27 September 2025, Volume 46 Issue 10

    

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  Review of Experimental Studies on the Catalytic Conversion of Ortho-para Hydrogen

  XU Sheng, ZHU Shaolong, FANG Song, QIU Limin, WANG Kai

  Journal of Engineering Thermophysics. 2025, 46(10): 3143-3158.

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  Ortho-para hydrogen conversion is an indispensable process in hydrogen liquefaction system. This paper summarizes the experimental research progress of ortho-para hydrogen conversion, comprehensively compares the advantages and disadvantages of various ortho-para hydrogen conversion schemes, analyzes the differences between typical ortho-para hydrogen catalysts, such as iron hydroxide and oxide catalysts and supported nickel catalysts, in terms of the activation methods and catalytic efficiencies, and further summarizes various measurement methods for ortho-para hydrogen concentrations as well as their measurement principles. Regarding the selection of catalysts for ortho-para hydrogen conversion, the literature findings indicate that supported nickel-based catalysts have higher catalytic efficiencies, but taking full consideration of catalyst preparation, activation, deactivation, and liquefier operating requirements, iron hydroxide as well as its oxide catalysts are still the mainstream catalysts for application-oriented catalytic choices. Among the measurement methods of ortho-para hydrogen fractions, compared with spectroscopy, acoustic velocity measurement, nuclear magnetic resonance, enthalpy measurement, etc., the ortho-para hydrogen concentration measurement based on thermal conductivity method has comprehensive advantages in terms of accuracy, response speed, economy and operability, which can be used as the preferred solution for the measurement of ortho-para hydrogen concentration. As large-scale hydrogen liquefaction plants are developing towards the direction of higher efficiency, compactness and reliability, continuous conversion is the mainstream solution for ortho-para hydrogen conversion in the future hydrogen liquefaction processes. However, at present, most of the domestic studies on continuous ortho-para hydrogen conversion remain in conceptual analysis and process application, lacking data on hydrogen conversion, flow and heat transfer under cryogenic conditions, as well as relevant high-precision correlation equations. Based on the measured data of continuous catalysis and cooling of orthopara hydrogen, the development of high-precision correlations for heat transfer, pressure drop and catalysis of hydrogen eat exchangers, and the accurate design of heat exchangers for continuous ortho-para hydrogen conversion, will be an urgent task to be carried out in the future.
  
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  Research on Optimal Dispatching of Power System of Concentrating Solar Power Based on Improved Snake Optimization Algorithm

  MA Xiaojing, LIAO Qinpei, QING Ziyi, CHAI Li, WANG Man, WANG Ruihuan

  Journal of Engineering Thermophysics. 2025, 46(10): 3159-3169.

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  In view of the randomness of the initial population diversity and limited local optimal ability of the snake optimization algorithm, an Improved Particles Transmit Information Snake Optimization (IPTISO) algorithm is proposed. By using a strategy to update the worst individual in different stages of egg laying, the global search ability and local search ability of the algorithm are balanced, and Circle chaotic mapping is introduced in the initial stage to improve the diversity of the population. At the same time, a pheromone induction method was introduced to change individual characteristics during the fighting and mating stages. By using the above improved method and introducing the green certificate-carbon trading mechanism, the power system of 1 concentrated solar power station and 10 thermal power units is solved, and various scheduling scenarios are analyzed and compared with other classical algorithms. The results show that compared with other algorithms, IPTISO algorithm can obtain the optimal economic and environmental scheduling scheme, which provides a new way to solve the optimal scheduling problem of power system.
  
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  Thermodynamic Analysis of a CO₂-based Combined Cooling, Heating, Power and Fuel System

  HUANG Shengqi, ZHAO Yao, CUI Liming

  Journal of Engineering Thermophysics. 2025, 46(10): 3170-3176.

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  Multi-energy co-generation systems are crucial for improving energy efficiency, enhancing system flexibility, and integrating various energy sources for end users. This paper proposes a largescale, cross-seasonal, and cross-regional CO₂-based combined cooling, heating, power and fuel system. A thermodynamic model of the system is developed to investigate the effects of parameters such as CO₂ mass flow coefficient, internal waste heat, compression/expansion stages, and intercooler outlet temperature on system performance. The results show that as the ratio of CO₂ mass flow rate within the CO₂ energy storage module to that captured by the direct air capture module increases from 200 to 600, the system energy utilization factor improves from 75% to 85%. When the expansion stage number is 3, 4, 5, 6, 8, 10, 11, 13 and 15, the system begins to generate cooling energy at higher compression stages. When the compression and expansion stages are 14 and 5, the system energy utilization factor reaches its maximum value of 105%. The optimal electrical roundtrip efficiency and system energy utilization factor are 70% and 105%, respectively.
  
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  Study on Effects of Key Parameters on a Novel Combined Cooling, Heating, and Power Generation System Integrated With Chemical Looping Hydrogen Generation

  LI Xinlu, DUAN Liqiang, WANG Qiushi, CHENG Siyu

  Journal of Engineering Thermophysics. 2025, 46(10): 3177-3187.

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  A combined cooling heating and power (CCHP) system integrated with chemical looping hydrogen generation(CLHG), molten carbonate fuel cell(MCFC) and organic Rankine cycle (ORC) is proposed. Methane is used as fuel, and hydrogen produced from chemical chain process is used to drive MCFC for power generation. The system is integrated with ORC, dual effect lithium bromide absorption refrigeration cycle, and heating subsystem to realize the energy cascade utilization and improve energy utilization efficiency. On the base of the first and second laws of thermodynamics, the study analyzes the impacts of key parameters on the new system performance. The research results show that under rated operating conditions, the energy efficiency and exergy efficiency of the new system are 67.66% and 50.47%, respectively. Compared with the MCFC-ORC CCHP system without integrating with chemical-looping hydrogen generation under the same conditions, the energy efficiency of the new system increases by 2.44%, the exergy efficiency increases by 0.65%, and the MCFC efficiency increases by 1.58%.
  
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  Study on Thermodynamic Performance of Compressed Air Gas Storage Device in Idle Oil and Gas Wells

  SU Chuanxin, WANG Guorong, JING Jiajia, ZHONG Lin, LIN Zhiyu

  Journal of Engineering Thermophysics. 2025, 46(10): 3188-3196.

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  In order to solve the problem of the abandonment of a large number of idle oil and gas Wells and the absorption of green electricity in oil fields, the paper innovatively proposes the use of idle oil and gas Wells as gas storage devices for compressed air energy storage system. Exergic model and exergic model have been established to reveal the change law of thermodynamic performance of idle oil and gas Wells in different operating pressure ranges and injection/production flow rates under the coupling effect of air gravity and formation temperature, and exergic efficiency and energy storage of idle oil and gas Wells in 7”well shafts have been studied. The results show that in the single injection and production simulation, the temperature changes greatly in the well depth of 200 m, the temperature changes increase with the well depth of 200 m to 3000 m, and the wellhead pressure is positively correlated with the air pressure gradient in the well. At fixed injection/production flow rate, exergy efficiency of exergy in well bower is the highest and fluctuates around 100.25%, with energy storage more than 1.4 times that of conventional steel tank gas storage device of the same water volume. Exergic flow matching curve with exergic efficiency approaching 100% was selected at a fixed operating pressure interval.
  
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  Control Method of Stability-Enhancement and Efficiency-Improvement of Controllable-Aerodynamic-Shape Compressor

  HU Chunjing, ZHANG Min, DU Juan, ZHANG Jian, WANG Sichen, NIE Chaoqun

  Journal of Engineering Thermophysics. 2025, 46(10): 3197-3207.

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  A control method of stability-enhancement and efficiency-improvement of controllableaerodynamic-shape compressor is proposed in this paper. The application of stator-blade and rotortip injections based on the Coanda effect are being considered in the 1.5 stage transonic axial flow compressor, aiming to achieve stability and efficiency improvements across full operating conditions. Firstly, the design of the controllable-aerodynamic-shape rotor/stator is carried out. Secondly, the impact of injection slot positions on the compressor performance was analyzed. Then impacts of injection mass flow rate on the stability and efficiency improvements of the aerodynamic controllable were investigated. It is found that only the injection slot position of the stator-blade injections being placed before the occurrence of flow instability can inhibit flow separation. As the jet mass flow increases, the ability of the aerodynamic controllable stator to control flow separation enhances. Moreover, the coupling of aerodynamic controllable stator-blade and rotor-tip injections can improve stability and efficiency simultaneously, with an efficiency increased by about 1.21% and a maximum flow margin improvement by 14.17%.
  
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  Effects of Hot Streaks on Aerodynamic Excitation of High Pressure Turbine Rotor Blade

  LI Ruiquan, ZHANG Weihao, ZHANG Ruifeng, WANG Yufan, HUANG Dongming, MU Chengyu

  Journal of Engineering Thermophysics. 2025, 46(10): 3208-3216.

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  The effects of hot streaks on unsteady aerodynamic excitation and their underlying mechanisms are investigated through unsteady numerical simulations. Additionally, the significance and independence of the impacts induced by hot streaks and wakes/potential fields are analyzed. Result shows that under hot streak inlet conditions, the relative flow angle at the rotor inlet exhibits a wider variation range compared to uniform inlet conditions. This enhanced flow unsteadiness leads to intensified pressure fluctuations on the rotor blade surface and increased aerodynamic force amplitudes. Particularly, the influence of hot streaks becomes very pronounced when aligned with the passage center. Spectral proper orthogonal decomposition (SPOD) analysis reveals that hot streaks exert stronger impacts on aerodynamic excitation than wakes/potential fields, while their effects almost remain mutually independent. These findings provide critical insights for optimizing aerodynamic and structural designs in turbine engineering.
  
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  Design and Off-design Performance Prediction of Liquid-gas Phase Change Carbon Dioxide Centripetal Turbine

  WANG Kaixin, GONG Wuqi, GAO Xinyi, WANG Fang

  Journal of Engineering Thermophysics. 2025, 46(10): 3217-3226.

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  The turbine is one of the important components in the transcritical CO₂ heat pump. The performance of the turbine will directly affect the efficiency of the whole system. Based on the flow theory of turbomachinery this paper established the design method and off-design performance prediction method of the liquid-gas phase change CO₂ centripetal turbine. According to the thermodynamic parameters of a transcritical CO₂ heat pump cycle, a carbon dioxide centripetal turbine with two-phase flow was designed, and the designed turbine was numerically analysed by CFD method. The results show that the performance of the designed turbine meets the parameter requirements; under the rated working conditions, the proportion of gaseous CO₂ components at the outlet of the impeller reaches 19.2%; compared with the numerical calculation results, the deviation of the prediction results is within 5%.
  
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  A Review of the Design of Supercritical Carbon Dioxide Centrifugal Compressor

  CHENG Liu, ZHANG Kexin, ZHANG Hualiang, CHEN Peng

  Journal of Engineering Thermophysics. 2025, 46(10): 3227-3244.

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  In recent years, the supercritical carbon dioxide Brayton dynamic cycle has become a research hotspot due to its high thermal economy, wide application scenarios and high development prospects. Starting from the application background of supercritical carbon dioxide Brayton power cycle, this paper analyzes the main performance indicators, application models and development trends of circulating systems in different scenarios, and points out the main research hotspots and difficulties of supercritical carbon dioxide centrifugal compressors, which are the core components of circulating systems. It is found that the special physical properties of supercritical carbon dioxide bring many new problems for compressor design that are different from traditional compressor design. Therefore, this paper focuses on the compressor design, and comprehensively reviews the one-dimensional, quasi-three-dimensional and three-dimensional design processes and design experience of the supercritical carbon dioxide centrifugal compressors. In one-dimensional design, the one-zone model is the main method for performance prediction. In comparison, the accuracy of efficiency prediction of this model is far less than that of pressure ratio prediction. Moreover, the lack of abundant experimental data to correct the traditional empirical formula restricts the applicability of one-dimensional design. In quasi-three-dimensional design, the streamline curvature method is proved to be more suitable for supercritical carbon dioxide centrifugal compressors. Full three-dimensional design and optimization methods have gradually become the main technical path. However, due to the complex flow mechanism and high design difficulty, this paper has analyzed the phenomena such as carbon dioxide condensation, tip clearance leakage and flow separation caused by the special physical properties of the working medium and outlined the optimization and improvement measures. On this basis, the current experimental research is summarized, the feasibility of supercritical carbon dioxide centrifugal compressor is preliminarily verified, and then the flow rules found in the experiment and the problems worth attention are summarized. Finally, the problems and development trends that need to be solved in compressor design and experimental research in the future are presented.
  
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  Study on Energy Loss Characteristics of Double-Suction Centrifugal Pump Under Pump and Turbine Operation

  PAN Jiale, LU Hongzhong, WANG Fujun, TAO Ran, WANG Chaoyue

  Journal of Engineering Thermophysics. 2025, 46(10): 3245-3250.

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  The reverse operation of pumps as turbines (PAT) is a common and economical method for energy recovery in engineering applications. Previous studies have revealed a certain correlation between the performance of centrifugal pumps under pump operation and reverse operation as turbines. However, most research has focused on single-stage, single-suction centrifugal pumps. There is a lack of in-depth understanding of the energy characteristics during normal and reverse operation of double-suction centrifugal pumps. In this paper, computational fluid dynamics (CFD) methods was employed to determine the degree of flow rate deviation between optimal operating points under bidirectional operation of a double-suction centrifugal pump. Additionally, the energy loss distribution in main components under both pump and turbine operation was quantified. This study contributes to the improvement of understanding of the differences in energy characteristics between normal and reverse operation of double-suction centrifugal pumps. It also provides theoretical guidance for the pump and turbine operation and coordinated optimization of double-suction centrifugal pumps. 
  
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  Impact of Gradient Porosity Structure in Gas Diffusion Layer on the Performance of Proton Exchange Membrane Fuel Cells

  CHEN Xin, YE Dingding, WANG Yang, ZHU Xun, YANG Yang, CHEN Rong, LIAO Qiang

  Journal of Engineering Thermophysics. 2025, 46(10): 3251-3257.

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  There are complex water management problems at the cathode of proton exchange membrane fuel cells, and the gas-liquid transport process in the gas diffusion layer is crucial. In order to improve the cathode water management capability, four kinds of gas diffusion layers with different oriented gradient porosity structures were proposed. A three-dimensional non-isothermal two-phase proton exchange membrane fuel cell mathematical model was established, in which the mass transfer loss was modified by setting the limiting current density. The influence of the gradient porosity structure on the gas-liquid two-phase transport and cell performance was investigated. The results show that the diffusion layer structure with higher porosity near the catalyst layer and the cathode inlet can effectively reduce the cathode liquid water saturation, enhance the oxygen transport and improve the electrochemical performance of the cell at high current densities. Moreover, the gradient porosity structure has little effect on the performance at low current densities. 
  
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  Study on the Influence Laws of Mixing Quality for Multi-chamber Continuous Mixing

  FAN Chao, ZHANG Pengchao, WEI Zongliang, MA Ning, QIN Neng, XIE Zhongyuan

  Journal of Engineering Thermophysics. 2025, 46(10): 3258-3263.

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  In this study, a CFD numerical model for the mixing of multi-component materials in a multi-chamber kneader was established, with a certain cast polymer bonded explosive (PBX) as the research object. Based on the model, research on the influencing laws of blade rotation speed, kneading clearance and blade combination on mixing uniformity was carried out. The results show that increasing the blade rotation speed significantly improves the mixing quality, and a blade rotation speed of 45 r·min⁻¹ is sufficient to meet the mixing quality requirements. Increasing the kneading gap of two blades is not conducive to the full mixing of materials, and its influence is less significant than that of the blade rotation speed. Besides, compared with the two-wing-two-wing blade combination, the four-wing-two-wing blade combination exhibits higher mixing efficiency. This study can provide guidance for the establishment of quality control methods for multi-chamber mixing processes, as well as the optimal design of equipment and technological processes.
  
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  Effects of Injection Pressure and Mixing Chamber Diameter on Gas-Liquid Flow and Spray of the Air-Assisted Nozzle

  YANG Yizhou, HUANG Yunlong, ZHANG Ying, LU Kang, GUO Genmiao, HE Zhixia

  Journal of Engineering Thermophysics. 2025, 46(10): 3264-3271.

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  This study integrates background light high-speed imaging technology with numerical simulation to investigate the effects of key parameters, such as injection pressure and mixing chamber diameter, on the gas-liquid flow characteristics and near-field spray morphology of air-assisted nozzles. The study elucidates the regulation mechanism of gas-liquid interaction in the atomization process. The results indicate that under non-air-assisted conditions, increasing the injection pressure promotes the transition of fuel cavitation from its initial stage to a super-cavitation state, significantly enhancing jet atomization. In air-assisted conditions, the introduction of high-pressure air suppresses the phase transition process and increases the spray cone angle. When the injection pressure remains constant, increasing the air pressure effectively improves the jet breakup process. Under the same air pressure, the spray cone angle of different nozzles initially increases and then decreases with rising injection pressure. Specifically, the large chamber diameter nozzle achieves a maximum spray cone angle increase of up to 13° compared to the small chamber diameter nozzle. The numerical simulation results exhibit good agreement with the visualization experimental data. Flow field analysis further clarifies the cavitation suppression mechanism inside air-assisted nozzles and the influence of gas-liquid momentum exchange on spray behavior. These findings provide valuable theoretical insights and experimental support for the optimization of air-assisted nozzle design.
  
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  Molecular Dynamics Simulation of Asphaltene/Surfactant Aggregation and Adsorption Properties at Oil-Water Interface

  ZHANG Faxue, WEN Boyao, LUO Zhengyuan, BAI Bofeng

  Journal of Engineering Thermophysics. 2025, 46(10): 3272-3277.

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  The aggregation/adsorption behaviors of asphaltenes and surfactants at the oil-water interfaces significantly affect the interfacial stability during heavy oil chemical flooding. Here we study the aggregation/adsorption characteristics of asphaltenes at interfaces and probe how their interactions with surfactants affect interfacial tension by combining molecular dynamics simulations with statistical physics method. The interfacial tension decreases with the increase of asphaltene at interfaces. Surfactants promote the dispersion of asphaltene aggregates at interfaces and reduce their adsorption via competitive adsorption. The reduction of interfacial tension is related to the interactions between asphaltenes and surfactants, particularly, SDBS with benzene ring structure have the most significant impact. By analyzing hydrogen bonding, aggregate structures, and intermolecular interaction energies, we reveal the microscopic mechanisms of asphaltenes/surfactants affecting interfacial tension. These findings provide important guidance for regulating interfacial stability and designing heavy oil chemical flooding systems.
  
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  Investigation of Interfacial Heat Conduction at Ga₂O₃/SiC Heterojunctions Using Lattice Dynamics

  YANG Hongao, SHEN Yang, CAO Bingyang

  Journal of Engineering Thermophysics. 2025, 46(10): 3278-3284.

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  By integrating machine learning interatomic potentials with lattice dynamics methods, a theoretical framework was developed for predicting thermal boundary conductance and systematically investigated the interfacial thermal transport mechanisms of Ga₂O₃/SiC heterojunctions. Using phonon Monte Carlo simulations and finite element methods, the effect of enhancing thermal boundary conductance on junction temperature reduction in Ga₂O₃ devices was investigated. Results demonstrate that the machine learning potential trained through iterative refinement on density functional theory datasets achieved an accuracy of 0.029 eV/atom, establishing an efficient computational framework. The ideal thermal boundary conductance of Ga₂O₃/SiC was determined to be 217 MW·m⁻²·K⁻¹, limited by lattice mismatch between the interfaces and low transmittance of low-frequency phonons. Device simulation results indicate that increasing the thermal boundary conductance from 150 MW·m⁻²·K⁻¹ to 217 MW·m⁻²·K⁻¹ would reduce the junction temperature by 10 K. This high-precision computational paradigm established in our study provides a universal research methodology for heterojunction thermal design and offers valuable guidance for thermal optimization of high-power electronic devices.
  
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  A Direct Method to Evaluate the Effects of Heat Exchanger Performances on Efficiency of Brayton Cycles

  LI Xiaolong, TANG Guihua, YANG Danlei, FAN Yuanhong

  Journal of Engineering Thermophysics. 2025, 46(10): 3285-3292.

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  The heat exchanger performances have significant effects on the efficiency of Brayton cycles. However, the existing evaluation methods are limited for heat exchanger evaluation in power cycles. The coupling analysis between the cycle and heat exchanger has high accuracy, but suffers from high computational cost and technical complexity. In this work, a decoupling method, named as performance recovery coefficient (PRC), was proposed to directly evaluate the effects of heat exchanger performances on cycle efficiency, avoiding the complex coupling analysis. The results indicated that the PRC is a general method for Brayton cycles with various layouts, parameters and working fluids. Based on the PRC, the heaters in both directly and indirectly heated systems were optimized, which can improve the cycle efficiency by 1.4 and 0.4 percentage points, respectively. 
  
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  Investigation of Alcohol Effect on Boiling Transition Temperatures of an Impacting Water Droplet

  CAI Chang, CHEN Han, SI Chao, LIU Hong

  Journal of Engineering Thermophysics. 2025, 46(10): 3293-3300.

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  The impact characteristics of a single water droplet and low-carbon alcohol-water droplet are experimentally studied. The results show that with an increased impact velocity, the wall temperature at the critical heat flux (CHF) exhibits an overall downward trend, while the wall temperature at the Leidenfrost point (LFP) increases. Both boiling transition temperatures increase remarkedly with the introduction of a tiny amount of low-carbon alcohol additive. In particular, within the present test range, the CHF temperatures of alcohol-water mixture droplets with large Weber numbers are higher than those of water droplets with small Weber numbers. Meanwhile, the LFP temperatures of alcohol-water mixture droplets with small Weber numbers are higher than those of water droplets with large Weber numbers. This indicates that the negative influence of impact momentum can be compensated by alcohol additives, so that a high boiling transition temperature and high heat transfer rate can be achieved simultaneously.
  
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  Experimental Study of the Non-isothermal Crystallisation Behaviour of a High-temperature Molten Salt

  FANG Yongzhe, TIAN Ziqian, YUAN Mengdi, LIAO Zhirong, LIU Huawei, XU Chao

  Journal of Engineering Thermophysics. 2025, 46(10): 3301-3307.

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  In this paper, the non-isothermal crystallization behaviour of solar salt is experimentally studied by visual experimental methods. Key crystallization kinetic parameters, such as the crystallization rate, are obtained by combining with theoretical analysis and calculation, and the correlation equations for the relative crystallinity under different cooling rates are fitted. It is found that the relative crystallinity of solar salt shows a strong nonlinear relationship with temperature, the cooling rate significantly affects the crystallisation process of solar salt, and a single kinetic model is difficult to accurately describe the whole crystallisation process of solar salt. Based on the visual experimental mean, we find the deficiency of differential scanning calorimeter’s inability to measure the relative crystallinity of the phase transition process of high-temperature eutectic molten salts, which enriches the research on the phase transition heat storage mechanism of high-temperature molten salts.
  
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  Study of Droplet Self-transport Behavior on Conical Surface

  CHANG Fangzheng, JIA Li, DING Yi

  Journal of Engineering Thermophysics. 2025, 46(10): 3308-3314.

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  The self-transport characteristics of driving liquid droplets in direction where the radius of curvature of the conical structure increases are widely used in technologies such as water mist collection, oil-water separation and immiscible material separation. Therefore, this paper focused on factors such as self-climbing height and stability during the self-transport process of droplets, and studied the directional self-transport behavior of low surface tension droplets on the hydrophobic vertical conical surface and the hydrophobic double-conical surface under various mechanical environments. The effects of droplet volume and curvature gradient on the directional self-transport of droplets were also explored. The study founded that the double-conical surface greatly increased the self-climbing height of the droplet, and provided a critical driving force for driving the self-transport of the droplet that was approximately twice than that of a vertical conical surface with the same curvature gradient. The stability of the self-transport was evaluated and proved that the self-transport process of the double-conical surface was more stable.
  
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  Experimental Study on Near-Field Thermal Radiation Enhanced by Coupled Polaritons

  ZHANG Wenbin, WANG Boxiang, JIN Shenghao, YI Fan, ZHAO Changying

  Journal of Engineering Thermophysics. 2025, 46(10): 3315-3320.

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  Near-field thermal radiation can surpass the well-known Planck’s blackbody radiation limit due to photon tunneling via evanescent waves. Particularly when surface polaritons are excited, the near-field radiative heat flux can exceed blackbody radiation by several orders of magnitude. The enhancement effect and modulation mechanisms of near-field thermal radiation hold broad application potential in near-field thermophotovoltaic system, near-field thermal imaging, and related fields. In this work, a tunable near-field thermal radiation measurement platform is designed based on nanopositioning technology and capacitive distance sensing. Using fabricated graphene-based composite samples, we measured near-field thermal radiation at a gap distance of (87±0.8) nm, demonstrating an enhancement of (302.8±35.2) times beyond the Planckian blackbody limit. The thermal conductance and heat transfer coefficient reached 0.136 W·K⁻¹ and 5440 W·m⁻²·K⁻¹, respectively. Furthermore, through comparative experiments and theoretical analysis, we investigated and discussed the near-field enhancement effect mediated by coupled surface polaritons.
  
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  Experimental Study on The Evolution of Phase Transition Flow Patterns in Flat Plate Micro-Heat Pipe Arrays

  TIAN Jibang, WANG Hongyan, ZHAO Yaohua, LI Peiyang, LI Chong, QUAN Zhenhua

  Journal of Engineering Thermophysics. 2025, 46(10): 3321-3328.

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  In this paper, a visualization platform was built based on the design of a flat micro-heat pipe array, and the visualization observation of the operating state of gas-liquid two-phase working media and the phase change heat transfer behavior in a confined space was carried out. The results show that the main flow patterns inside the heat pipe are bubble flow, plug flow and ring flow. The heat transfer performance of a low liquid filling rate is superior to that of a high liquid filling rate. A high liquid filling rate will cause a liquid column that hinders the flow of steam in the middle section of the heat pipe, reducing the heat transfer performance. The thermal resistance of the heat pipe is the smallest at a liquid filling rate of 15%, and it is 0.41 K·W⁻¹ at a heating power of 160 W. The experiment observed that the steam flow hindered the reflux of the condensate, resulting in the drying up of the evaporation end. The heat transfer limit inside the heat pipe was a typical carrying limit.
  
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  Design of Hybrid-Enhanced Photothermal Materials and Their Application in Water Evaporation

  YING Liangri, LIU Shule, WANG Weilong, DING Jing, LU Jianfeng

  Journal of Engineering Thermophysics. 2025, 46(10): 3329-3336.

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  Sustainable solar energy for interfacial steam generation presents a promising solution to the water scarcity problem. However, challenges such as low steam generation rates and significant thermal losses in evaporators hinder its practical use. In this study, inspired by the hollow structure of penguin feathers, a low-cost, scalable carbonized kapok fiber aerogel (Ni-NCNTs/KF) was developed. The hybrid photothermal mechanism and efficient solar light capture enabled the vertically aligned Ni-NCNTs array on the surface of hollow kapok fibers (KF) to absorb over 96% of solar light. The Ni-NCNTs core-shell structure promoted surface plasmon resonance and efficient electron transfer at the Ni/CNT interface, significantly enhancing the photothermal conversion efficiency. Additionally, the macroporous nature of kapok fibers (KF) reduced thermal conductivity, minimizing heat losses during evaporation. As a result, Ni-NCNTs/KF achieved a high evaporation rate of 3.22 kg·m⁻²·h⁻¹. This study provides a new design approach for efficient photothermal materials and offers a viable solution for solar-driven seawater desalination.
  
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  Study on the Thermal-Hydraulic Performance of Shell and Tube Heat Exchanger with Metal Foam Baffles

  NIE Changda, CHEN Zhibo, LIU Xinjian, RAO Zhonghao

  Journal of Engineering Thermophysics. 2025, 46(10): 3337-3345.

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  Segment baffles are widely used in the shell and tube heat exchangers (STHXs) to change the flow pattern and thus enhance heat transfer. However, the highly increased flow resistance and dead zones remain serious drawbacks in the applications. To address this issue, the metal foam baffle is proposed in this work to replace the solid baffle. Its heat transfer enhancement is verified and optimized by the numerical simulation with considering the thermal non-equilibrium between fluid and foam baffles. Effects of pore density, cutting, number and nonuniform thickness of foam baffles on the STHX performance were examined and compared with the solid segment baffles. Results show that there exists a threshold pore density for foam baffles, above which the temperature difference between outlet and inlet of STHX with foam baffles is higher compared to that with solid baffles. The threshold pore density increases with the increases of metal foam baffles cutting and number. In addition, the thickness of foam baffles with 8-8-8-10-12-12-12 mm arraignment along the flow direction has the better heat transfer enhancement. This STHX at the optimum pore density decreases the pressure drop by 35.8%, and increases the Nusselt number (Nu) and performance evaluation criterion (PEC) by 1.14 and 1.31 times compared to solid baffles at same parameters, respectively.
  
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  Study on the Structural Design and Performance of PNIPAM/C₁₈H₃₈ Composite Phase Change Material Thermal Diode

  TAO Keai, LI Jing, YANG Xu, MAO Yu

  Journal of Engineering Thermophysics. 2025, 46(10): 3346-3356.

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  To achieve a significant difference in thermal conductance between forward and reverse directions, most studies construct thermal diodes using multiple phase change materials (PCMs) with separate encapsulation to prevent leakage and material intermixing. However, this approach increases system cost and complexity and introduces interfacial thermal resistance. Moreover, existing studies on heterogeneous structures predominantly focus on the microscopic scale, lacking systematic exploration of macroscopic structures and their synergistic effects with PCMs. In this study, carbonized pomelo peel—a low-cost biomass material with high porosity and a specific surface area of 414.28 m²/g—is employed as the encapsulation matrix. A dual-phase-change thermal diode is designed by integrating the solidliquid phase change of n-octadecane (C₁₈H₃₈) and the hydrophilichydrophobic transition of poly(Nisopropylacrylamide) (PNIPAM), leveraging the differences in heat transfer mechanisms and thermal conductivities. A one-dimensional numerical model is used for performance prediction and experimental guidance. Experimental results show that under a temperature difference of approximately 25°C, the thermal diode exhibits a heat flux asymmetry of up to 1.11, demonstrating excellent thermal rectification performance and promising potential for applications in compact thermal management systems.
  
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  Optimization and Performance Verification of Fins Structure in Shell-and-Tube Latent Heat Thermal Energy Storage Unit

  XU Yang, WEI Yong, CUI Ming, CAI Xiao, ZHENG Zhangjing

  Journal of Engineering Thermophysics. 2025, 46(10): 3357-3366.

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  A modified optimization algorithm was established based on the principle of ”inward displacement of heat transfer hysteresis zone” to address the problem of heat transfer hysteresis zone in shell-and-tube phase change heat storage units. Y-shaped, arrow shaped, and annular connected fins were selected and optimized using the modified algorithm combined with genetic algorithm. Numerical simulation and experimental research were conducted on the solidification performance of phase change materials. The results show that compared with the unoptimized Y-shaped fins, the optimized Y-shaped fins can shorten the complete solidification time by 12.5%, but there is still a problem of heat transfer hysteresis zone. The optimized arrow shaped fins and annular connected fins can move the heat transfer hysteresis zone inward, reducing the complete solidification time by 21.5% and 24.4% respectively, further accelerating the solidification process. The experimental results also indicate that optimized arrow shaped fins and annular connected fins can accelerate the solidification of phase change materials, and the annular connected fins have the best performance, verifying the effectiveness of the optimization algorithm and the accuracy of numerical simulation.
  
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  Response of a Swirl Spray Flame Subjected to Forcing in a Centrally-Staged Combustor

  ZHANG Junhua, LI Lei, AN Qiang, CHI Zixin, HUI Xin

  Journal of Engineering Thermophysics. 2025, 46(10): 3367-3379.

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  Centrally-staged combustor can significantly reduce pollutant emissions, but they are susceptible to combustion instabilities. This paper first obtains the self-excited oscillation characteristics of a centrally-staged combustor through experimental methods. Subsequently, large-eddy simulation (LES) is employed to analyze the related flow and flame responses. The results indicate that as the equivalence ratio of the dome increases or the staging ratio decreases, the swirl flame transitions from a stable combustion state to a limit-cycle oscillation state. At low forcing amplitudes, the flow field is dominated by a central vortex tube, which, however, cannot lead to the global heat release rate fluctuation. As the amplitude increases, axisymmetric vortex structures emerge in the flow field, causing significant fluctuations in the heat release rate. Higher forcing amplitudes lead to a decrease in the receptivity of the shear layer to the forcing, leading to a reduction in the gain of the flame response.
  
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  NO_x Generation Characteristics and Prediction Model for H₂/CH₄/air Premixed Flames on Metal Fiber Surfaces

  WANG Tiantian, LI Dezheng, YAO Qiang, ZHANG Yang, ZHANG Hai, LÜ Junfu

  Journal of Engineering Thermophysics. 2025, 46(10): 3380-3388.

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  Hydrogen co-firing is one of the potential pathways to reduce carbon emissions for natural gas users in China, which has received much attention recently. The NO_x generation of the fuel after hydrogen addition is one of the key considerations for the promotion of this pathway. In this paper, the effects of different parameters such as hydrogen blending ratio, excess air ratio, combustion thermal power, and fiber porosity on NO_x generation characteristics of hydrogen-enriched methane are investigated on a 2 kW fully premixed metal fiber surface burner. The results show that a decrease in hydrogen blending ratio, combustion thermal power, and fiber porosity, and an increase in excess air ratio help to reduce the temperature in the high-temperature zone of the combustion chamber, and thus NO_x generation is reduced. Considering the effect of metal fibers on the flow and heat transfer during the combustion of hydrogen-enriched methane, a prediction model of NO_x generation on the surface of metal fibers in the blue-flame mode was developed. Comparison with the experimental values shows that the deviation of the NO_x simulation values is basically within ±16%, which confirms the reliability of the simulation results.
  
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  The Behavior of the Jet Flame Induced by Spontaneous Ignition of High-Pressure Hydrogen Release From Tubes With Different Diameters

  GONG Liang, LI Chenyang, WANG Haoyu, YANG Zihang, MO Tianyu, ZHENG Xianwen, ZHANG Yuchun

  Journal of Engineering Thermophysics. 2025, 46(10): 3389-3396.

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  High-pressure hydrogen storage is currently the mainstream way of hydrogen storage. However, spontaneous ignition and subsequent jet flame will occur when high-pressure hydrogen release, which is a key problem hindering the safe application of hydrogen energy. In this paper, numerical simulation is used to study the flow field and the development of the flame induced by spontaneous ignition of high-pressure hydrogen release from tubes of different diameters. The results show that the larger the tube diameter, the higher the height of the Mach disk, but the smaller the relative expansion. Increasing the tube diameter will increase the area of hydrogen jet flame and the area of hydrogen leakage outside the tube, and the axial and radial propagation distance of the hydrogen jet flame will increase. In addition, the flame outside the 10 mm diameter tube appeared to be extinguished.
  
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  Process Simulation of Biomass Chemical Looping Production of Ammonia Syngas Coupled With Ammonia Synthesis

  WU Tianhao, ZHONG Fagen, LIN Yan, YAN Shuchang, LI Chengyang, FANG Shiwen, WEI Xiaoyu, HUANG Zhen

  Journal of Engineering Thermophysics. 2025, 46(10): 3397-3406.

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  In this research, a method for producing ammonia synthesis gas (N₂+H₂) and ammonia via biomass chemical looping was developed using Aspen Plus software. The process utilized pine wood biomass, steam, and oxygen carriers as raw materials. The study examined the impact of key parameters on system performance through a combination of process simulation and sensitivity analysis. The optimal parameters were identified as follows: an OC/B ratio of 9, a fuel reactor temperature of 900°C, an S/B ratio of 4, a hydrogen reactor temperature of 600°C, an AIR/B ratio of 1.5, and an ammonia reactor temperature and pressure of 300°C and 15 MPa, respectively. At an NH3 yield of 0.326 kg/kg biomass, the system achieved an exergy efficiency of 70.6% and consumed energy at a rate of 155.3 kW. This study not only established a biomass chemical looping process for preparing ammonia synthesis gas but also introduced a novel production process for ammonia synthesis.
  
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  Research on Ignition Delay of Ammonia Fuel in High-Pressure Lean Combustion

  SONG Yu, WANG Xianjie, LIU Fei, WU Jingxing, MA Yutao, LIU Yishuo

  Journal of Engineering Thermophysics. 2025, 46(10): 3407-3414.

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  With the acceleration of global industrialization, the use of fossil fuels is constantly increasing. Ammonia is considered a promising new type of clean energy due to its high energy density and the characteristic of zero carbon dioxide during combustion. We conducted an experimental study on the ignition delay of ammonia lean combustion under high pressure (Φ = 0.1 ∼ 0.25, p = 0.175 ∼ 1 MPa) using a shock tube experimental platform. The influence mechanism of parameters such as pressure, temperature, and equivalence ratio on ignition delay characteristics was explored based on detailed ammonia chemical mechanisms. The lower the equivalence ratio (Φ = 0.1), the higher the concentration of radicals O and OH during ignition and combustion under fuel-lean conditions, which accelerates the initial chain reaction of NH₃ and reduces the ignition delay time. When the pressure is higher, it is beneficial for the elementary reactions R5: H₂+M⇔H+H+M and R77: H₂O₂ (+M)⇔OH+OH (+M) to proceed, increase the concentration of the radical pool, and accelerate the elementary reaction process.
  
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  Study on the Influence of In-cylinder Hydrogen Injection on Combustion Characteristics and Lean Burn Limit of Gasoline Engines

  RAO Shunlu, ZHENG Zhaolei, FAN Guangtao

  Journal of Engineering Thermophysics. 2025, 46(10): 3415-3426.

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  This paper studies the effect of hydrogenation ratio on the combustion characteristics and lean burn limit of gasoline and hydrogen dual direct injection engines. Research results show that when the hydrogen blending ratio is 36%, the ignition process of the gasoline engine can be significantly accelerated and the pressure rise rate can be greatly increased, thereby enhancing the combustion performance of the gasoline engine. Compared with a pure gasoline engine, the 36% hydrogen blending ratio expands the lean burn limit of the gasoline engine from λ=1.62 to λ=2.16; the indicated thermal efficiency can reach a maximum of 47.7%. NO_x emissions first increase and then decrease as the excess air coefficient increases, but when λ=1.6, NO_x emissions are much lower than the equivalence ratio operating condition; due to the adoption of the high-energy ignition system coupled hydrogen blending strategy, the fuel is fully burned, so the HC, CO emissions are almost zero; CO₂ emissions decrease with the increase of excess air coefficient and hydrogen blending ratio.
  
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  Multi-stage Auto-ignition Patterns and the Effect of EGR for Single Droplet of Iso-octane

  SONG Haiyu, ZHANG Wenyi, ZHOU Hengyi, LIANG Wenkai, LIU Yucheng

  Journal of Engineering Thermophysics. 2025, 46(10): 3427-3439.

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  This study uses numerical simulations to investigate the multi-stage auto-ignition patterns of iso-octane single droplet under non-convective condition and analyse its dynamic ignition process. Firstly, we obtained that the pure gas phase reaction of iso-octane has two-stage heat release under both low and high temperature paths, i.e., four-stage ignition, by numerical simulation of a 0-D reactor. Then, we numerically simulated iso-octane single droplet auto-ignition patterns in the initial temperature of 600∼1000 K, initial pressure of 0.05∼2 MPa in air environment, and obtained that the patterns under the above conditions include no ignition, single stage cool flame, and two-stage ignition. Then we discussed the dynamic ignition process of two-stage ignition with the reactions occurring around the droplet under different temperature paths in detail. Finally, the inhibitory effect of adding EGR gas on auto-ignition of iso-octane single droplet was discussed. 
  
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  Molecular Dynamics Study on Electric Field Enhanced MoS₂ Catalytic Cracking of Methane for Hydrogen Production

  ZHOU Wenjun, LU Yi, ZHOU Weixing, JIA Zhenjian

  Journal of Engineering Thermophysics. 2025, 46(10): 3440-3448.

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  Hydrogen fuel is a clean energy with a wide range of application prospects, and methane direct cracking hydrogen production is an efficient hydrogen production method. In order to improve hydrogen production, an electric field-assisted MoS₂ catalytic cracking methane method for hydrogen production was proposed. Molecular dynamics simulations were used to evaluate methane pyrolysis efficiency and hydrogen yield under different electric field strengths and disclose the mechanism of the electric field to improve the catalytic performance of MoS₂. The results show that the improvement of methane cracking efficiency is related to the strength of the electric field. It promotes the collision opportunity and decreases the reaction activate energy. The charge transfer and bonding between methane and sulfur were enhanced under appropriate electric field strength, thereby improving the adsorption and catalytic cracking performance of MoS₂. Meanwhile, the electric field promotes the hydrogen radical attack reaction, enriches the reaction network of methane cracking for hydrogen production, and promotes the collision and conversion between products, thereby providing more pathways for hydrogen production.
  
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  Experimental and Kinetic Modeling Study of CO/H₂/CH₄/NO Oxidation at High Pressure

  LIU Yunyang, YOU Jiajun, ZHAO Yun, YIN Geyuan, HU Erjiang, HUANG Zuohua, BAO Yangyang

  Journal of Engineering Thermophysics. 2025, 46(10): 3449-3457.

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  In this study, typical coal-derived syngas blended NO oxidation experiments were carried out using a flow reactor operating at a pressure of 1.8 MPa. In this experiment, the NO_x blending concentration ranged from 0% ∼ 0.185% and the temperature ranged from 623 ∼ 1273 K. The effect of NO addition on the CO/H₂/CH₄ oxidation characteristics was analyzed. The experimental results indicate that under high-pressure conditions, the addition of NO has a promoting effect on the low-temperature oxidation of CO, H₂, and CH₄ while inhibiting the consumption of these gases at medium temperatures. Furthermore, the low-temperature promoting or intermediate-temperature inhibiting effects are enhanced with the increase of the blending concentration. In particular, the onset reaction temperature of CH₄ was advanced by 125 K, while the complete reaction temperature of CO was delayed by more than 100 K. Updated based on the CRECK-2019 model, the new model could accurately predict the species concentrations for the CO/H₂/CH₄/NO oxidation process. A detailed kinetic analysis was also carried out using the new model, revealing the main reaction pathways and sensitive reactions of the CO/H₂/CH₄/NO oxidation process.
  
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  Evolution Mechanism and Effect of Metal Elements During Flame Synthesis of Nickel-rich Cathode Materials for Lithium-ion Batteries

  WANG Junlei, LI Jinyu, DU Wen, LI Shilong, CHEN Guohui, WANG Kun

  Journal of Engineering Thermophysics. 2025, 46(10): 3458-3469.

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  Recently, flame synthesis has been used to prepare the nickel-rich cathode material LiNi_0.8Co_0.1Mn_0.1O₂ (NCM811) for lithium-ion batteries. However, the process involves lithium, nickel, cobalt, and manganese, which are four metal elements with different physicochemical properties, and the evolution mechanism of the flame synthesis and its effects on cathode materials are still not clear. In the present study, the decomposition and reaction characterization of the nitrate precursors of the above four metals were performed by using thermogravimetric experimental analysis and thermodynamic theoretical calculations. Results showed that nitrates of lithium, nickel, cobalt, and manganese can be completely decomposed into their respective oxides in the high-temperature flame. Nickel, cobalt, and manganese oxides are less reactive and remain stable in the flame. In contrast, lithium oxide is highly reactive and will further react with the combustion products of carbon dioxide and water in the flame, converting it into lithium carbonate and lithium hydroxide. Thus, the four metal elements involved in the flame synthesis nickel-rich cathode materials can effectively be divided  into two groups, which significantly simplify the understanding of the flame synthesis multi-metal oxide nanomaterials. Finally, to clarify the effect of the reactive element lithium, we investigated the effects of different lithium sources including lithium nitrate, lithium carbonate, and lithium hydroxide on the flame-synthesized NCM811 with significantly different morphological structures and electrochemical performances.
  
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  Investigation of Spark Ignition Combustion Characteristics on a Rod-Less Opposed-Piston Engine

  HAO Caifeng, DENG Longfei, HAO Liping, ZHU Weiqing, LI Yaozong

  Journal of Engineering Thermophysics. 2025, 46(10): 3470-3478.

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  The rod-less opposed-piston engine is a new configuration engine, with a high-degree freedom of the piston motion trajectory. By driving the cam profile optimization, piston motion planning, and redistribution of working-process, it was achieved that the combustion exothermic and heat transfer were optimized coupling with the volume change volume, thereby improving the thermal efficiency. Based on the constant volume incendiary vessel, it was found that the aviation kerosene could not be successfully ignited with the ambient temperature below 355 K, and the aviation kerosene could auto-ignite with the ambient temperature above 750 K. Based on the principle demonstration prototype, the feasibility of working principle of the rod-less opposed-piston engine was verified, and the engine could achieve operate steadily at a certain speed. At the same time, the effects of intake temperature, throttle opening, injected mass, injection timing and ignition timing on the combustion process were studied.
  
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  Experimental Study on the Effect of Nanobubbles on the Atomization Characteristics of Nozzle

  PEI Fanqi, DU Yuhang, MAO Ronghai, WEN Zhi, LOU Guofeng

  Journal of Engineering Thermophysics. 2025, 46(10): 3479-3487.

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  To study the influence of nanobubbles on the atomization characteristics of pressure swirl atomizer, the presence and long-term stability of nanobubbles in water were experimentally examined with Nanoparticle Tracking Analysis method firstly in this paper. And then, the effects of nanobubbles on the atomization characteristics under different pressures were investigated by atomization experiments. The results of stability experiments show that the mean diameter of nanobubbles basically stabilizes at about 80∼120 nm. While the concentration of nanobubbles stabilizes at about (1.5∼1.8)×10⁸ mL⁻¹ after 50 days. The results reflect that nanobubbles-water blend can be stored for a long time and keep its activity. The experimental results of atomization characteristics show that the flow characteristic curve is reduced by 6.33% while the atomization cone angle is increased by 2.3% after adding nanobubbles to water. After comparing the vary of Sauter mean diameter, it is found that when the pressure is greater than 3 MPa, the Sauter mean diameter of nanobubbles-water blend is slightly lower than that of deionized water. Besides, the greater the pressure, the smaller the axial distance of the outlet, the greater of the difference of Sauter mean diameter. The above study reflects that nanobubbles can effectively enhance the atomization characteristics of pressure swirl atomizer.
  
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  Effect of Ethanol and Phenol on Low Temperature Denitration of SNCR

  DING Wenxi, LIU Meng, WAN Jun, LIU Wei

  Journal of Engineering Thermophysics. 2025, 46(10): 3488-3493.

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  In recent years, the problem of nitrogen oxide emissions has attracted wide attention in the field of environmental protection. Firstly, the effect of ethanol (C₂H₆OH) and phenol (C₆H₅OH) on the denitration efficiency of SNCR was studied in a tube furnace. It was concluded that ethanol and phenol had a better effect on the denitration efficiency of SNCR from 650°C to 800°C. In the 6 kW(th) CFB coal burning test system, the effects of the two on SNCR in actual coal burning flue gas were further studied. The result indicated that both ethanol and phenol could improve the denitration efficiency when the reaction temperature was lower than 700°C. From 700 to 750°C, it was advisable to use ethanol as additive and control β(C₂H₅OH/NH₃) to about 0.8. Higher than 750°C, SNCR denitration efficiency was higher than 50%, it was not appropriate to add these two additives.