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288 results on '"Zheng‐Hong Luo"'

1. Review on Blood Flow Dynamics in Lab-on-a-Chip Systems: An Engineering Perspective

Author

Bin-Jie Lai, Li-Tao Zhu, Zhe Chen, Bo Ouyang, and Zheng-Hong Luo

Subjects
Chemical engineering, TP155-156, Biotechnology, TP248.13-248.65
Abstract

Under different transport mechanisms, blood flow dynamics, heavily linked to the flow shear rate conditions, in “lab-on-a-chip” (LOC) systems are found to result in varying transport phenomena. This Review examines the blood flow patterns in LOC systems through the role of viscoelastic properties such as dynamic blood viscosity and elastic behavior of the red blood cells. The study of blood transport phenomena in LOC systems through key parameters of capillary and electro-osmotic forces is provided through experimental, theoretical, and numerous numerical approaches. The disturbance triggered by electro-osmotic viscoelastic flow is particularly discussed and applied in the enhancement of the mixing and separating capabilities of LOC devices handling blood and other viscoelastic fluids for future research opportunities. Furthermore, the Review identifies the challenges in the numerical modeling of blood flow dynamics under the LOC systems, such as the call for more accurate and simplified blood flow models and the emphasis on numerical studies of viscoelastic fluid flow under the electrokinetic effect. More practical assumptions for zeta potential conditions while studying the electrokinetic phenomena are also highlighted. This Review aims to provide a comprehensive and interdisciplinary perspective on blood flow dynamics in microfluidic systems driven by capillary and electro-osmotic forces.

Published
2024
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17. Cyclic extrusion synthesis of mesoporous carbon‐supported metal catalysts for selective hydrogenation

Author

Pengfei Zhang, Jialu Xu, Shengtai Hou, Qiang Niu, and Zheng-Hong Luo

Subjects
Environmental Engineering, General Chemical Engineering, Biotechnology
Abstract

The mesoporous carbon-supported metal catalysts are important materials in heterogeneous catalysis. From the standpoint of process intensification, the current synthesis methods still suffer from several issues, such as the excessive use of toxic solvents, the time-consuming self-assembly process, and the difficulty of continuous production. Herein, we report a solvent-free and continuous route to synthesize mesoporous carbon-supported metal catalysts. Interestingly, the use of cyclic extrusion could promote the mixing, coordination, and assembly of catalyst precursors (tannin-metal salts-additives) by shearing and squeeze force. The as-made mesoporous carbon-supported nickel showed high surface areas (up to 512m2g-1), narrow pore size distribution (~10 nm), and good performance in the selective hydrogenation of nitrobenzene to aniline (Conv.>99%; Sel.>99%). In addition, the fluid property of catalyst precursors and the geometry of the twin-screw extrusion channel were studied, and the essence of this cyclic extrusion process is also discussed.

Published
2023

21. Contributors

Author

Maryam Peter Abraham, Peter Abraham, Charles Oluwaseun Adetunji, Juliana Bunmi Adetunji, Eleonora Alfinito, Francisco J. Arraez, Md. Ashrafuzzaman, Lázaro A.M. Castanedo, Rosella Cataldo, Tânia Cova, Dagmar R. D’hooge, Wadzani Palnam Dauda, Dhurvas Chandrasekaran Dinesh, Mariya Edeleva, Peyman Fahimi, Márcio Ferreira, Freddy L. Figueira, Elkanah Glen, Virendra Kumar Gupta, Chidi Nnamdi Ifechukwude, Kehinde Kazeem Kanmodi, Basil Raju Karimadom, Satyajit Khatua, Haya Kornweitz, Jugal Kumawat, Zheng-Hong Luo, Yoshi W. Marien, Lou Massa, Chérif F. Matta, Pedro Maximiano, Jean-Francois Millithaler, Daji Morumda, Lawrence Achilles Nnyanzi, Sandra Nunes, Alberto Pais, Tanmoy Kumar Paul, Divya Rai, Kaushik Rajaram, Paola Rondon-Villarreal, Hemant Sarin, Chandrabose Selvaraj, Sumit Sharma, Pedro Nuno Simões, Sanjeev Kumar Singh, Katarzyna Staszak, Maciej Staszak, Srivignesh Sundaresan, Srabani Taraphder, Jince Thomas, Minu Elizabeth Thomas, Sabu Thomas, Paul H.M. Van Steenberge, Carla Vitorino, Yi-Yang Wu, Le Xie, Radhey Shyam Yadav, and Yin-Ning Zhou

Published
2023

23. Ring Repeating Unit: A Deterministic Structure Representation of Polymers for Property Predictions

Author

Mengxian Yu, Yajuan Shi, Qingzhu Jia, Qiang Wang, Zheng-Hong Luo, Fangyou Yan, and Yin-Ning Zhou

Abstract

Deterministic structure representation of polymers plays a crucial role in developing models for polymer property prediction and polymer design by data-centric approaches. Currently, unique structure representations of polymers, especially the polymers with heteroatomic backbones, are unavailable. In this contribution, we propose a so-called ring repeating unit (RRU) method that can uniquely represent polymers with a broad range of structure diversity. To prove the rationality of RRU-based structure representation for generating feature descriptors, a quantitative structure property relationship (QSPR) model for glass transition temperature (Tg) was established for 1321 polyimides with good accuracy (R2 = 0.8793). Comprehensive model validations including external, internal, and Y-random validations were performed, providing Tg prediction result with an average absolute error (AAE) of 19.38 ℃. It is believed that the as-developed RRU method allows for dealing with any macromolecular structure and targeted property, enabling for reliable polymer property prediction and high-performance polymer design by data-driven approaches.

Published
2022

37. Coarse-grid simulations of full-loop gas-solid flows using a hybrid drag model: Investigations on turbulence models

Author

Qun-Jie Xu, Wei-Cheng Yan, Li-Tao Zhu, Jun-Sen Li, Zheng-Hong Luo, and Taha Abbas Bin Rashid

Subjects
Physics, Turbulence, General Chemical Engineering, Flow (psychology), Mesoscale meteorology, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Grid, Instability, Physics::Fluid Dynamics, 020401 chemical engineering, Drag, Fluidization, Fluidized bed combustion, 0204 chemical engineering, 0210 nano-technology
Abstract

The effect of fluid turbulence models on the coarse-grid simulation for the mesoscale gas-solid flow system is not as clear as that for gas-liquid/single flows. In this study, the effect of different turbulence models on predictions of riser-only, turbulent and bubbling flow hydrodynamics is quantified. Then the selected turbulence models are examined by coarse-grid simulations in a full-loop circulating fluidized bed (CFB) with a proposed hybrid drag model which integrates two SGMs and Hulin-Gidaspow model. Results show that the standard k-epsilon and k-omega models fail to capture a correct fluidization pattern in riser. Meanwhile, the RNG and realizable k-epsilon models and SST k-omega model enable satisfactory predictions which are highly comparable to discrete model predictions and experiments over different flow regimes. However, the realizable k-epsilon model produces more pronounced flow fluctuations causing computational instability. Using superior turbulence closures, full-loop simulations with the proposed hybrid model can predict desirable hydrodynamics.

Published
2021

38. Kinetic study for the oxidation of cyclohexanol and cyclohexanone with nitric acid to adipic acid

Author

Guangxiao Li, De-Tao Pan, Zheng-Hong Luo, Huilong Wei, and Yuanhai Su

Subjects
Environmental Engineering, Adipic acid, Chemistry, General Chemical Engineering, Induction period, Inorganic chemistry, Cyclohexanol, Cyclohexanone, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Biochemistry, Polyester, chemistry.chemical_compound, 020401 chemical engineering, Catalytic oxidation, Nitric acid, Yield (chemistry), 0204 chemical engineering, 0210 nano-technology
Abstract

The adipic acid is an important intermediate in the production of nylon, polyurethane and polyester resins. The industrial approach for preparing adipic acid is through the liquid catalytic oxidation of KA oil with nitric acid. In this work, a comprehensive model is developed for this reaction based on the kinetic study conducted in a continuous flow tubular reactor. The kinetic model fits well with the experimental results across the experimental conditions, and the average relative error between the calculated and experimental values is 5.7%. Results show that there was an induction period at the early stage of reaction. Moreover, it is found that at temperature range of 328–358 K, the formation rate of adipic acid strongly dependents on the temperature and nitric acid concentration. The developed model is used to predict the yield of adipic acid at 359–368 K. The work in this study could provide much knowledge for industrial tubular reactor design.

Published
2021

39. Coupled matrix kinetic Monte Carlo simulations applied for advanced understanding of polymer grafting kinetics

Author

Paul Van Steenberge, Freddy L. Figueira, Dagmar R. D'hooge, Yi-Yang Wu, Yin-Ning Zhou, and Zheng-Hong Luo

Subjects
Fluid Flow and Transfer Processes, chemistry.chemical_classification, Work (thermodynamics), Materials science, Process Chemistry and Technology, Grafting (decision trees), Monte Carlo method, Thermodynamics, Chain transfer, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Matrix (mathematics), chemistry, Chemistry (miscellaneous), Chemical Engineering (miscellaneous), Kinetic Monte Carlo, Polystyrene, 0210 nano-technology
Abstract

One of the challenges for modelling of polymerization kinetics is the detailed description of the molecular build-up of both linear and non-linear chains, specifically those with many grafts and crosslinks. Such grafted/crosslinked (co)polymers are relevant as emulsifiers, surface-modifying agents, coating materials, and compatibilizers. In the present work, we put forward a coupled matrix-based Monte Carlo (CMMC) concept to be successful in this respect, avoiding computational stiffness. The CMMC concept is illustrated for single phase grafting of polybutadiene (PB) with styrene (St) at 343 K by limiting the St conversion to 30%. Considering literature kinetic parameters, a benchmark for average characteristics as obtainable by deterministic method of moments simulations is first presented to then gradually extend the level of modelling output addressing (i) conventional grafting performance indicators (e.g. the grafting yield and mass ratio); (ii) univariate chain length distributions for all macrospecies types (polystyrene, PB, PB with only T grafts, PB with at least one H graft, etc.); (iii) bivariate St–butadiene distributions showing a compositional drift, due to the kinetic tendency to attack longer chains if they are sufficiently present and the competition between grafting and crosslinking; (iv) the explicit molecular build-up of individual molecules predicting the positioning of the St–Bd and St–St connectivity points and the chain formation history. It is demonstrated that the CMMC tool allows the simulation of the contribution and structure of molecules that are hard to access purely experimentally, so that in the long run, novel structure–property relationships are within reach. It is also showcased that consideration of elementary reactions is highly recommended and that even at 343 K, thermal self-initiation with St and related chain transfer reactions matter for a full appreciation of molecular variations. The current work also opens the pathway to identifying pragmatic equations for the experimentalist and online control benefiting from a detailed CMMC solution under any desired conditions.

Published
2021

40. 'Living' Polymer Dispersity Quantification for Nitroxide-Mediated Polymerization Systems by Mimicking a Monodispersed Polymer Blending Strategy

Author

Yin-Ning Zhou, Tian-Tian Wang, Zheng-Hong Luo, and Yi-Yang Wu

Subjects
chemistry.chemical_classification, Nitroxide mediated radical polymerization, Materials science, Polymers and Plastics, Organic Chemistry, Dispersity, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Inorganic Chemistry, Polymerization, Chemical engineering, chemistry, Materials Chemistry, 0210 nano-technology
Abstract

The quantification of dispersity is an indispensable part of characterizing polymers. In this work, general dispersity equations for “living” polymers obtained by nitroxide-mediated polymerization ...

Published
2020

41. CFD-PBM Simulation of Bubble Columns: Sensitivity Analysis of the Nondrag Forces

Author

Zheng-Hong Luo, Xi-Bao Zhang, and Wei-Cheng Yan

Subjects
Physics, business.industry, General Chemical Engineering, Bubble, Work (physics), 02 engineering and technology, General Chemistry, Mechanics, Computational fluid dynamics, Physics::Classical Physics, 021001 nanoscience & nanotechnology, Turbulent dispersion, Industrial and Manufacturing Engineering, Bubble induced turbulence, Physics::Fluid Dynamics, 020401 chemical engineering, Drag, Lubrication, Sensitivity (control systems), 0204 chemical engineering, 0210 nano-technology, business
Abstract

In this work, the effect of non-drag forces (lift force, turbulent dispersion force, wall lubrication force and virtual mass force) and bubble induced turbulence (BIT) on the CFD-PBM simulation of ...

Published
2020

42. Kinetic Study on Ultraviolet Light-Induced Solution Atom Transfer Radical Polymerization of Methyl Acrylate Using TiO2

Author

Jinjin Li, Chao Bian, Yin-Ning Zhou, Yuan-Xing Liu, and Zheng-Hong Luo

Subjects
Materials science, Atom-transfer radical-polymerization, General Chemical Engineering, Kinetics, technology, industry, and agriculture, General Chemistry, medicine.disease_cause, Kinetic energy, Photochemistry, Industrial and Manufacturing Engineering, Titanium oxide, chemistry.chemical_compound, chemistry, Polymerization, medicine, Methyl acrylate, Ultraviolet
Abstract

The kinetics of the ultraviolet light-induced solution atom transfer radical polymerization (ATRP) of methyl acrylate using titanium oxide (TiO2) was investigated through experiments and modeling b...

Published
2020

43. Comparative analysis of numerically derived drag models for development of bed expansion ratio correlation in a bubbling fluidized bed

Author

Zheng-Hong Luo, Taha Abbas Bin Rashid, and Li-Tao Zhu

Subjects
Physics::Fluid Dynamics, Pressure drop, Expansion ratio, Work (thermodynamics), Materials science, Mechanics of Materials, Drag, Fluidized bed, General Chemical Engineering, Flow (psychology), Kinetic theory of gases, Development (differential geometry), Mechanics
Abstract

For designing and operating fluidized bed reactors, bed expansion ratio is one of the most important parameters. In this research, a bubbling fluidized bed is simulated using three-dimensional Eulerian-Eulerian method that is incorporated with kinetic theory of granular flow (KTGF) to calculate the pressure drop, gas volume fraction (GVF) and bed expansion ratio. Grid optimization is firstly conducted to achieve suitable solution for further simulations. Subsequently, different numerically derived drag models are employed to investigate the effect of these models on gas-solid flow dynamics. Afterwards, the fluidized bed is simulated at different gas superficial velocities employing two different drag models respectively. Simulation results have been comprehensively validated against experimental data. Finally, an expression for bed expansion ratio has been formulated and compared with the empirical correlation. The proposed correlation holds reasonably well with various experimental values. This work provides a scalable way to aid in designing and operating process reactors.

Published
2020

44. Effect of granular properties on hydrodynamics in coarse-grid riser flow simulation of Geldart A and B particles

Author

Zheng-Hong Luo, Li-Tao Zhu, and Taha Abbas Bin Rashid

Subjects
geography, Work (thermodynamics), Materials science, geography.geographical_feature_category, Turbulence, General Chemical Engineering, Flow (psychology), Laminar flow, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Inlet, Physics::Fluid Dynamics, Viscosity, 020401 chemical engineering, SCALE-UP, Fluidization, 0204 chemical engineering, 0210 nano-technology
Abstract

In this work, a three-dimensional coarse-grid two-fluid model (TFM) simulation by varying granular properties like granular viscosity, frictional viscosity, and solids pressure has been performed. Simulated predictions were subsequently compared with experimental results in the case of Geldart A or B particles. Laminar flow behavior is also studied and coarse-grid simulation predictions were less realistic for laminar flow. This flow regime which although consumes less computational resources falls short for large-scale riser scale up. Flow regime in our simulation was fast fluidization and simulation predicts with minimum error near riser inlet. More specifically, granular viscosity, frictional viscosity and solids pressure for Type A particles predict with minimum error especially near riser inlet at a lower height. For Type B particles, these three solid properties correspond closely with experimental results near inlet at a lower height whereas, at a higher height, turbulence increases and simulation results deviate from experimental studies.

Published
2020

46. Explicit Stochastic Modeling of Termination Chain Length Dependencies for All Disparate Radical Pairs in Single Phase Free Radical Induced Grafting

Author

Freddy L. Figueira, Alessandro D. Trigilio, Yi-Yang Wu, Yin-Ning Zhou, Zheng-Hong Luo, Paul H.M. Van Steenberge, and Dagmar R. D'hooge

Subjects
History, Polymers and Plastics, General Chemical Engineering, Environmental Chemistry, General Chemistry, Business and International Management, Industrial and Manufacturing Engineering
Published
2022

47. Cost‐efficient modeling of distributed molar mass and topological variations in graft copolymer synthesis by upgrading the method of moments

Author

Yi‐Yang Wu, Freddy L. Figueira, Mariya Edeleva, Paul H. M. Van Steenberge, Dagmar R. D'hooge, Yin‐Ning Zhou, and Zheng‐Hong Luo

Subjects
Technology and Engineering, Environmental Engineering, CROSS-LINKING, STYRENE, General Chemical Engineering, RAFT POLYMERIZATION, bivariate distributions, CHEMICAL-COMPOSITION, grafting, nonlinear polymers, numerical fractionation, SIZE-EXCLUSION CHROMATOGRAPHY, chromatography, MULTIPLE-DETECTION, GRADIENT INTERACTION CHROMATOGRAPHY, LIQUID-CHROMATOGRAPHY, MOLECULAR-WEIGHT DISTRIBUTION, Biotechnology, FREE-RADICAL COPOLYMERIZATION
Abstract

Cost-efficient deterministic method of moments solvers, as widely used to calculate average characteristics of chemical processes driven by population variations (e.g., average chain lengths), can be a posteriori extended with approximated solutions delivering distributed properties (e.g., chain length distributions). However, these solutions are rarely verified, specifically for complex systems with many population members and strong coupling, as is the case for industrially relevant free-radical-induced grafting (FRIG) toward graft copolymer (GC) synthesis with monomer unit dependent reactions. FRIG, as studied in the present work with polybutadiene at low styrene conversions, is an important chemical process, for example, the production of compatibilizers and high-impact materials. Deterministic model validation is uniquely performed by benchmarking the low to medium molar mass (MM) results (29 topologies) in the log-molar mass distribution with detailed matrix-based kinetic Monte Carlo simulation output, inherently capable of mapping distributions. The GC product is identified to be a heterogeneous mixture in MM, chemical composition, and molecular topology at any styrene conversion. The molecular structural evolution during GC synthesis is further theoretically related to both one-dimensional size-exclusion chromatography (1D-SEC) and two-dimensional liquid chromatography (2D-LC) analysis. It is shown that conventional SEC-even in the absence of broadening-is insufficient for GC separation, mainly due to the unavoidable coelution of topologically different GC species. In any case, the parallel running of advanced modeling tools allows for detailed molecular interpretation.

Published
2022

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