| In press |
Electromagnetic heating of gold nanoparticle dispersions at 200kHz
H Chen, D. Wen, Nanomedicine, in press |
Flow boiling heat transfer in minichannel heat sinks under sub-atmospheric pressures
X Hu, G Lin, C Yan, D. Wen, Experimental Heat Transfer, in press |
High power calibration and measurement method for bio-electromagnetic study
X Liu, H Chen, X Chen, D Wen, C Parini , IET Electronics Letters, in press |
Performance assessement of a minichannel heat sink using water and FC-72 as the coolants
X.Hu, G Lin, Y Cai, D. Wen, Heat Transfer Engineering |
2012 |
Comparative analysis of CFD models for jetting fluidized beds: The effect of inter-phase drag force
P Pei, K Zhang, D. Wen, Powder Technology 221, 114-122 |
Comparative analysis of CFD models for jetting fluidized beds: the effect of particle phase viscosity.
P Pei, K Zhang, G Xu, Y Yang, D. Wen, Particuology, 10-4, 444–449
|
Convective heat transfer of aqueous alumina nanosuspension in a horizontal minichannel.
S Vafaei, D. Wen, Heat and Mass Transfer , 48-2, 349-357 |
Discrete particle modeling of granular temperature distribution in a bubbling fluidized bed Original
Y He, T Wang, N Deen, M Annaland, H Kuipers, D. Wen, Particuology, 10-4, 428-437
|
Experimental study of a nitrogen-charged cryogenic loop heat pipe
L Bai, G Lin, H. Zhang, J Miao, D. Wen, Cryogenics, Vol 52 (10), 557–563
|
Hydrodynamics of a fluidized bed co-combustor with tobacco waste
K Zhang, B Yu, J Chang, T Wang, D Wen, Bioresource Technology. 119, 339-348 |
Influence of nanoparticles on boiling heat transfer
D. Wen, Applied Thermal Engineering, 41, 2-9 |
Low frequency heating of gold nanoparticle dispersions for non-invasive thermal therapies
X, Liu, H, Chen, X, Chen, C. Parini, D. Wen, NANOSCALE, 4-13, 3945-3953 |
Operating characteristics of a miniature cryogenic loop heat pipe
L Bai, G Lin, H Zhang, J Miao, D. Wen, International Journal of Heat and Mass Transfer, vol 55, 8093–8099
|
Preface for 13th Brazilian congress of thermal science and engineering
F Bandarra, D. Wen, Applied Thermal Engineering, 41, 1 |
UV-Cross-Linkable Multilayer Microcapsules Made of Weak Polyelectrolytes
Q, Yi, D. Wen, G. Sukhorukov, Langmuir, 28- 29, 10822-10829 |
2011 |
Boiling heat transfer of nanofluids: the effect of heating surface modification.
D. Wen, M. Corr, X Hu,G Lin, International Journal of Thermal Science, 50, 480-485 |
BUBBLE GROWTH RATE FROM A STAINLESS STEEL SUBSTRATE AND NEEDLE NOZZLES,
S Vafaei, P Angeli, D. Wen , Colloids and Surfaces A: Physicochemical and Engineering Aspects, 384, 240– 247 |
Dynamic characteristics of binary mixtures in a two-jet fluidized bed
P. Pei, K. Zhang, B.Yu, J.Gao, G.Wu, D. Wen, Chemical Engineering Science.66(8), 1702-1714 |
Experimental study Of flow boiling Of FC-72 in parallel minichannels under sub-atomspheric pressures
X.Hu, G Lin, Y Cai, D. Wen, Applied Thermal Engineering, 31 (17-18), 3839-3853 |
Flow boiling heat transfer of alumina nanofluids in single microchannels and the roels of nanoparticles
S Vafaei D. Wen, Journal of Nanoparticle Research, 13(3), 1063-1073 |
Modeling and Analysis of Supercritical Startup of a Cryogenic Loop Heat Pipe
L Bai, G Lin, GP Peterson, D. Wen, JOURNAL OF HEAT TRANSFER-TRANSACTIONS OF THE ASME,133(12),121501 |
Nanofluids Surface Wettability Through Asymtotic Contact Angle.
S Vafaei, D. Wen, T. Borca-Tasciuc, Langmuir, 27 (6), pp 2211–2218 |
Removal of antimony in the flotation wastewater from antimony mine by electrocoagulation with aluminum electrodes.
J Zhu, F Wu, X Pan, D. Wen, Journal of Environmental Sciences,23(7), 1066–1071 |
Spreading of triple line and dynamics of bubble growth inside nanoparticle disperisons on top of a substrate plate
S.Vafaei, D. Wen, Journal of Colloid and Interface Science, 362, 285-291 |
Thermal oxidation of iron nanoparticles and its implication for chemical-looping combustion
D. Wen, P. Song, K Zhang, J Qian, Journal of Chemical Technology & Biotechnology,86(3),375-380 |
Ultrasonic aided fabrication of nanofluids
H Chen, D. Wen, Nanoscale Research Letters, 6,198 |
2010 |
Bubble formation in a quiescent pool of gold nanoparticle suspension
S.Vafaei D. Wen, Advances in Colloid and Interface Science, 159(1), 72-93 |
Bubble formation on a submerged micronozzle
S. Vafaei, D. Wen, Journal of Colloid and Interface Science, 343, 1, 291-297 |
CFD simulation of a gas-solid fluidized bed with two vertical jets
P Pei, K Zhang, J Ren, D. Wen, Particuology, doi:10.1016/j.partic.2010.08.001 |
CFD simulation of jet behaviors in a binary gas-solid fluidized bed: comparisons with experiments
P Pei, G Wu, K Zhang, B Yu, J Jiang D. Wen, Frontiers of Chemical Engineering in China, 4(3), 242-249 |
Critical heat flux (CHF) of subcooled flow boiling of alumina nanofluid in a horizontal microchannel.
S Vafaei, D. Wen, ASME Journal of Heat Transfer, 132 (10),102404 |
Effect of gold nanoparticles on the dynamics of gas bubbles
S. Vafaei, D. Wen, Langmuir, 26 (10), pp 6902–6907 |
Experimental and Theoretical Invesigation of Quasi Steady State Bubble Growth on Top of Submerged Stainless Steel Nozzles
S. Vafaei, T. Borca-Tasciuc, D. Wen, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 369,11-19 |
Experimental investigation of a dual compensation chamber loop heat pipe.
G Lin, N Li, L Bai, D. Wen, International Journal of Heat and Mass Transfer. 53 (15-16), pp3231-3240 |
Experimental study of jet structure and pressurisation upon liquid nitrogen injection into water
H. Clark, A. Martinez-Herasme, R Crookes, D. Wen, International Journal of Multiphase Flow, 36(11-12), 940-949
|
Modeling and analysis of startup of a loop heat pipe
L. Bai, G. Lin, D. Wen, Applied Thermal Engineering, 30 (17-18), 2778-2787 |
Molecular dynamic simulation of heating and cooling of a core-shell structured metallic nanoparticle.
P Song D. Wen, The Journal of Physical Chemistry C, 114 (19), pp 8688–8696 |
Nanofuel as a potential secondary energy carrier
D. Wen, Energy and Environmental Science, 3, 591-600. |
Parametric analysis of steady-state operation of a CLHP
L.Bai, G. Lin, D. Wen, Applied Thermal Engineering, 30, 850-858 |
Surface melting and sintering of metallic nanoparticles
P. Song D. Wen, Journal of Nanoscience and Nanotechnology, 10, 8010-8017 |
The effect of gold nanoparticles on the spreading of triple line
S. Vafaei, D. Wen, Microfluidics and Nanofluidics, 8(6) 843-848 |
Viscosity mesurement on colloidal dispersion (Nanofluids) for heat transfer applications
D Venerus J Buongiorno .. D. Wen..., Applied Rheology, 20(4), 44582 |
2009 |
A benchmark study on the thermal conductivity of nanofluids
J Buongiorno,D Venerus, ..... D. Wen..., Journal of Applied Physics 106, 094312 |
CFD simulation of bubbling and collapsing characteristics in a gas-solid fluidized bed
P Pei, K Zhang,E Liu and D Wen, Journal of Petroleum Science, 6:69-75 |
Experimental investigation of startup behaviors of a dual compensation chamber loop heat pipe with insufficient fluid inventory
L Bai, G. Lin, D. Wen, J Feng, Applied Thermal Engineering, 29, 1447-1456 |
Experimental Investigation of the Oxidation of Tin Nanoparticles
P. Song, D. Wen, J. Phys. Chem. C 2009, 113, 13470–13476 |
Flow and migration of nanoparticles in a single channel
D. Wen, L Zhang, Y He, Heat and Mass Transfer 45, 1061-1067 |
Intracellular hyperthermia: nanobubbles and their biomedical applications.
D. Wen, International Journal of Hyperthermia. 25-7, 533-541 |
Mathematical modeling of steady state operation of a loop heat pipe
L. Bai G Lin H. Zhang, D. Wen, Applied Thermal Engineering, vol 29, 2643-2654 |
Molecular dynamics simulation of the sintering of metallic nanoparticles
P.Song, D. Wen, Journal of Nanoparticle Research, 12 (3), 823-829. |
Review of nanofluids for heat transfer applications
D. Wen, G. Lin, S. Vafaei, K Zhang, Journal of Partriology, 7, 141-150 |
2008 |
Effect of grid scale, time step and maximum solid volume fraction on CFD simulation in a jetting fluidized bed
P Pei, K. Zhang and D. Wen, Journal of Processing Engineering, 8, 1057-1063 |
Mechanisms of thermal nanofluids on enhanced critical heat flux (CHF)
D. Wen, International Journal of Heat and Mass Transfer. 51:4958-4965 |
On the role of structural disjoining pressure to boiling heat transfer with thermal nanofluids
D. Wen, Journal of Nanoparticle Research, 10: 1129-1140 |
Oxidation investigation of nickel nanoparticles
P.Song, D. Wen, Z. Guo, T. Korakianitis, Physical Chemistry Chemical Physics, 10(33):5057-65 |
Phase change heat transfer of liquid nitrogen in an aqueous based TiO2 nanofluids
D. Wen, Y. Ding, G. Lin, Journal of Nanoparticle Research, 10:987-996 |
Supercritical fluids techniques for clean biofuel production
D. Wen, H Jiang and K Zhang , Progress in Natural Science, 19, 273-284 |
2007 |
Gas-solid suspension heat transfer through a packed bed
D. Wen, T. Cong, Y. He, H. Chen, Y Ding, Chemical Engineering Science 62, 4241-4249 |
Heat transfer of gas-solid two-phase mixtures flowing through a packed bed under constant wall heat flux conditions
T Cong, Y He, H.Chen, Y. Ding, D. Wen, Chemical Engineering Journal, 130, 1-10 |
2006 |
CFD modelling of cocurrent gas-solid flow through a packed bed using kinetic theory approach
S. Li, Y. Ding, D. Wen, Y. He , Chemical Engineering Science, 61, 1922-1931 |
Confined growth of a vapour bubble in a capillary tube at initially uniform superheat: Experiments and modelling
D. Kenning, D. Wen, K. Das, S. Wilson, International Journal of Heat and Mass Transfer, 49: 4653-4671 |
Heat transfer of aqueous suspensions of carbon nanotubes (CNT nanofluids)
Y.Ding, H. Alias, D. Wen, R. Williams, International Journal of Heat and Mass Transfer, 49: 240-250
|
Heat transfer of gas flow through a packed bed
D. Wen, Y. Ding, Chemical Engineering Science, 61: 3532-3542 |
Liquid nitrogen injection into water: Pressure build-up and heat transfer
D. Wen, Y. Ding, H. Chen, P. Dearman, Cryogenics, 46: 740-748 |
Measurement of the convective heat transfer of TiO2 nano-fluids
Y. Jin, Y. Ding, D. Wen, D. Cang, Y.Zong, Energy for Metallurgical Industry, 25: 47-50 |
Natural convective heat transfer of suspensions of titanium dioxide nanoparticles (nanofluids)
D. Wen. Y. Ding, IEEE Transactions on Nanotechnology, 5: 220-227
|
Pool boiling heat transfer of aqueous TiO2-based nanofluids
D. Wen, Y. Ding, R. Williams, Journal of Enhanced Heat Transfer, 13: 231-244
|
Preface for Journal of Chemical Technology and Biotechnology
C. Xu, D. Wen, Journal of Chemical Technology and Biotechnology, 81: 731 |
Solid behaviour in a dilute gas-solid two-phase mixture flowing through monolith channels
Y. Ding, Z. Wang, D. Wen, M. Ghadiri, X. Fan, D. Parker, Chemical Engineering Science, 61, 1561-1570 |
2005 |
Effect of particle migration on heat transfer in suspensions of nanoparticles flowing through minichannels
D. Wen, Y. Ding, Microfluidics and Nanofluidics, 1: 183-189 |
Experimental investigation into the pool boiling heat transfer of aqueous based γ-alumina nanofluids
D. Wen, Y. Ding, Journal of Nanoparticle Research, 7: 265-274
|
Formulation of nanofluids for natural convective heat transfer applications
D. Wen, Y. Ding, International Journal of Heat and Fluid Flow, 26: 855-864
|
Hydrodynamics of gas-solid two-phase mixtures flowing upward through packed beds
Y. Ding, Z. Wang, D. Wen, M.Ghadiri, Powder Technology, 153: 13-22
|
Influence of dry patches dynamics on transition boiling
D. Wen, L. Chai, International Journal of Heat and Technology, 23: 1-6
|
Nanofluids turn up the heat
D. Wen, Y. Ding, R. Williams, The Chemical Engineer: 771: 32-34
|
Numerical study on the gas fluidisation of secondary agglomerates of nanoparticles
Y. He, H. Lu, D. Wen, Y Ding, Progress in Natural Science, 15: 111-116 |
Particle migration in a flow of nanoparticle suspensions
Y.Ding, D. Wen, Powder Technology, 149: 84-92
|
Preface: Green Chemistry and Future Energy
D. Wen, Progress in Natural Science 15: 1 |
Solids behaviour in a gas-solid two-phase mixture flowing through a packed particle bed
Y.Ding, Z. Wang, D. Wen, M. Ghadiri, X Fan, D Parker, Chemical Engineering Science, 60: 5231-5239
|
Theoretical analyses on boiling critical heat flux with porous media
L. Chai, D. Wen, Heat and Mass Transfer, 41: 780-784
|
Vertical upward flow of gas-solid two-phase mixtures through monolith channels
Y.Ding, Z.Wang, M.Ghadiri, D. Wen, Powder Technology, 153: 51-58
|
2004 |
Effective thermal conductivity of aqueous suspensions of carbon nanotubes (carbon nanotube nanofluids)
D. Wen, Y. Ding, Journal of Thermophysics and Heat Transfer, 18: 481-485
|
Experimental investigation into convective heat transfer of nanofluids at the entrance region under laminar flow conditions
D. Wen, Y. Ding, International Journal of Heat and Mass Transfer, 47: 5181-5188
|
Hierarchical self-organization of complex systems
L. Chai, D. Wen, Chemical Research in Chinese Universities, 20: 440-445 |
Saturated flow boiling of water in a narrow channel: Time-averaged heat transfer coefficients and correlations
D. Wen, Y. Yan, D. Kenning, Applied Thermal Engineering, 24: 1207-1223
|
Two-phase pressure drop of water during flow boiling in a vertical narrow channel
D. Wen, D. Kenning, Experimental Thermal and Fluid Science, 28: 131-138
|
2002 |
Effects of surface wettability on nucleate pool boiling heat transfer for surfactant solutions
D. Wen, B. Wang, International Journal of Heat and Mass Transfer, 45: 1739-1747 |
Examination of the mass-heat transfer analogy for two-phase flows in narrow channels: Comparison of gas bubble enhancement of membrane separation and heat transfer to vapour bubbles in boiling
S. Smith, T. Taha, D. Wen, Z. Cui, D. Kenning, Chemical Engineering Research and Design, 80: 729-738 |
Revision on Rohsenow model for nucleate boiling of liquid with considering the effect of surface wettability
B. Wang, C. Li, D. Wen, X. Peng, Journal of Engineering Thermophysics, 23: 79-84 |
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