapor Phase Change in Thin Metal Films Induced by an Ultrashort Laser Pulse,” Frontiers in Heat and Mass Transfer, 2(1), p. 013005 (PDF).
117. Zhao, M., Yang, M., Lu, M., and Zhang, Y., 2011, “Self-Sustained Oscillations and Bifurcations of Mixed Convection in a Multiple Ventilated Enclosure,” Computational Thermal Sciences, 3(1), pp. 63-72 (PDF).
116. Shao, W., and Zhang, Y., 2011, “Effects of Film Evaporation and Condensation on Oscillatory Flow and Heat Transfer in an Oscillating Heat Pipe,” J. Heat Transfer, 133(4), p. 042901 (PDF).
115. Zhou, J., Zhang, Y., Chen, J.K., and Feng, Z.C., 2011, “Inverse Estimation of Surface Heating Condition in a Finite Slab with Temperature-Dependent Thermophysical Properties,” Heat Transfer Eng., 32(10), pp. 861-875 (PDF).
114. Baheti, K., Huang, J., Chen, J.K., and Zhang, Y., 2011, “An Axisymmetric Interfacial Tracking Model for Melting and Resolidification in a Thin Metal Film Irradiated by Ultrashort Pulse Lasers,” Int. J. Therm. Sci., 50(1), pp. 25-35 (PDF).
113. Yang, L., Zhang, Y., and Chen, J.K., 2011, “An Integral Approximate Solution to Ablation of a Two-Layer Composite with a Temporal Gaussian Heat Flux,” Heat Transfer Eng., 32(5), pp. 418-428 (PDF).
112. Huang, J, Zhang, Y., Chen, J.K., and Yang, M., 2011, “Modeling of Ultrafast Phase Change Processes in a Thin Metal Film Irradiated by Femtosecond Laser Pulse Trains,” J. Heat Transfer, 133(3), p. 031003 (PDF).
111. Shao, W., and Zhang, Y., 2011, “Thermally-Induced Oscillatory Flow and Heat Transfer in an Oscillating Heat Pipe,” J. Enhanced Heat Transfer, 18(3), pp. 177-190 (PDF).
110. Feng, Z.C., Chen, J.K., Zhang, Y., and Montgomery-Smith, S., 2010, “Temperature and Heat Flux Estimation from Sampled Transient Sensor Measurements,” Int. J. Therm. Sci., 49(12), pp. 2385-2390 (PDF).
109. Zhou, J., Zhang, Y., Chen, J.K., and Feng, Z.C., 2010, “Inverse Estimation of Spatially and Temporally Varying Heating Boundary Conditions of a Two-Dimensional Object,” Int. J. Therm. Sci., 49(9), pp. 1669-1679 (PDF).
108. Huang, J, Zhang, Y., and Chen, J.K., 2010, “Ultrafast Phase Change during Femtosecond Laser Interaction with Gold Films: Effect of Film Thickness,” Numer. Heat Transfer, Part A, 57(12), pp. 893-910 (PDF).
107. Shi, J., Li, C., Zhang, Y., and Li, H., 2010, “Coupled Heat and Mass Transfer in the Entrance Region of a Circular Tube with Fully-Developed Parabolic Flow and External Convective Heating,” Heat and Mass Transfer, 46(5), pp. 563-570 (PDF).
106. Zhou, J., Zhang, Y., Chen, J.K., and Feng, Z.C., 2010, “Inverse Estimation of Surface Heating Condition in a Three-Dimensional Object Using Conjugate Gradient Method,” Int. J. Heat Mass Transfer, 53(13-14), pp. 2643-2654 (PDF).
105. Chen, T., and Zhang, Y., 2010, “Two-Dimensional Modeling of Sintering of a Powder Layer on Top of Nonporous Substrate,” Frontiers of Mechanical Engineering in China, 5(2), pp. 143-138 (PDF).
104. Feng, Z.C., Chen, J.K., and, Zhang, Y., 2010, “Real-Time Solution of Heat Conduction in a Finite Slab for Inverse Analysis,” Int. J. Therm. Sci., 49(5), pp. 762-768 (PDF).
103. Damronglerd, P., and Zhang, Y., 2010, “Numerical Simulation of Melting in Porous Media via a Modified Temperature-Transforming Model,” J. Thermophys. Heat Transfer, 24(2), pp. 340-347 (PDF).
102. Zhou, J., Zhang, Y., Chen, J.K., and Feng, Z.C., 2010, “Inverse Heat Conduction Using Measured Back Surface Temperature and Heat Flux,” J. Thermophys. Heat Transfer, 24(1), pp. 95-103 (PDF).
101. Li, L., Zhang, Y., Ma, H. B., and Yang, M., 2010, “Molecular Dynamics Simulation of Effect of Liquid Layering around the Nanoparticle on the Enhanced Thermal Conductivity of Nanofluids,” J. Nanopart. Res., 12(3), pp. 811-821 (PDF).
100. Zhang, Y., Damronglerd, P., and Yang, M., 2010, “Analysis of Infiltration, Solidification, and Remelting of a Pure Metal in Subcooled Porous Preform,” Heat Transfer Eng., 31(7), pp. 555-563 (PDF).
99. Zhou, J., Zhang, Y., Chen, J.K., and Feng, Z.C., 2010, “Inverse Heat Conduction in a Composite Slab with Pyrolysis Effect and Temperature-Dependent Thermophysical Properties,” J. Heat Transfer, 132(3), p. 034502 (PDF).
98. Zhou, J., Chen, J.K., and Zhang, Y., 2010, “Simulation of Laser-Induced Thermotherapy Using a Dual-Reciprocity Boundary Element Model with Dynamic Tissue Properties,” IEEE Trans. Biomed. Eng., 57(2), pp. 238-245 (PDF).
97. Xu, J., Zhang, Y., and Ma, H. B., 2009, “Effect of Internal Wick Structure on Liquid-Vapor Oscillatory Flow and Heat Transfer in an Oscillating Heat Pipe,” J. Heat Transfer, 131(12), p. 121012 (PDF).
96. Zhang, Y., Li, L., Ma, H. B., and Yang, M., 2009, “Effect of Brownian and Thermophoretic Diffusions of Nanoparticles on Nonequilibrium Heat Conduction in a Nanofluid Layer with Periodic Heat Flux,” Numer. Heat Transfer, Part A, 56(4), pp. 325-341 (PDF).
95. Zhang, Y., 2009, “Generalized Dual-Phase Lag Bioheat Equations Based on Nonequilibrium Heat Transfer in Living Biological Tissues,” Int. J. Heat Mass Transfer, 52(21-22), pp. 4829-4834 (PDF).
94. Huang, J., Zhang, Y., and Chen, J.K., 2009, “Ultrafast Solid-Liquid-Vapor Phase Change in a Thin Gold Film Irradiated by Multiple Femtosecond Laser Pulses,” Int. J. Heat Mass Transfer, 52(13-14), pp. 3091-3100 (PDF).
93. Huang, J., Zhang, Y., and Chen, J.K., 2009, “Ultrafast Solid-Liquid-Vapor Phase Change of a Gold Film Induced by Pico- to Femtosecond Lasers,” Appl. Phys. A-Mater., 95(3), pp. 643–653 (PDF).
92. Zhou, J., Zhang, Y., and Chen, J.K., 2009, “Numerical Simulation of Random Packing of Spherical Particles for Powder-Based Additive Manufacturing,” J. Manuf. Sci. Eng., 131(3), p. 031004 (PDF).
91. Zhou, J., Zhang, Y., and Chen, J.K., 2009, “Numerical Simulation of Laser Irradiation to a Randomly Packed Bimodal Powder Bed,” Int. J. Heat Mass Transfer, 52(13-14), pp. 3137-3146 (PDF).
90. Zhou, J., Zhang, Y., and Chen, J.K., 2009, “An Axisymmetric Dual-Phase-Lag Bioheat Transfer Model for Laser Heating of Living Tissues,” Int. J. Therm. Sci., 48(8), pp. 1477-1485 (PDF).
89. Zhou, J., Chen, J.K., and Zhang, Y., 2009, “Dual-Phase Lag Effects on Thermal Damage to Biological Tissues Caused by Laser Irradiation,” Comput. Biol. Med., 39(3), pp. 286-293 (PDF).
88. Xu, J., and, Zhang, Y., 2009, “Analysis of Heat Transfer during Liquid-Vapor Pulsating Flow in a U-Shaped Miniature Channel,” J. Enhanced Heat Transfer, 16(4), pp. 367-385 (PDF).
87. Jiao, A., Zhang, Y., Ma, H. B., and Critser, J., 2009, “Effects of Lewis Number on Coupled Heat and Mass Transfer in a Circular Tube Subjected to External Convective Heating,” Heat and Mass Transfer, 45(5), pp. 591-598 (PDF).
86. Zhou, J., Zhang, Y., and Chen, J.K., 2009, “Effects of Large Blood Vessels on the Transient Propagation of Ultrafast Laser Pulse in Biological Tissues,” Heat and Mass Transfer, 45(5), pp. 527-535 (PDF).
85. Shi, Y., and Zhang, Y., 2009, “A Semi-Exact Solution for Solidification of a Binary Solution on a Cold Isothermal Surface below Eutectic Temperature,” Heat Transfer Eng., 30(5), pp. 368-374 (PDF).
84. Xiao, B., and Zhang, Y., 2009, “Numerical Simulation of Pulsatile Turbulent Flow in Tapering Stenosed Arteries,” Int. J. Numer. Methods Heat Fluid Flow, 19(5), pp. 561-573 (PDF).
83. Zhang, Y., and Chen, J.K., 2008, “Ultrafast Melting and Resolidification of Gold Particle Irradiated by Pico- to Femtosecond Lasers,” J. Appl. Phys., 104, p. 054910 (PDF).
82. Shi, Y., and Zhang, Y., 2008, “Simulation of Random Packing of Spherical Particles with Different Size Distributions,” Appl. Phys. A-Mater., 92(3), pp. 621-626 (PDF).
81. Li, L., Zhang, Y., Ma, H. B., and Yang, M., 2008, “An Investigation of Molecular Layering at the Liquid-Solid Interface in Nanofluids by Molecular Dynamics Simulation,” Phys. Lett. A, 372(25), pp. 4541–4544 (PDF).
80. Zhang, Y., and Ma, H. B., 2008, “Nonequilibrium Heat Conduction in a Nanofluid Layer with Periodic Heat Flux,” Int. J. Heat Mass Transfer, 51 (19-20), pp. 4862-4874 (PDF).
79. Zhou, J., Zhang, Y., and Chen, J.K., 2008, “A Dual Reciprocity Boundary Element Method for Photothermal Interactions in Laser-Induced Thermotherapy,” Int. J. Heat Mass Transfer, 51 (15-16), pp. 3869-3881 (PDF).
78. Wang, S., and Zhang, Y., 2008, “Forced-Convection Heat Transfer of Microencapsulated Phase-Change Material Suspensions Flow in a Circular Tube Subject to External Convective Heating,” J. Enhanced Heat Transfer, 15(2), pp. 171-181 (PDF).
77. Li, L., Yang, M., and Zhang, Y., 2008, “Numerical Study of Periodically Fully-Developed Convection in Channels with Periodically Grooved Parts,” Int. J. Heat Mass Transfer, 51(11-12), pp. 3057-3065 (PDF).
76. Ma, H. B., Borgmeyer, B., Cheng, P., and Zhang, Y., 2008, “Heat Transport Capability in an Oscillating Heat Pipe,” J. Heat Transfer, 130(8), p. 081501 (PDF).
75. Xiao, B., and Zhang, Y., 2008, “Numerical Simulation of Direct Metal Laser Sintering of Single-Component Powder on Top of Sintered Layers,” J. Manuf. Sci. Eng., 130(4), p. 041002 (PDF).
74. Zhang, Y., and Chen, J.K., 2008, “An Interfacial Tracking Method for Ultrashort Pulse Laser Melting and Resolidification of a Thin Metal Film,” J. Heat Transfer, 130(6), p. 062401 (PDF).
73. Zhou, J., Zhang, Y., Chen, J.K., and Smith, D. E., 2008, “A Nonequilibrium Thermal Model for Rapid Heating and Pyrolysis of Organic Composites,” J. Heat Transfer, 130(6), p. 064501 (PDF).
72. Zhou, J., Zhang, Y., and Chen, J.K., 2008, “Non-Fourier Heat Conduction Effect on Laser-Induced Thermal Damage in Biological Tissues,” Numer. Heat Transfer, Part A, 54(1), pp. 1-19 (PDF).
71. Zhang, Y., and Faghri, A., 2008, “Advances and Unsolved Issues in Pulsating Heat Pipes,” Heat Transfer Eng., 29(1), pp. 20-44 (PDF).
70. Zhou, J., Chen, J.K., and Zhang, Y., 2008, "Numerical Modeling of Transient Progression of Plasma Formation in Biological Tissues Induced by Short Laser Pulses,” Appl. Phys. B-Lasers, 90(1), pp. 141-148 (PDF).
69. Shi, Y., Zhang, Y., and Konrad, C., 2007, “Solid-Liquid-Vapor Phase Change of a Subcooled Metal Powder Particle Subjected to Nanosecond Laser Heating,” Nanoscale Microscale Thermophys. Eng., 11(3-4), pp. 301-318 (PDF).
68. Xiao, B., and Zhang, Y., 2007, “Laser Sintering of Metal Powders on Top of Sintered Layers under Multiple-Line Laser Scanning,” J. Phys. D: Appl. Phys., 40(21), pp. 6725-6734 (PDF).
67. Zhou, J., Chen, J.K., and Zhang, Y., 2007, “Theoretical Analysis of Thermal Damage in Biological Tissues Caused by Laser Irradiation,” Mol. Cell. Biomec., 4(1), pp. 27-39 (PDF).
66. Zhang, Y., and Chen, J.K., 2007, “Melting and Resolidification of Gold Film Irradiated by Nano- to Femtosecond Lasers,” Appl. Phys. A-Mater., 88(2), pp. 289-297 (PDF).
65. Zhou, J., Zhang, Y., and Chen, J.K., 2007, “Numerical Simulation of Compressible Gas Flow and Heat Transfer in a Microchannel Surrounded by Solid Media,” Int. J. Heat Fluid Flow, 28(6), pp. 1484-1491 (PDF).
64. Chen, T., and Zhang, Y., 2007, “Three-Dimensional Modeling of Laser Sintering of a Two-Component Metal Powder Layer on Top of Sintered Layers,” J. Manuf. Sci. Eng., 129(3), pp. 575-582 (PDF).
63. Xiao, B., and Zhang, Y., 2007, “Analysis of Melting of Alloy Powder Bed with Constant Heat Flux,” Int. J. Heat Mass Transfer, 50(11-12), pp. 2161-2169 (PDF).
62. Konrad, C., Zhang, Y., and Shi, Y., 2007, “Melting and Resolidification of a Subcooled Metal Powder Particle Subjected to Nanosecond Laser Heating,” Int. J. Heat Mass Transfer, 50(11-12), pp. 2236-2245 (PDF).
61. Chen, T., and Zhang, Y., 2007, “Thermal Modeling of Laser Sintering of Two-Component Metal Powder on Top of Sintered Layers via Multi-line Scanning,” Appl. Phys. A-Mater., 86(2), pp. 213-220 (PDF).
60. Damronglerd, P., and Zhang, Y., 2007, “Modified Temperature-Transforming Model for Convection-Controlled Melting,” J. Thermophys. Heat Transfer, 21(1), pp. 203-208 (PDF).
59. Xiao, B., and Zhang, Y., 2007, “Marangoni and Buoyancy Effects on Direct Metal Laser Sintering with a Moving Laser Beam,” Numer. Heat Transfer, Part A, 51(7-8), pp. 715-733 (PDF).
58. Xiao, B., and Zhang, Y., 2007, “Analysis of Partial Melting in Metal Powder Bed with Constant Heat Flux,” Heat Transfer Eng., 28(5), pp. 472-483 (PDF).
57. Zhou, J., Yu, A., and Zhang, Y., 2007, “A Boundary Element Method for Evaluation of the Effective Thermal Conductivity of Packed Beds,” J. Heat Transfer, 129(3), pp. 363-371 (PDF).
56. Zhang, Y., 2006, “Nonequilibrium Modeling of Heat Transfer in a Gas-Saturated Powder Layer Subject to a Short-Pulsed Heat Source,” Numer. Heat Transfer, Part A, 50(6), pp. 509-524 (PDF).
55. Chen, T., and Zhang, Y., 2006, “Analysis of Melting in a Subcooled Two-Component Metal Powder Layer with Constant Heat Flux,” Appl. Therm. Eng., 26(7), pp. 751-765 (PDF).
54. Chen, T., and Zhang, Y., 2006, “A Partial Shrinkage Model for Selective Laser Sintering of a Two-Component Metal Powder Layer,” Int. J. Heat Mass Transfer, 49(7-8), pp. 1489-1492 (PDF).
53. Xiao, B., and Zhang, Y., 2006, “Partial Melting and Resolidification of Metal Powder in Selective Laser Sintering,” J. Thermophys. Heat Transfer, 20(3), pp. 439-448 (PDF).
52. Damronglerd, P. and Zhang, Y., 2006, “Transient Fluid Flow and Heat Transfer in a Porous Structure with Partial Heating and Evaporation on the Upper Surface,” J. Enhanced Heat Transfer, 13(1), pp. 53-64 (PDF).
51. Chen, T., and Zhang, Y., 2006, “Three-Dimensional Modeling of Selective Laser Sintering of Two-Component Metal Powder Layers,” J. Manuf. Sci. Eng., 128(1), pp. 299-306 (PDF).
50. Ma, Z. H., and Zhang, Y., 2006, “Solid Velocity Correction Schemes for a Temperature Transforming Model for Convection Phase Change,” Int. J. Numer. Methods Heat Fluid Flow, 16(2), pp. 204-225 (PDF).
49. Boyden, S., and Zhang, Y., 2006, “Temperature and Wavelength-Dependent Spectral Absorptivities of Metallic Materials in the Infrared,” J. Thermophys. Heat Transfer, 20(1), pp. 9-15 (PDF).
48. Konrad, C., Zhang, Y., and Xiao, B., 2005, “Analysis of Melting and Resolidification in a Two-Component Metal Powder Bed Subjected to Temporal Gaussian Heat Flux,” Int. J. Heat Mass Transfer, 48(19-20), pp. 3932-3944 (PDF).
47. Zhang, Y., 2004, “A Simulation-Based Correlation of Cross-Sectional Area of the Thin Film Produced by Laser Chemical Vapor Deposition with a Moving Laser Beam,” J. Manuf. Sci. Eng., 126(4), pp. 796-800 (PDF).
46. Chen, T., and Zhang, Y., 2004, “Numerical Simulation of Two-Dimensional Melting and Resolidification of a Two-Component Metal Powder Layer in Selective Laser Sintering Process,” Numer. Heat Transfer, Part A, 46(7), pp. 633-649 (PDF).
45. Zhang, Y., 2004, “Effect of Natural Convection on Laser Chemical Vapor Deposition with a Stationary Laser Beam,” Int. J. Heat Fluid Flow, 25 (4), pp. 683-691 (PDF).
44. Zhang, Y., 2003, “Quasi-Steady State Natural Convection in Laser Chemical Vapor Deposition using a Moving Laser Beam,” J. Heat Transfer, 125(3), pp. 429-437 (PDF).
43. Zhang, Y., and Faghri, A., 2003, “Oscillatory Flow in Pulsating Heat Pipes with Arbitrary Numbers of Turns,” J. Thermophys. Heat Transfer, 17(3), pp. 340-347 (PDF).
42. Zhang, Y., 2002, “Coupled Forced Convective Heat and Mass Transfer in a Circular Tube with External Convective Heating,” Prog. Comput. Fluid Dyn., Int. J., 2(2-4), pp. 90-96 (PDF).
41. Shafii, M. B., Faghri, A., and Zhang, Y., 2002, “Analysis of Heat Transfer in Unlooped and Looped Pulsating Heat Pipes,” Int. J. Numer. Methods Heat Fluid Flow, 12(5), pp. 585-609 (PDF).
40. Zhang, Y., Faghri, A., and Shafii, M.B., 2002, “Analysis of Liquid-Vapor Pulsating Flow in a U-shaped Miniature Tube ,” Int. J. Heat Mass Transfer, 45(12), pp. 2501-2508 (PDF).
39. Zhang, Y., and Faghri, A., 2002, “Heat Transfer in a Pulsating Heat Pipe with Open End,” Int. J. Heat Mass Transfer, 45(4), pp. 755-764 (PDF).
38. Shafii, M. B., Faghri, A., and Zhang, Y., 2001, “Thermal Modeling of Unlooped and Looped Pulsating Heat Pipes,“ J. Heat Transfer,123(6), pp. 1159-1172 (PDF).
37. Zhang, Y., and Faghri, A., 2001, "Numerical Simulation of Condensation on a Capillary Grooved Structure,” Numer. Heat Transfer, Part A, 39(3), pp. 227-243 (PDF).
36. Zhang, Y., Faghri, A., Shafii, M. B., 2001, “Capillary Blocking in Forced Convective Condensation in Horizontal Miniature Channels,” J. Heat Transfer, 123(3), pp. 501-511 (PDF).
35. Zhang, Y., and Faghri, A., 2000, “Thermal Modeling of Selective Area Laser Deposition of Titanium Nitride on a Finite Slab with Stationary and Moving Laser Beams,” Int. J. Heat Mass Transfer, 43(20), pp. 3835-3846 (PDF).
34. Zhang, Y., Faghri, A., Buckley, C.W., and Bergman, T.L., 2000, “Three-Dimensional Sintering of Two-Component Metal Powders with Stationary and Moving Laser Beams,” J. Heat Transfer, 122(1), pp. 150-158 (PDF).
33. Zhang, Y., and Faghri, A., 1999, “Vaporization, Melting and Heat Conduction in the Laser Drilling Process,” Int. J. Heat Mass Transfer, 42(10), pp. 1775-1790 (PDF).
32. Zhang, Y., and Faghri, A., 1999, “Melting of a Subcooled Mixed Powder Bed with Constant Heat Flux Heating,” Int. J. Heat Mass Transfer, 42(5), pp. 775-788 (PDF).
31. Zhang, Y., and Faghri, A., 1998, “Melting and Resolidification of a Subcooled Mixed Powder Bed with Moving Gaussian Heat Source,” J. Heat Transfer, 120(4), pp. 883-891 (PDF).
30. Zhang, Y., and Faghri, A., 1998, “A Thermal Model for Mushy Zone Formation in Binary Solutions,” J. Sol. Energy Eng., 120(2), pp. 144-147 (PDF).
29. Zhang, Y., and Faghri, A., 1997, “Analysis of Freezing in an Eccentric Annulus,” J. Sol. Energy Eng., 119(3), pp. 237-241 (PDF).
28. Zhang, Y., Chen, Z.Q., and Faghri, A., 1997, “Heat Transfer During Solidification around a Horizontal Tube with Internal Convective Cooling,” J. Sol. Energy Eng., 119(1), pp. 44-47 (PDF).
27. Zhang, Y., and Faghri, A., 1996, “Heat Transfer Enhancement in Latent Heat Thermal Energy Storage System by Using the Internally Finned Tube,” Int. J. Heat Mass Transfer, 39(15), pp. 3165-3173 (PDF).
26. Zhang, Y., and Faghri, A., 1996, “Heat Transfer Enhancement in Latent Heat Thermal Energy Storage System by Using an External Radial Finned Tube,” J. Enhanced Heat Transfer, 3(2), pp. 119-127 (PDF).
25. Zhang, Y., and Faghri, A., 1996, “An Integral Approximate Solution of Heat Transfer in the Grinding Process,” Int. J. Heat Mass Transfer, 39(13), pp. 2653-2662 (PDF).
24. Zhang, Y., and Faghri, A., 1996, “Semi- Analytical Solution of Thermal Energy Storage System with Conjugate Laminar Forced Convection,” Int. J. Heat Mass Transfer, 39(4), pp. 717-724 (PDF).
23. Zhang, Y., Chen, Z.Q., and Chen, M., 1996, “Local Non-Similarity Solution of Coupled Heat-Mass Transfer of a Flat Plate with Uniform Heat Flux in a Laminar Parallel Flow,” J. Thermal Science, 5(2), pp. 112-116 (PDF).
22. Chen, M., and Zhang, Y., 1995, “Letter to the Editor,” Applied Mathematical Modeling, 19(8), p. 510.
21. Zhang, Y., and Faghri, A., 1995, “Analysis of Thermal Energy Storage System with Conjugate Turbulent Forced Convection,” J. Thermophys. Heat Transfer, 9(4), pp. 722-726 (PDF).
20. Zhang, Y., and Faghri, A., 1995, “Analysis of Forced Convection Heat Transfer in Microencapsulated Phase Change Material Suspensions,” J. Thermophys. Heat Transfer, 9(4), pp. 727-732 (PDF).
19. Zhang, Y., and Chen, Z.Q., 1994, “Effect of Wall Conduction on Melting in an Enclosure Heated at Constant Rate,” Int. J. Heat Mass Transfer, 37(2), pp. 340-343 (PDF).
18. Zhang, Y., Chen, Z.Q., and Wang, Q.J., 1994, “Analysis of Melting in an Enclosure with Discrete Heating at Constant Rate,” Int. J. Heat Fluid Flow, 15(1), pp. 79-82 (PDF).
17. Zhang, Y., and Ju, Y., 1994, “Analysis of Solidification in the Presence of High Rayleigh Number Convection in an Enclosure,” J. Thermal Science, 3(3), pp. 173-176 (PDF).
16. Zhang, Y., W. Li and Chen, Z.Q., 1994, “Heat Transfer on an Aligned Tube Bank with Enlarged First Row Tube,” J. Xi’an Jiaotong Univ., 28(9), 44-50 (PDF).
15. Zhang, Y., Chen, Z.Q., Wang, Q.J., and Wu, Q.J., 1994, “Numerical Solution of Melting in a Rectangular Cavity with Discrete Heat Sources,” Chinese J. Computat. Phys., 11(1), pp. 9-16 (PDF).
14. Chen, M., Zhang, Y., and Chen, Z.Q., 1994, “Solidification in a Concentric Annulus with Boundary Conditions of the Third Kind,” Acta Energiae Solaris Sinica, 15(1), pp. 43-49 (PDF).
13. Dan, J., Zhang, Y., and Chen, Z.Q., 1994, “Heat Transfer and Pressure Drop Characteristics for Non-Standard Staggered Fin Array with Top Clearance Aligned Parallel to an Air Flow,” Acta Energiae Solaris Sinica, 15(2), pp. 147-152 (PDF).
12. Ju, Y., Zhang, Y. and Chen, Z.Q., 1994, “Studies on Thermal Performance of Fin Array with Coupled Radiation and Convection,” J. Gansu Sciences, 6(3), pp. 27-30 (PDF).
11. Zhang, Y., Jin, Y.Y., Chen, Z.Q., Dong, Z.F., and Ebadian, M.A., 1993, “An Analytical Solution to Melting in a Finite Slab with a Boundary Condition of the Second Kind,” J. Heat Transfer, 115(2), pp. 463-467 (PDF).
10. Zhang, Y., Chen, Z.Q., Wang, Q.J., and Wu, Q.J., 1993, “Melting in an Enclosure with Discrete Heating at Constant Rate,” Exp. Therm. Fluid Sci., 6(2), pp. 196-201 (PDF).
9. Zhang, Y., and Chen, Z.Q., 1993, “Solidification around Horizontal Cylinder Controlled by Natural Convection,” Acta Energiae Solaris Sinica, 14(4), pp. 357-363 (PDF).
8. Zhang, Y., Chen, Z.Q., and Wang, Q.J., 1993, “Analytical Solution of Melting in a Subcooled Semi- Infinite Solid with Boundary Condition of the Second Kind,” J. Thermal Science, 2(2), pp. 111-115 (PDF).
7. Zhang, Y., and Ju, Y., 1993, “Flow Patterns and Thermal Drag in a One-Dimensional Inviscid Channel with Heating or Cooling,” J. Thermal Science, 2(4), pp. 266-269 (PDF).
6. Zhang, Y., and Chen, Z.Q., 1993, “Fully Automatic Measuring System of Local Mass/Heat Transfer Coefficient,” Experimental Technique and Management, 10(2), pp. 33-35 (PDF).
5. Zhang, Y., Chen, Z.Q., and Liu, X.D., 1993, “ Radiative Heat Transfer of an Isolated Phase Circular Bus with Slots,” Electric Power Construction, 14(7), pp. 1-2 (PDF).
4. Zhang, Y., Chen, Z.Q., and Dong, Z.F., 1993, “Thermodynamic Analysis of Latent Heat Energy Storage System,” J. Gansu Sciences, 5(3), pp. 28-32 (PDF).
3. Zhang, Y., and Chen, Z.Q., 1992, “The Effect of a Gap between Layers on the Heat Transfer Performance of Aligned Tube Banks,” Heat Transfer Eng., 13(2), pp. 33-41 (PDF).
2. Zhang, Y., and Chen, Z.Q., 1992, “Analytical Solution of Coupled Laminar Heat-Mass Transfer in a Tube with Uniform Heat Flux,” J. Thermal Science, 1(3), 184-188 (PDF).
1. Zhang, Y., and Chen, Z.Q., 1989, “Numerical Analysis of Fin Surface with Radiation and Convection,” J. Engineering Thermophys., 10(1), pp. 69-71 (PDF).