Your search keyword '"MICROWAVE heating"' showing total 16,590 results

1. Dielectric conductivity and microwave heating behavior of NiO at high temperature.

Author

Yoshikawa, Noboru and Sato, Haruto

Subjects

*THERMAL conductivity, *HIGH temperatures, *MICROWAVE heating, *DIELECTRIC loss, *DIELECTRICS, *ACTIVATION energy

Abstract

Measurement of high-temperature physical properties at microwave frequency is important to interpret the heating behavior of NiO observed in the author's previous studies. In this study, the impedance (4 Hz–5 MHz) and permittivity [at the microwave frequency (2.45 GHz)] of NiO powder particles were measured from room temperature (RT) to 800 °C. At high frequency above 100 kHz, the conductivity is almost independent of temperature up to a certain temperature (Ti). Above Ti, the conductivity showed a strong positive dependence on the temperature. In this region, the apparent activation energy is determined to be 0.51 eV, which is close to that of the previously reported large polaron transport mechanism (band-like conduction). It was also shown that the conductivity increased linearly with frequency and that a dielectric conductivity relation (σ = ωε″) holds, which is different from the hopping mechanism of the small polaron. Considering these results, it was understood that the temperature increase occurred preferentially in the microwave E-field. The slow increase from the room temperature is due to a small but finite dielectric loss at room temperature, and because of the low conductivity, induction current is not effectively generated in the H-field. On the other hand, after a certain time, the temperature rises to reach the large temperature-dependent conductivity, and then, a significant temperature rise occurs. [ABSTRACT FROM AUTHOR]

Published

2024

2. Development of a microwave chemical cell coupled with post-wall waveguide for in situ/operando soft x-ray absorbance spectroscopy under microwave irradiation.

Author

Fujitani, Kaito, Suzuki, Satoru, Kishihara, Mitsuyoshi, and Utsumi, Yuichi

Subjects

*MICROWAVE spectroscopy, *X-ray spectroscopy, *SOFT X rays, *MICROWAVES, *SYNCHROTRON radiation, *MICROWAVE heating

Abstract

In this study, we developed a microwave chemical cell for total electron yield soft x-ray absorption spectroscopy (XAS) using synchrotron radiation under microwave irradiation. In addition, in situ XAS measurements of ammonia borane were performed using the device developed. The device comprises a post-wall waveguide housing a sample holder formed within it. Electrons emitted from the sample during soft x-ray irradiation pass through the metal plates of the waveguide and are measured using a picoammeter. Integration of the microwave irradiation structure into a synchrotron radiation beamline, which is a challenge in soft x-ray analysis requiring measurements in a high-vacuum atmosphere, was achieved by miniaturizing the device using 24.125 GHz ISM band microwaves, instead of the typical 2.45 GHz microwaves. Performance of the device was thoroughly assessed through temperature distribution simulation, temperature measurement of water, and evaluation of frequency characteristics. When the sample holder was filled with water and irradiated with 3 W microwaves, the temperature increased to 97 °C, which is close to the boiling point. The in situ XAS measurements performed using this device with ammonia borane/graphite (2:1) powder at the B-K edge during microwave irradiation showed that peaks associated with hydrogen desorption intensified with prolonged microwave exposure. This result indicates that microwave heating in a vacuum and soft x-ray analysis during microwave heating were achieved. The developed microwave chemical cell emerges as a powerful tool, facilitating advancements in our understanding of elementary chemical processes and elucidating microwave-specific effects such as local heating during microwave irradiation. [ABSTRACT FROM AUTHOR]

Published

2024

3. Rapid 24 GHz microwave sintering of alumina – yttria-stabilized zirconia ceramic composites.

Author

Egorov, S.V., Eremeev, A.G., Kholoptsev, V.V., Plotnikov, I.V., Rybakov, K.I., Sorokin, A.A., Balabanov, S.S., and Rostokina, E.Ye.

Subjects

*MICROWAVE heating, *ELECTROMAGNETIC fields, *SPECIFIC gravity, *FRACTURE toughness, *POWER density, *MICROWAVE sintering

Abstract

Samples of alumina – 3 % yttria-stabilized zirconia (YSZ) composites were sintered in rapid processing regimes using 24 GHz microwave heating at rates of up to 200 °C/min and zero hold time. The final relative density was 96–99 % for the samples containing 1.5 and 7.5 wt % YSZ and 98–99 % for the samples containing 13 wt % YSZ. The microwave sintering kinetics were compared for the processes carried out by direct and susceptor-assisted microwave heating. Under direct microwave heating, the effect of an intense microwave electromagnetic field with an estimated absorbed power density of up to 130 W/cm3 resulted in a shift of the shrinkage curves by about 100 °C towards lower temperatures compared to the case of susceptor-assisted heating. The grain size of the samples sintered by direct microwave heating decreased with an increasing heating rate. The mechanical properties were slightly higher for the materials sintered under susceptor-assisted microwave heating. The samples containing 13 wt % YSZ exhibited a microhardness of about 20 GPa and a fracture toughness of about 7 MPa m1/2. [ABSTRACT FROM AUTHOR]

Published

2024

4. Facile synthesis of nanocrystalline cellulose from rice husk by microwave heating: evaluation of morphological architectures from the macro-to-nano dimensions.

Author

Lim, Kah Yee and Foo, Keng Yuen

Subjects

MICROWAVE heating, RICE hulls, SURFACE stability, SURFACE charges, CELLULOSE synthase

Abstract

This study reports the preparation (80 min) of rice husk (RH)-derived cellulose nanowhiskers (CNWs) via microwave-irradiation. The unique features of RH-CNWs and the intermediate products were validated with respect to the alteration of morphological structure, particle dimension, crystalline pattern, chemical compositions, functionalities, thermal stability and surface charge. With the integration of microwave heating (MW), the isolation of nano-sized fragments from the matrix of amorphous and non-cellulosic materials has been successfully accomplished, recorded a high conversion yield at 61.5%. The average length and diameter of RH-CNWs were 264.35 nm and 25.26 nm, respectively, recording an average aspect ratio at 10.47. X-ray diffraction analysis revealed a crystallinity index of 65.9%, and the diffraction pattern was identical to type-Iβ crystalline cellulose. Further clarifications with respect to the surface functionality, thermal stability and composition analyses have verified the successive esterification of sulfate functional groups over the surface of RH-CNWs, leading to a higher thermal stability and zeta-potential (ζ = − 44.50 mV). Given the explicit characteristics of MW, the synergistic interactions of microwave-chemical actions have offered the additional impact force and dipolar rotation, accelerating the cleavage of hydrogen bonds and complete removal of amorphous domains from the RH surface. [ABSTRACT FROM AUTHOR]

Published

2024

5. Alternative Metallic Fillers for the Preparation of Conductive Nanoinks for Sustainable Electronics.

Author

Corrales‐Pérez, Belén, Díaz‐Ufano, Carlos, Salvador, María, Santana‐Otero, Antonio, Veintemillas‐Verdaguer, Sabino, Beni, Valerio, and Morales, María del Puerto

Subjects

*METAL nanoparticles, *MANUFACTURING processes, *MICROWAVE heating, *IRON-nickel alloys, *CHEMICAL synthesis, *BIODEGRADABLE materials

Abstract

The development of electronics with net zero carbon emissions through more efficient and environmentally friendly materials and processes is still a challenge. Here, alternative chemical synthesis routes of metal conductive nanoparticles, based on biodegradable materials are explored, such as nickel, iron–nickel alloy and iron nanoparticles, to be used, in the long term, as fillers in inks for inject printing. Thus, Ni and FeNi metal nanoparticles of 25–12 nm, forming aggregates of 614–574 nm, respectively, are synthesized in water in the presence of a polyol and a reducing agent and under microwave heating that enables a more uniform and fast heating. Iron nanoparticles of 120 ± 40 nm are synthesized in polyol that limits the aggregation and the oxidation degree. Commercial metal nanoparticles of iron and nickel, are coated with ethylene glycol and used for comparison. The conductivity of nanoparticles when pressed into pellets remains similar for both commercial and synthesized samples. However, when deposited on a strip line and heated, synthesized Ni, FeNi, and Fe nanoparticles show significant conductivity and interesting magnetic properties. It is demonstrated that the nanosize facilitates sintering at reduced temperatures and the capping agents prevent oxidation, resulting in promising conductive fillers for printed electronic applications. [ABSTRACT FROM AUTHOR]

Published

2024

6. Drying kinetics and energy efficiency of Y2O3–CeO2 co-doped ZrO2 powder under microwave heating.

Author

Liu, Benhua, Ren, Chunxiao, Zhou, Ju, Tang, Ju, Zhang, Fan, Omran, Mamdouh, and Chen, Guo

Subjects

*MICROWAVE heating, *MICROWAVE drying, *DIFFUSION coefficients, *STRENGTH of materials, *METALLIC oxides

Abstract

Zirconia has important application prospects in the field of ceramics. However, during a high-temperature heating process, pure zirconia will undergo martensite transformation, which seriously affects its service performance. Metal oxides, such as Y 2 O 3 –CeO 2 doping ZrO 2, effectively improve the toughness and fire resistance of the material. Thus, the drying of Y 2 O 3 –CeO 2 co-doped ZrO 2 powder is an essential step before practical application. The study employs contemporary microwave drying techniques. The results of the experiment show that the average microwave drying rate increases with an increase in mass, water content, and microwave heating power. When the initial mass was 30 g, the initial moisture content was 12 %, microwave power was 720 W, and the drying rate was the fastest. We used four dynamic models: Modified Page, Quadratic, Wang and Singh, and Page to fit the experiment data. The best model was Modified Page, which describes the kinetic process most accurately. Fick's second law describes how, in the drying process, when microwave power is 720 W, initial mass is 15 g and initial water content is 8 %, the effective diffusion coefficient is 5.25 × 10−16 m2/s. Fourier Transforms of the infrared spectrum of the samples before and after drying were analyzed, the intensity of the O–H absorption peak located at 3442.03 cm/s, and O–H–O absorption peak located at 1594.48 cm/s. Both decreased significantly after drying. To discuss the relationship between the microwave power and the diffusion coefficient, the activating energy of microwave heating was 32.01 W/g. The experimental results show high heating efficiency and selective heating of the microwave method. This study provides a theoretical basis and research data for microwave drying of Y 2 O 3 /CeO 2 co-doped ZrO 2 powder in industry. [ABSTRACT FROM AUTHOR]

Published

2024

7. Comparative study of microwave-assisted and hydrothermal hydroxyapatite synthesis from neutralization slag: Optimization, energy, and adsorption.

Author

Huang, Jianying, Liu, Tao, Zhang, Yimin, and Hu, Pengcheng

Subjects

*HYDROXYAPATITE synthesis, *RESPONSE surfaces (Statistics), *HYDROTHERMAL synthesis, *SURFACE charges, *ADSORPTION capacity, *MICROWAVE heating

Abstract

The study proposes the utilization of microwave-assisted methods for converting neutralization slag (NS) into hydroxyapatite (HAP), offering an alternative to the conventional hydrothermal method. The microwave-assisted approach addresses the challenges encountered in hydrothermal reactions, such as particle agglomeration, reduced specific surface area, prolonged reaction time, high temperature requirements, and inadequate saturation adsorption capacity. By employing the response surface methodology with a Box-Behnken design, the study found that the microwave-assisted method significantly reduced the synthesis time from 90 to 25 min and the temperature from 120 °C to 56 °C. Furthermore, the microwave method consumed only 1/43 of the energy utilized in hydrothermal synthesis. To assess the performance of the synthesized HAP, various detection methods were utilized, including XRD, SEM-EDS, FTIR, Zeta potential, and ICP, which analyzed the crystal structure, crystallinity, morphology, chemical composition, and surface charge of HAP. The BET method was used to measure the specific surface area, further confirming the successful synthesis of HAP. The HAP synthesized through this microwave-assisted method exhibited a saturation adsorption capacity of up to 98.4 mg/g of fluoride ions from vanadium industrial raffinate. This study demonstrates that the microwave-assisted method provides a viable solution for reducing energy consumption and enhancing HAP synthesis efficiency for wastewater treatment in the vanadium industry. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

8. An Efficient Synthesis of Novel Semicarbazones and Their Biological Activities.

Author

Ahsan, Mohamed Jawed, Sarwar, Ali, Ali, Abuzer, Ali, Amena, Ahmad, Md. Dabeer, Hedaytullah, Md., Salahuddin, Ahsan, Md Faiyaz, and Riadi, Yassine

Subjects

*DNA topoisomerase II, *ULTRASONIC waves, *MICROWAVE heating, *GRAM-negative bacteria, *THIN layer chromatography, *CIPROFLOXACIN

Abstract

The article discusses the synthesis of novel semicarbazones and their biological activities, including antimicrobial properties. The study focuses on the preparation of semicarbazones with improved biological activity, achieved through ultrasonic irradiation and a simple solvent system. The compounds showed promising antibacterial activities, particularly (E)-2-(1-(3-chloro-4-fluorophenyl)ethylidene)-N-(2-chlorophenyl)hydrazine-1-carboxamide (4e), which exhibited good activity against both Gram-positive and Gram-negative bacteria. Molecular docking studies provided insights into the compounds' binding interactions with DNA gyrase, suggesting potential for further research on antimicrobial compounds. [Extracted from the article]

Published

2024

9. Preparation, characterisation and functional effects of goat milk whey protein isolate with low lactose after heat and non‐heat treatments.

Author

Shu, Qin, Zhu, Li, Li, Zekun, Al‐Wraikat, Majida, Li, Linqiang, and Liu, Yongfeng

Subjects

*GOAT milk, *MILK proteins, *GOATS, *DAIRY products, *MICROWAVE heating, *FOOD pasteurization, *LACTOSE

Abstract

This study investigates the physicochemical and functional properties of goat milk whey with heat and non‐heat treatments (pasteurisation, high‐temperature heating, ultrasonic treatment and microwave heating) and lactose hydrolysis. The optimal lactose hydrolysis conditions were obtained through orthogonal test. The results revealed the lactose and glucose in low‐lactose goat milk whey remained largely unchanged through all four treatments, while high‐temperature and microwave treatments induced protein structure alteration. The foaming and emulsifying properties of low‐lactose whey powder were enhanced by heating and ultrasonic treatments, although foam stability decreased. Our findings provide valuable insights into exploiting more nutritional goat milk products. [ABSTRACT FROM AUTHOR]

Published

2024

10. Opinion on the prospects of emerging food processing technologies to achieve sustainability in the industry by reduced energy consumption, waste reduction and valorisation, and improved food nutrition.

Author

Gavahian, Mohsen

Subjects

*SUSTAINABILITY, *INDUSTRIAL energy consumption, *TECHNOLOGICAL innovations, *FOOD science, *RESISTANCE heating, *MICROWAVE heating

Abstract

Summary: Conventional food processing technologies cannot meet the demands of sustainability in the face of societal concerns about climate change, resource scarcity, and food insecurity. Therefore, the food industry must embrace emerging food processing technologies such as ohmic heating, microwave heating, cold plasma, pulsed electric field, and ultrasound to achieve sustainable food production. Although these technologies have been researched worldwide, they have yet to be widely adopted in the industry as concerns such as high capital investments, regulatory issues, technological limitations, and scalability limit their practical applications. This manuscript discusses key contributions of emerging technologies in enhancing sustainability, including reducing energy consumption, waste reduction and valorisation, and enhancing nutrition. Despite these promising capabilities, fully benefiting from emerging technologies in the industry requires further technological advancements, optimisation, economic viability, consumer acceptance, regulatory compliance, and sustainable workforce education. These could be achieved only by close collaborations between academia, industry, and technology developers. Such considerations and actions to resolve the concerns could facilitate the industrial application of emerging technologies to achieve a more sustainable future with reduced carbon emission, environmental impact, and carbon footprint, along with the capability of improved resource efficiency and further contributions to food security and food nutrition improvement. [ABSTRACT FROM AUTHOR]

Published

2024

11. Existence of solutions for the problem of microwave heating and a Liapunoff criteria for stability and instability.

Author

Cimatti, Giovanni

Abstract

The Galerkin's method is applied to prove the existence of at least one solution of the initial boundary value problem for the nonlinear system of partial differential equations modelling the electromagnetic heating of materials. In addition a criteria of stability and instability based on a Liapunoff function is presented. [ABSTRACT FROM AUTHOR]

Published

2024

12. Effect of microwave heating on rock damage and energy evolution.

Author

Li, Tan, Wang, Wei, Chen, Guangbo, and Li, Qinghai

Abstract

Rock fragmentation efficiency can be increased by microwave heating. The mechanical properties and energy evolution characteristics of coarse sandstone specimens under different microwave heating conditions are compared in this paper. The effects of microwave heating time and power on coarse sandstone specimens of peak stress, elastic modulus, brittleness index, damage variable, and impact energy index are analyzed. The results indicate that the microwave heating power and microwave heating time are inversely proportional to peak stress and elastic modulus and directly proportional to peak strain. With the increase of microwave heating power and microwave heating time, the brittleness index and damage variable of rock specimens increase, the impact energy index decreases. The microwave heating power and microwave heating time increase the rock brittleness index. The energy absorption rate of rock specimens decreases with the increase of microwave heating time. The impact energy index is inversely proportional to microwave heating power and microwave heating time. High-power and long-time microwave heating can reduce the possibility of rockbursts and the intensity of potential dynamic disasters. The research conclusion can provide the theoretical and technical basis for breaking rock by microwave heating. [ABSTRACT FROM AUTHOR]

Published

2024

13. Raman Thermometry for Temperature Assessment of Inorganic Transformations During Microwave Heating.

Author

Jamboretz, John and Birkel, Christina S.

Subjects

*PHASE transitions, *MICROWAVE heating, *FURNACES, *TRANSITION temperature, *CHEMICAL amplification

Abstract

ABSTRACT Microwave heating is an intriguing method for the synthesis of inorganic solids offering a variety of advantages over conventional furnace heating, such as fast heating and cooling rates as well as volumetric and selective heating of precursors. However, there are many open questions regarding this “black‐box” process, and insights into the effect of microwave radiation on different types of solids are generally missing. In situ Raman spectroscopy is a powerful technique to unravel chemical transformations and identify intermediate species during microwave solid‐state syntheses. A major challenge is the temperature measurement under microwave conditions because (metallic) thermocouples cannot be used and optical pyrometry has significant drawbacks. In contrast, Raman thermometry is a viable method that relies on the temperature‐induced shift of Raman signals. Here, we use this method to estimate the temperature during microwave heating of a model system (titania) that undergoes a phase transition at temperatures >800°C. The estimation is derived from a flexible double exponential calibration function applied to Raman spectroscopic peak shifts in the temperature‐resolved furnace heating data, which was found to describe two titania modes (one anatase and one rutile) extremely well. Based on a detailed error and uncertainty analysis, we suggest options to further optimize Raman thermometry for use in high‐temperature microwave heating conditions. [ABSTRACT FROM AUTHOR]

Published

2024

14. Simulation study on additive-promoted microwave dehydration of lignite.

Author

Li, Xiaolong, Zuo, Mingjin, Liu, Xiaoyan, Chen, Simo, Li, Qian, Ge, Lichao, and Wang, Yang

Subjects

*ELECTROMAGNETIC fields, *ELECTROMAGNETIC coupling, *COMPUTATIONAL electromagnetics, *LIGNITE, *MICROWAVE drying, *MICROWAVE heating

Abstract

Microwave dehydration technology has been widely used in coal processing methods due to its unique advantages. Adding additives with high dielectric loss to coal can enhance the microwave absorption capacity of coal, so as to effectively improve the dehydration process. In order to understand the change and distribution of multi-fields in the microwave drying process of lignite under the action of different additives, verify the experiment and reduce the cost and number of experiments, this paper established a multi-field coupling model of electromagnetic field and heat and mass transfer of multiphase porous media based on COMSOL Multiphysics, so as to simulate the microwave drying process of lignite. The results show that the distribution areas of electromagnetic field, temperature field, and vapor in coal are basically the same, while the distribution of liquid water is just the opposite. With the enhancement of additive promotion effect, the parts with strong electromagnetic field strength increase, the hot spots of temperature field increase, the maximum temperature, and minimum temperature increase, and the water content in coal samples decreases. The promotion effect of additives on the microwave dehydration process of lignite is consistent with the experiment. [ABSTRACT FROM AUTHOR]

Published

2024

15. Producing aromatic‐rich oil through microwave‐assisted catalytic pyrolysis of low‐density polyethylene over Ni/Co/Cu‐doped Ga/ZSM‐5 catalysts.

Author

Islam, K. M. Oajedul, Ahmad, Nabeel, Ahmed, Usama, Siddiqui, Mohammad Nahid, Ummer, Aniz Chennampilly, and Abdul Jameel, Abdul Gani

Subjects

*BENZENE derivatives, *HEAVY oil, *CIRCULAR economy, *PLASTIC scrap, *DOPING agents (Chemistry), *GIBBERELLINS, *PETROLEUM products

Abstract

Microwave (MW)‐assisted catalytic pyrolysis represents a promising method for transforming petroleum‐based plastic waste into valuable chemicals, offering a pathway towards more sustainable circular economy. In this study, catalytic pyrolysis of low‐density polyethylene (LDPE) was conducted under MW irradiation. The influence of various catalyst types (HZSM‐5, Ga/ZSM‐5, Ga/Ni/ZSM‐5, Ga/Co/ZSM‐5, and Ga/Cu/ZSM‐5) on product yield and distribution was examined. The results revealed that the Ga/ZSM‐5 catalyst yielded the maximum liquid oil, approximately 41%. Ga/Ni/ZSM‐5 performed excellently in the production of long‐chain olefins, constituting about 27% of the liquid fraction. However, Ga/Co/ZSM‐5 led to the production of heavy pyrolysis oil containing nearly 25% long‐chain paraffins, rendering it unsuitable for producing high‐value chemicals. Conversely, the Ga/Cu/ZSM‐5 catalyst yielded an aromatic‐rich pyrolysis oil, with benzene derivatives constituting approximately 90% of the liquid oil fraction, thus proving to be a suitable catalyst for the intended application. The liquid product distribution was compared with a petroleum assay by SimDist, and this suggested that utilizing the HZSM‐5 catalyst could yield an 86.4% naphtha fraction. The study also revealed that the Ga/Cu/ZSM‐5 catalyst generated the largest amounts of hydrogen and syngas, as determined by a MicroGC analysis of the gas products. This catalyst also exhibited the maximum coke deposition (1.35%) postreaction, which was attributed to its high aromatic hydrocarbon content in the pyrolysis oil and maximal hydrogen release. A comparison of fresh and spent catalyst properties was conducted to gain insights into catalyst activity and to correlate the effects of metal doping on product distribution. These findings underscore the potential of MW‐assisted catalytic pyrolysis, particularly with the Ga/Cu/ZSM‐5 catalyst, for the efficient conversion of plastic waste into valuable chemicals, thereby contributing to sustainable resource utilization and environmental conservation. [ABSTRACT FROM AUTHOR]

Published

2024

16. Molecular Structure and Properties of Resistant Dextrins from Potato Starch Prepared by Microwave Heating.

Author

Kapusniak, Kamila, Wojcik, Malwina, Rosicka-Kaczmarek, Justyna, Miśkiewicz, Karolina, Pacholczyk-Sienicka, Barbara, and Juszczak, Leslaw

Subjects

*MOLECULAR structure, *MICROWAVE heating, *DEXTRINS, *DIETARY fiber, *RHEOLOGY

Abstract

The dextrinization of potato starch was performed using a sophisticated single-mode microwave reactor with temperature and pressure control using 10 cycles of heating with stirring between cycles. Microwave power from 150 to 250 W, a cycle time from 15 to 25 s, and two types of vessels with different internal diameters (12 and 24 mm) and therefore different thicknesses of the heated starch layer were used in order to estimate the impact of vessel size used for microwave dextrinization. The characteristics of resistant dextrins (RD) including solubility in water, total dietary fiber (TDF) content, color parameters, the share of various glycosidic bonds, and pasting and rheological properties were carried out. The applied conditions allowed us to obtain RDs with water solubility up to 74% at 20 °C, as well as TDF content up to 47%, with a predominance of low-molecular-weight soluble fiber fraction, with increased content of non-starch glycosidic bonds, negligible viscosity, and a slightly beige color. The geometry of the reaction vessel influenced the properties of dextrins obtained under the same heating power, time, and repetition amounts. Among the conditions used, the most favorable conditions were heating 10 times for 20 s at 200 W in a 10 mL vessel and the least favorable were 15 s cycles. [ABSTRACT FROM AUTHOR]

Published

2024

17. Microwave sintering of nano-sized samarium oxide synthesized by pneumatic impinging flow microchannel reactor: High-value utilization of rare earth.

Author

Ran, Jianfeng, Lv, Peng, Liu, Yuanhong, Guo, Runding, Li, Shiwei, Yin, Shaohua, Huang, Weichao, and Zhang, Libo

Subjects

*RARE earth oxides, *MICROWAVE heating, *PRECIPITATION (Chemistry), *MICROCHANNEL flow, *MICROREACTORS

Abstract

Samarium oxide (Sm 2 O 3), a quintessential lanthanide oxide, garners significant attention in electrocatalysis and photocatalysis. However, the physicochemical properties of precursors and rare earth oxides are hampered by traditional precipitation reactions, mainly due to the asymmetry of time and space. A new anti-clogging strategy based on pneumatic impingement flow is proposed. Subsequently, nano-sized Sm 2 O 3 powder with an ellipsoidal morphology and a median particle size of 70 nm are prepared using the integration of microchannel reaction and microwave heating. Correlation analysis and morphology evolution mechanism reveal intricate relationships among different variables, emphasizing the importance of achieving balance to effectively control crystal properties. Numerical simulations show that the selective heating of microwave make it significantly superior to conventional. Preliminary economic analysis suggests that producing 1 kg of nano-Sm 2 O 3 can yield $57.56. The combination of microchannels and microwaves offers a pathway for the high-value utilization of rare earths and holds significant industrial application prospects. [ABSTRACT FROM AUTHOR]

Published

2024

18. Designing Heterogeneous Catalysts for Microwave Assisted Selective Oxygenation.

Author

Sun, Jia, Hayward, James S., Barter, Michael, Slocombe, Daniel R., and Bartley, Jonathan K.

Subjects

*DIELECTRIC loss, *HETEROGENEOUS catalysis, *MICROWAVE heating, *METAL catalysts, *TECHNOLOGICAL innovations

Abstract

Microwave dielectric heating is an emerging technology in heterogeneous catalysis. However, catalyst design in this field is not as well developed as when conventional heating is used. In this study the selective oxidation of propene to acrolein has been used as a model reaction to understand the how the properties of bismuth mixed metal oxide catalysts can be tuned for use in microwave assisted catalysis. The role of the dielectric properties, that are crucial to enable the catalyst to be heated in the microwave electric field, were determined using cavity perturbation methods. Catalysts with a very high loss tangent reached high temperatures leading to combustion products, whereas materials with a low loss tangent could not be heated and were inactive. Bi2MoO6 and BiVO4 both showed promising performance during an initial screening and were investigated further. For Bi2MoO6, a partial substitution of molybdenum with vanadium resulted in the formation of Bi1−X/3V1−xMoxO4, with a decrease in particle size and dielectric loss tangent, and the highest rate of acrolein production was found when x=0.6 at 15 W microwave power. Higher microwave power resulted in thermal runaway which decreased the activity of the catalyst. [ABSTRACT FROM AUTHOR]

Published

2024

19. Regeneration behavior of solid desiccants with microwave drying.

Author

Zhang, Xiaoyuan, Chen, Meiqian, and Guan, Junli

Subjects

*SILICA gel, *MICROWAVE heating, *TEMPERATURE distribution, *MICROWAVE drying, *ENVIRONMENTAL protection, *DRYING

Abstract

Solid desiccants have been widely used in dehumidification systems, but the regeneration of desiccants is significant for the economy and environment protection. The regeneration performance of several typical solid desiccants was examined in a microwave combined hot air lab-scale setup. The shortest time required for desiccants happened in the combined heating. Among eight desiccants, zeolite in the combined drying took the shortest time to be regenerated. Activated alumina was the most difficult to be regenerated, and it in the hot air drying had the highest absorption capacity, while 3A (1.6–2.5) zeolite in the microwave and combined heating had the highest absorption capacity. Silica gels in all heating modes had the minimum absorption capacity. At low power levels (100-300W), the regeneration performance of the silica gels was prompted by the multi-magnetron radiation modes with the top one. The temperature distribution uniformity in silica gel was lifted with the assisted hot air drying. The multi-magnetron could ameliorate the microwave heating uniformity. The combined drying not only could lift the heating uniformity of the microwave, but also lowered the energy consumption by the traditional hot air drying alone. This study can provide basic data for the design and improvement of the desiccant rotors. [ABSTRACT FROM AUTHOR]

Published

2024

20. Integrating Microwave Heating with Foam-Mat Drying: Drying Kinetics and Optimization for Thick Foamed Mango Pulp.

Author

Jatupon Saijuntha, Wasan Duangkhamchan, Pannipa Youryon, Ronsse, Frederik, and Prarin Chupawa

Subjects

*MICROWAVE heating, *RESPONSE surfaces (Statistics), *ENERGY consumption, *STANDARD deviations, *DRYING, *MANGO

Abstract

This study addresses the challenge of processing undersized or overripe mangoes by integrating microwave heating with traditional foam-mat drying technique. The study aims at investigating drying kinetics coupled with thin-layer drying modeling and influences of microwave power (300 - 600 W) and hot-air temperature (55 - 75 °C). Among ten drying models, the so-called Midilli equation fitted well with experimental data. Results showed enhanced drying process associated with microwave heating, providing reduced drying time from 600 - 700 min (for conventional hot-air mode) to 30 - 100 min (for microwave-assisted mode). Standard deviations of moisture content and dried foam thickness measured at various points revealed uneven heat distribution when using high microwave energy, evidenced by burnt spots at 600 W. Additionally, foam collapse was observed under the mild process with low microwave powers, possibly due to prolonged drying periods. Response surface methodology demonstrated that microwave power was more important factor, positively affecting effective diffusivity coefficient (Deff) while inversely influencing specific energy consumption (SEC) and color difference (ΔE). Deff value increased from 5.41x10-6 m²·s-1 at 300 W and 55 °C to 18.43x10-6 m²·s-1 at 600 W and 75 °C, confirming enhance drying performance. As assisted with microwave heating, drying foamed mango sample consumed less energy up to 92 %. Optimal drying parameters were determined based on balancing the enhancement of drying performance and color alteration, suggesting drying the thick foamed mango pulp at temperature of 55 °C combined with microwave heating at 520 W, which can be served as a basis for further industrial scale-up. [ABSTRACT FROM AUTHOR]

Published

2024

21. Enhancing Iron Ore Grindability through Hybrid Thermal-Mechanical Pretreatment.

Author

Adewuyi, Sefiu O., Ahmed, Hussin A. M., Anani, Angelina, Saeed, Abdu, Ahmed, Haitham M., Alwafi, Reem, and Luxbacher, Kray

Subjects

*IRON ores, *SIZE reduction of materials, *MICROWAVES, *SIMULATION methods & models, *ORES, *ORE-dressing, *MICROWAVE sintering

Abstract

Grinding is an important process of ore beneficiation that consumes a significant amount of energy. Pretreating ore before grinding has been proposed to improve ore grindability, reduce comminution energy, and enhance downstream operations. This paper investigates hybrid thermal mechanical pretreatment to improve iron ore grinding behavior. Thermal pretreatment was performed using conventional and microwave approaches, while mechanical pretreatment was conducted with a pressure device using a piston die. Results indicate that conventional (heating rate: 10 °C; maximum temperature: 400 °C), microwave (2.45 GHz, 1.7 kW, 60 s), and mechanical (14.86 MPa, zero delay time) pretreatments improved the studied iron ore grindability by 4.6, 19.8, and 15.4%, respectively. Meanwhile, conventional-mechanical and microwave-mechanical pretreatments enhanced the studied iron ore grindability by 19.2% and 22.6%, respectively. These results suggest that stand-alone mechanical pretreatment or microwave pretreatment may be more beneficial in improving the grinding behavior of the studied fine-grain iron ore sample. The results of the mechanical pretreatment obtained in this study may be used in a simulation of the HPGR system for grinding operations of similar iron ore [ABSTRACT FROM AUTHOR]

Published

2024

22. COMSOL-Based Simulation of Microwave Heating of Al 2 O 3 /SiC Composites with Parameter Variations.

Author

Li, Guo and Zhou, Jian

Subjects

*ALUMINUM oxide, *MICROWAVE heating, *ELECTROMAGNETIC fields, *ELECTRIC fields, *PROCESS heating

Abstract

The process of microwave heating involves the coupling of multiple physical phenomena, specifically including the distribution of the electromagnetic field in the resonant cavity. The electromagnetic effect generates heat and encourages the transfer of heat inside the material. In this numerical study, a 3D computer model of microwave heating of Al2O3/SiC composites using a multimode microwave heating chamber was established based on the simulation software COMSOL Multiphysics 5.6, and the symmetry treatment of the model was carried out, which effectively reduced the amount of model calculations and accurately analyzed the microwave heating characteristics of the samples. The analysis of the microwave heating characteristics of the sample was mainly preformed from the perspective of the electric field distribution in the resonant cavity, the sample heating rate and the sample heating uniformity, and then it was determined how the microwave source power and sample mold selection affect the temperature and electric field parameters of the sample. After experimental verification, the error between the simulation results and the temperature parameters obtained from the actual experiments is less than 2%. This study contributes to further understanding the heating behavior of Al2O3/SiC composites in complex multimode microwave heating environments and can be used to control the dynamic parameters during microwave heating in order to improve the heating rate and heating uniformity of samples. [ABSTRACT FROM AUTHOR]

Published

2024

23. Oxidative Catalytic Depolymerization of Lignin into Value-Added Monophenols by Carbon Nanotube-Supported Cu-Based Catalysts.

Author

Tang, Chen, Cao, Yang, Gao, Jie, Luo, Gang, Fan, Jiajun, Clark, James H., and Zhang, Shicheng

Subjects

*ELECTRON paramagnetic resonance, *SUSTAINABILITY, *MICROWAVE heating, *REACTIVE oxygen species, *CARBON nanotubes, *LIGNIN structure, *LIGNINS

Abstract

Lignin valorisation into chemicals and fuels is of great importance in addressing energy challenges and advancing biorefining in a sustainable manner. In this study, on the basis of the high microwave absorption performance of carbon nanotubes (CNTs), a series of copper-oxide-loaded CNT catalysts (CuO/CNT) were developed to facilitate the oxidative depolymerization of lignin under microwave heating. This catalyst can promote the activation of hydrogen peroxide and air, effectively generating a range of reactive oxygen species (ROS). Through the application of electron paramagnetic resonance techniques, these ROS generated under different oxidation conditions were detected to elucidate the oxidation mechanism. The results demonstrate that the •OH and O2•− play a crucial role in the formation of aldehyde and ketone products through the cleavage of lignin Cβ-O and Cα-Cβ bonds. We further evaluated the catalytic performance of the CuO/CNT catalysts with three typical lignin feedstocks to determine their applicability for lignin biorefinery. The bio-enzymatic lignin produced a 13.9% monophenol yield at 200 °C for 20 min under microwave heating, which was higher than the 7% yield via hydrothermal heating conversion. The selectivity of G-/H-/S-type products was slightly affected, while lignin substrate had a noticeable effect on the selective production. Overall, this study explored the structural characteristics of CuO/CNT catalysts and their implications for lignin conversion and offered an efficient oxidation approach that holds promise for sustainable biorefining practices. [ABSTRACT FROM AUTHOR]

Published

2024

24. Microwave-Assisted Physical Foaming of Polymers: A Review.

Author

Zhong, Wenyu, Hu, Dongdong, Chen, Yichong, and Zhao, Ling

Subjects

*POROUS materials, *RENEWABLE energy sources, *POROUS polymers, *MICROWAVE heating, *THREE-dimensional printing, *HEAT transfer

Abstract

Over the past two decades, the use of microwaves for physical foaming of polymers has undergone significant advancements. Typically, the preparation of polymer foams during physical foaming relies on heat transfer heating, which results in temperature gradients and consumes significant time and energy. In contrast, microwave-assisted physical foaming offers a simple, convenient, fast, and cost-effective approach for obtaining polymer foams. These features render microwaves an alternative clean energy source that can replace or complement the conventional heating in various foaming processes. This review provides an overview of recent research on the application of microwaves to five different methods for preparing polymeric foams, namely batch foaming, bead foaming, steam foaming, salt immersion foaming, and 3D-printing. The study also highlights key challenges and opportunities for the development of microwave foaming processes and identifies potential areas for future research. [ABSTRACT FROM AUTHOR]

Published

2024

25. Performance and protein conformation of thermally treated silver carp (Hypophthalmichthys molitrix) and scallop (Argopecten irradians) blended gels.

Author

Fan, Xinru, Geng, Wenhao, Li, Meng, Wu, Zixuan, Li, Ying, Yu, Shuang, Zhao, Guanhua, and Zhao, Qiancheng

Subjects

*BAY scallop, *SILVER carp, *PROTEIN conformation, *AQUATIC resources, *MICROWAVE heating

Abstract

BACKGROUND: The quality of surimi‐based products can be improved by combining the flesh of different aquatic organisms. The present study investigated the effects of incorporating diverse ratios of unwashed silver carp (H) and scallop (A) and using various thermal treatments on the moisture, texture, microstructure, and conformation of the blended gels and myofibrillar protein of surimi. RESULTS: A mixture ratio of A:H = 1:3 yielded the highest gel strength, which was 60.4% higher than that of scallop gel. The cooking losses of high‐pressure heating and water‐bath microwaving were significantly higher than those of other methods (P < 0.05). Moreover, the two‐step water bath and water‐bath microwaving samples exhibited a more regular spatial network structure compared to other samples. The mixed samples exhibited a microstructure with a uniform and ordered spatial network, allowing more free water to be trapped by the internal structure, resulting in more favorable gel properties. The thermal treatments comprehensively modified the tertiary and quaternary structures of proteins in unwashed mixed gel promoted protein unfurling, provided more hydrophobic interactions, enhanced protein aggregation and improved the gel performance. CONCLUSION: The findings of the present study improve our understanding of the interactions between proteins from different sources. We propose a new method for modifying surimi's gel properties, facilitating the development of mixed surimi products, as well as enhancing the efficient utilization of aquatic resources. © 2024 Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2024

26. Microstructural investigation of variable tungsten reinforcement in copper-based composite microwave castings.

Author

Bashir, Khalid, Gupta, Dheeraj, and Jain, Vivek

Subjects

*METALLIC composites, *MICROWAVE heating, *RECRYSTALLIZATION (Metallurgy), *MICROWAVE ovens, *COPPER

Abstract

The composite castings of Cu-xW (where; x=5, 10, and 15 wt.%) have been successfully developed by a novel processing route. The concept of microwave hybrid heating is successfully applied in this study and cast samples were developed in a domestic microwave oven with a maximum power of 900 W and at a frequency of 2.45 GHz. The in situ melting and cast samples were developed with in a duration of 07 min of microwave radiation exposure. The microstructure of cast samples developed shows a regular, roughly hexagonal grain growth that resembles cellular proliferation. The recrystallization and grain growth suppression after adding W content in Cu have been revealed. The formation of different phases such as Cu64O and CuWO4 were observed. The Vicker's microhardness value of composite cast samples was observed to increase more than twice of pure copper cast samples. [ABSTRACT FROM AUTHOR]

Published

2024

27. Technologies to decontaminate aflatoxins in foods: a review.

Author

Kinyoro, Ibrahim Shabani and Kaale, Lilian

Subjects

*MICROWAVE heating, *METABOLITES, *AFLATOXINS, *ORGANIC acids, *ARTIFICIAL intelligence, *DECONTAMINATION of food

Abstract

Summary: Aflatoxins are toxic secondary metabolites produced by Aspergillus spp., found in staple food commodities. Aflatoxins are carcinogenic, teratogenic, and mutagenic and pose a serious threat to the health of humans. The identification and quantification of aflatoxins in foods is a major challenge to guarantee food safety. Therefore, developing feasible, sensitive, and robust methods for decontamination is paramount, with short processing time and negligible impact on quality. This review evaluates recent novel technologies for aflatoxins decontamination by physical methods (microwave heating, Gama and electron beam irradiation, pulse light and ultraviolet), chemical methods (ozone, natural plant extracts, and organic acids), and biological methods (atoxigenic Aspergillus strains, Trichoderma spp., and bacteria and yeast). The study highlights on the cutting‐edge technologies of smart packaging and artificial intelligence (AI). To achieve more efficiency and adaptability to different food matrices in aflatoxins decontamination, the study suggests integrating multiple strategies. The study also recommends integrating Partnership for Delivery (P4D) to share the responsibility to increase the chance for success and control aflatoxins in foods. [ABSTRACT FROM AUTHOR]

Published

2024

28. Ancillary ligand effects and microwave‐assisted enhancement on the catalytic performance of cationic ruthenium(II)‐CNC pincer complexes for acceptorless alcohol dehydrogenation.

Author

Yadav, Dibya, Singh, Rahul Kumar, Misra, Shilpi, and Singh, Amrendra K.

Subjects

*LIGANDS (Chemistry), *DEHYDROGENATION, *RUTHENIUM, *CATALYSIS, *MICROWAVES

Abstract

The application of cationic Ru(II)‐CNC pincer complexes [Ru(CNC)(CO)(PPh3)Cl]PF6 (1), [Ru(CNC)(PPh3)2Cl]PF6 (2), [Ru(CNC)(η2:η2‐COD)Cl]PF6 (4), and [Ru(CNC)(DMSO)2Cl]PF6 (5) in acceptorless dehydrogenation of alcohols is reported under conventional "oil‐bath" and microwave heating conditions. The effect of different ancillary ligands (CO, PPh3, COD, and DMSO) have been demonstrated during catalysis. Complexes with more π‐acid ligands CO and COD perform better compared with those with PPh3 and DMSO ligands. A plausible mechanism is proposed based on NMR and mass investigation during the catalysis. The catalytic performance matches with the order of trans effect among the four ancillary ligands studied in these complexes. Further, a significant reduction in reaction time, as well as reaction temperature, was observed for catalytic reactions under the microwave‐assisted reaction compared with the oil‐bath heating reaction. [ABSTRACT FROM AUTHOR]

Published

2024

29. Universal, minute-scale synthesis of transition metal compound nanocatalysts via graphene-microwave system for enhancing sulfur kinetics in lithium-sulfur batteries.

Author

Yang, Chao, Liu, Haoliang, Wang, Yijia, Yang, Jiaxi, Yin, Haosen, Deng, Leping, Bai, Yuge, Zhao, Bin, Xiao, Bing, and Han, Xiaogang

Subjects

*LITHIUM sulfur batteries, *TRANSITION metal compounds, *NANOPARTICLES, *SULFUR, *GRAPHENE oxide, *MICROWAVE heating, *METAL compounds

Abstract

[Display omitted] The application of Li-S batteries on large scale is held back by the sluggish sulfur kinetics and low synthesis efficiency of sulfur host. In addition, the preparation of catalysts that promote polysulfide redox kinetics is complex and time-consuming, reducing the cost of raw materials in Li-S. Here, a universal synthetic strategy for rapid fabrication of sulfur cathode and metal compounds nanocatalysts is reported based on microwave heating of graphene. Heat-sensitive materials can achieve rapid heating due to graphene reaching 500 ℃ within 4 s via microwave irradiation. The MoP-MoS 2 /rGO catalyst demonstrated in this work was synthesized within 60 s. When used for catalysts for Li-S batteries whose graphene/sulfur cathodes were also synthesized by microwave heating, enhanced catalytic effect for sulfur redox reaction was verified via experimental and DFT theoretical results. Benefiting from fast redox reaction (MoP), smooth Li+ diffusion pathways (MoS 2), and large conductive network (rGO), the assembled Li-S battery with MoP-MoS 2 /rGO-Add@CS displays a remarkable initial specific capacity, stable lithium anode and good cycle stability (in pouch cells) using this two-pronged strategy. The work provides a practical strategy for advanced Li-S batteries toward a wide range of applications. [ABSTRACT FROM AUTHOR]

Published

2024

30. A review of microwave–metal discharge interaction: Mechanism, regulation, and application for synthesis of nanomaterials.

Author

Xie, Yixuan, Shi, Ruiqian, Fu, Benwei, Song, Chengyi, Shang, Wen, Tao, Peng, and Deng, Tao

Subjects

INTERMETALLIC compounds, MICROWAVE heating, MICROWAVE ovens, METALLIC surfaces, HIGH-frequency discharges

Abstract

Placing metals within microwave ovens has been generally viewed as a dangerous practice because of occurrence of violent discharge, but in recent years such discharge phenomenon has attracted increasing attention and has enabled a variety of exciting applications. In this work, we provide a comprehensive review of fundamental understanding of microwave–metal discharge interaction and its state-of-the-art application for nanomaterials synthesis. We introduce the microscopic interaction between different categories of materials and the electric and magnetic field of microwaves. For microwave–metal interaction, we highlight its size-dependence and point out the influence of the oxide layer on the surface of metals. We discuss the required conditions for occurrence of discharge, microscopic formation mechanism, and characteristic features of microwave–metal discharge processes. Through analyzing the influence from the microwave input, discharging metals, and surrounding discharging media, we discuss the strategy for systematical regulation of the discharge process. We describe the applications of the microwave–metal discharge for facile synthesis of various functional nanomaterials including core–shell carbon/metal, metal oxides, metal chalcogenides, intermetallic compounds, metallic nanoparticles and metallic compounds, and organic compounds. Finally, the challenges in precise characterization and dynamic regulation of the discharge process as well as exciting application opportunities are discussed. [ABSTRACT FROM AUTHOR]

Published

2024

31. 微波技术在稀土领域中的应用研究进展.

Author

马升峰, 徐惠, 高天佐, 候少春, 陈明光, 曾青云, 刘勇, 冯伟, 高凯, 李裕, and 许延辉

Subjects

MICROWAVE heating, PROCESS heating, MANUFACTURING processes, HYDROMETALLURGY, MICROWAVES

Abstract

Copyright of Hydrometallurgy of China is the property of Hydrometallurgy of China Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

32. Fast microwave-assisted methacrylation of Pluronics for photoinduced 3D printing.

Author

Bomediano, Mateus P., Santos, Murilo I., Lorevice, Marcos V., Romano, Giovana B., da Silva, Laura C. E., Junior, Airton G. S., and de Oliveira, Marcelo G.

Subjects

THREE-dimensional printing, CHEMICAL reactions, ORGANIC solvents, HYDROGELS, POLYMERS

Abstract

Methacrylation of Pluronics enables 3D printing of irreversible hydrogel constructs, thereby diversifying their potential applications. Current methods rely on organic solvents and time-consuming reactions. Herein, a rapid method for the microwave-assisted methacrylation of Pluronics by methacrylic anhydride (MA) in the absence of organic solvents is presented, which reduced the reaction time from 24 h to ca. 10 min. 1H-NMR analysis showed that this method allows modulating the methacrylation degree (MD) of Pluronics from 45 to 97% by using different MA:Pluronic ratios. 3D-printed constructs with lower MD showed larger pores and lower compression modulus. [ABSTRACT FROM AUTHOR]

Published

2024

33. Plant protein and animal protein‐based Pickering emulsion: A review of preparation and modification methods.

Author

Wen, Jiayu, Jiang, Lianzhou, and Sui, Xiaonan

Subjects

PLANT proteins, MICROWAVE heating, CHEMICAL properties, SPRAY drying, HYDROSTATIC pressure

Abstract

Protein‐based Pickering emulsions are gaining popularity due to their biocompatibility and alignment with people's pursuit of health. This review focuses on recent advances in the preparation of Pickering emulsions using various plant and animal proteins from different sources. For sustainability and cost reasons, plant proteins are preferred, while animal proteins provide better nutritional quality. According to the type of plant or animal protein, the suitable modification and preparation methods of stable Pickering emulsion are summarized, including heating, enzyme induction, anti‐solvent precipitation, pH‐cycling, glycosylation, microwave heating, spray drying, and high hydrostatic pressure. Different methods were employed to modify the properties of Pickering emulsion particles at the oil–water interface. To overcome the amphiphilicity limitations of some proteins, substances such as polysaccharides or polyphenols were combined to improve the physical and chemical properties of the particles. Additionally, this review analyzes the effect of different protein particle sources on the properties of Pickering emulsions. [ABSTRACT FROM AUTHOR]

Published

2024

34. The Effects of Different Cooking Systems on Changes in the Bioactive Compounds, Polyphenol Profiles, Biogenic Elements, and Protein Contents of Cauliflower Florets.

Author

Ahmed, Isam A. Mohamed, Al-Juhaimi, Fahad Y., Özcan, Mehmet Musa, Uslu, Nurhan, and Karrar, Emad

Subjects

MICROWAVE heating, BLANCHING (Cooking), MICROWAVE ovens, GALLIC acid, MICROWAVE cooking

Abstract

In the current study, we examined the effects of boiling cauliflower in a pressure cooker, conventional boiling, conventional heating, and microwave heating on the chemical components, total phenol, flavonoids, antioxidant capacity (DPPH test), phenolic compounds, and mineral contents of cauliflower florets to reveal the differences between these cooking methods. Cauliflower is generally consumed either boiled or cooked in dry heat. In this study, different boiling and dry heat cooking methods were tried to reveal the changes in phytochemical composition and protein and mineral contents of cauliflower florets. Depending on the cooking methods of the cauliflower florets, the total phenolic and flavonoid contents of the cauliflower florets were determined to be between 273.72 (conventional heating) and 731.01 mg GAE/100 g (microwave heating) and 142.02 (conventional heating) and 797.10 mg/100 g (conventional boiling), respectively. The antioxidant capacity results of cauliflowers were found to be between 8.30 (conventional heating) and 33.69 mmol/kg (fresh). Statistically significant differences were detected in the moisture, total phenol, total flavonoid, and antioxidant activity values of cauliflower depending on the cooking techniques applied (p < 0.05). The gallic acid and 3,4-dihydroxybenzoic acid values of fresh and cooked cauliflowers were identified to be between 10.93 (microwave heating) and 194.79 mg/100 g (boiling in pressure cooker) and 17.58 (conventional heating) and 145.80 mg/100 g (boiling in pressure cooker), respectively. In general, the lowest amounts of phenolic compounds were defined in cauliflower samples boiled with a conventional heating system, followed by cauliflower samples cooked with the microwave heating method. Considering the component amounts as a result of cooking, the highest phenolic component amounts were specified in the cauliflower sample cooked by boiling in a pressure cooker. The protein quantities of fresh and cooked cauliflowers were determined to be between 16.11 (fresh) and 19.79% (microwave heating). The K and S contents of fresh cauliflowers and cauliflowers cooked with different blanching methods were specified to be between 19,647.62 (conventional boiling) and 35,130.01 mg/kg (conventional heating) and 3196.54 (boiling in pressure cooker) and 5105.65 mg/kg (microwave heating), respectively. The K, Mg, S, Fe, Cu, Mn, and Zn results of cauliflowers cooked in an oven and microwave were higher than those cooked using the control and boiling methods. [ABSTRACT FROM AUTHOR]

Published

2024

35. Upgrading Biomass Wastes to Graphene Quantum Dots with White-Light-Emitting Features in the Solid State.

Author

Magri, Pierre, Franchetti, Pascal, Gaumet, Jean-Jacques, Maxit, Benoit, Diliberto, Sébastien, and Pierrat, Philippe

Subjects

QUANTUM dot synthesis, CARBON-based materials, X-ray photoelectron spectroscopy, MICROWAVE heating, TRANSMISSION electron microscopy

Abstract

The emergence of bio-based carbonaceous materials for various applications has attracted significant attention during the last few years. Here, we report a rapid, efficient, and reproducible microwave-assisted synthesis of graphene quantum dots (GQDs) with identical features irrespective of the nature of biomass waste investigated. The synthesized GQDs were fully characterized by X-ray photoelectron spectroscopy, Fourier-transform infrared spectroscopy, transmission electron microscopy, and dynamic light scattering. The nanoparticles displayed narrow sizes of 1–2 nm and high solubility in polar solvents such as water and ethanol. The protocol described herein is advantageous in comparison to dealing with the synthesis of GQDs from biomass waste previously reported since our protocol is faster owing to the use of microwave heating and the avoidance of dialysis for the purification step. Furthermore, in solution, the water-soluble particles showed excitation-dependent photoluminescence ranging from blue to orange emission wavelengths. Interestingly, thin films displayed white-light emission under 325 nm UV-light excitation, while aggregation-induced quenching was usually observed, opening the way for their potential use as a phosphor in white-light-emitting diodes. [ABSTRACT FROM AUTHOR]

Published

2024

36. Energy and exergy performances of low-density polyethylene plastic particles assisted by microwave heating.

Author

Zhao, Wenke, Zhang, Yaning, Cui, Longfei, Fu, Wenming, and Liu, Wei

Subjects

LOW density polyethylene, PLASTIC scrap, ENERGY consumption, EXERGY, MICROWAVE heating, MICROWAVES

Abstract

Plastic waste can exist naturally for hundreds of thousands of years and harm humans, animals, and the environment. In this study, the energy and exergy performances (absorbed energy, energy efficiency, absorbed exergy, and exergy efficiency) of LDPE (low-density polyethylene) plastic particles assisted by microwave heating based on the experimental data as affected by microwave power, feeding load, and chamber volume were evaluated and analyzed. The results showed that as the microwave power raised from 500 to 900 W, the feeding load changed from 10 to 30 g, and the chamber volume decreased from 200 to 100 ml, (a) the absorbed energy at the heating time of 60 min increased from 19.73 kJ, 5.84 kJ, and 22.71 kJ to 37.69 kJ; (b) the energy efficiency for the whole heating process increased from 1.10%, 0.32%, and 1.26% to 2.09%; (c) the absorbed exergy at the heating time of 60 min increased from 0.308, 0.091, and 0.091 to 0.724 kJ; and (d) the exergy efficiency for the whole heating process increased from 0.017, 0.005, and 0.023 to 0.040%, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

37. Heating performances of corn straw particle with/without SiC particle in a microwave chamber.

Author

Cui, Longfei, Zhao, Wenke, Mostafa, Ehab, and Zhang, Yaning

Subjects

CORN straw, BIOMASS production, SILICON carbide, BIOCHAR, BIOGAS, MICROWAVE heating

Abstract

The amount of biomass production each year is huge, and microwave-assisted pyrolysis of biomass to obtain biogas, bio-oil, and biochar is a promising method. In this study, silicon carbide (SiC) was selected as the microwave absorber, and the effects of microwave power (400, 450, 500, 550 and 600 W), reactor chamber volume (100, 150, 200, 250, and 300 W), and the mass ratio of SiC and corn straw (0, 0.25, 0.5, 0.75, and 1) on the heating performances of corn straw particles were investigated and presented in this study. When the microwave power increased from 400 to 600 W, the average heating rate of corn straw particles increased from 23.06 ℃ /min to 101.46 ℃ /min, and that of mixture particles of corn straw and SiC increased from 87.00 ℃ /min to 236.88 ℃/min. When the reactor chamber volume increased from 100 to 300 mL, the average heating rate of corn straw particles decreased from 38.21 ℃/min to 22.54 ℃/min, and that of mixture particles of corn straw and SiC decreased from 98.84 ℃/min to 76.01 ℃/min. When the mass ratio of SiC and corn straw increased from 0 to 1, the average heating rate of mixture particles of corn straw and SiC increased from 101.46 ℃/min to 236.88 ℃/min. Some formulae with R2 values ranged from 0.971 to 0.998 were proposed to determine the transient temperatures of corn straw particles and mixture particles of corn straw and SiC. [ABSTRACT FROM AUTHOR]

Published

2024

38. 微波强化煤层气井压裂开采的物性规律.

Author

李小刚, 秦　杨, 刘紫微, 朱静怡, 杨兆中, 谢诗意, 金心岫, and 高晨轩

Abstract

Copyright of Special Oil & Gas Reservoirs is the property of Special Oil & Gas Reservoirs Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

39. Mechanical properties and damage constitutive relationship of microwave irradiation of granite under uniaxial compression.

Author

Li, Diyuan, Lyu, Xinxin, Zhou, Aohui, Ru, Wenkai, and Su, Xiaoli

Subjects

*DIGITAL image correlation, *CRACK closure, *ELASTIC modulus, *CRACK propagation (Fracture mechanics), *ROCK music

Abstract

AbstractMicrowaves have great potential to increase the efficiency of hard rock breakage during mechanical excavation in engineering. This study conducted uniaxial compression tests on granite specimens after microwave irradiation at 4.85 kW. The results demonstrated a linear decrease in uniaxial compressive strength and elastic modulus correlating with increasing irradiation durations. Acoustic emission data indicated increased normalized crack closure stress and decreased normalized crack initiation and damage stress, suggesting complex crack propagation and evolution patterns under microwave influence. 3D Digital Image Correlation revealed that as heating time increased, the macrocrack leading to specimen failure shifted from being load-dominated to involving both load and microwave-induced thermal cracks. A simple four-parameter damage constitutive model for granite (a1, r1, a2, and r2) effectively described the damage evolution under the coupling effect of microwave and uniaxial load. The model accurately characterized the complete stress–strain curves, including both microcrack compaction and post-peak stages, revealing that initial damage escalates with longer heating, though the progression rate decreases. [ABSTRACT FROM AUTHOR]

Published

2024

40. Comparative analysis of methane and natural gas pyrolysis for low-GHG hydrogen production.

Author

Di Liddo, Luke, Cepeda, Francisco, Saegh, George, Salakhi, Mehdi, and Thomson, Murray J.

Subjects

*NATURAL gas, *HYDROGEN production, *GREENHOUSE gases, *GREEN business, *CARBON dioxide

Abstract

Methane pyrolysis is emerging as an attractive clean hydrogen production method. As its commercialization proceeds, the pyrolysis of natural gas (NG) becomes pertinent. In this work, the decomposition of pure methane and a realistic NG mixture are compared experimentally and numerically. Methane and NG pyrolysis are performed between 600 and 1200 °C over a fluidized bed of carbon particles heated by microwaves. Experimentally, no conclusive difference is observed in methane conversion between methane and NG pyrolysis. Numerically, the methane conversion rate is 8.5% higher for NG at 950 °C. The difference diminishes past 950 °C, becoming 0 past 1050 °C. The simulations showed that the enhanced methane decomposition in NG pyrolysis is due to an attack on methane by radicals generated during ethane and propane decomposition. The CO 2 in our NG mixture decomposes into CO. This work validates the longstanding use of methane pyrolysis as a surrogate for NG pyrolysis. • Experimentally, no conclusive difference between NG and pure CH 4 pyrolysis. • Numerically, NG pyrolysis had at most 8.5% higher methane conversion. • Radicals from ethane decomposition attacked methane and increased methane conversion. • Inlet C 2 H 6 > 10 vol% increased the outlet CH 4 rather than aiding its decomposition. • CO 2 in the NG mixture decomposed into CO, implying non-zero GHG emissions. [ABSTRACT FROM AUTHOR]

Published

2024

41. Controllable Atomic Migration in Microstructures and Defects for Electromagnetic Wave Absorption Enhancement.

Author

Su, Xiaogang, Wang, Jun, Liu, Tong, Zhang, Yu, Liu, Yanan, Zhang, Bin, Liu, Yaqing, Wu, Hongjing, and Xu, He‐Xiu

Subjects

*MICROWAVE heating, *KIRKENDALL effect, *POINT defects, *IMPEDANCE matching, *COBALT sulfide, *ELECTROMAGNETIC wave absorption

Abstract

Defects and microstructures have been utilized to effectively modulate electromagnetic (EM) wave absorption for mitigating electromagnetic pollution and stealth issues. However, precisely feasibly tailoring them still remains challenging. Here, by using a multilevel hollow cobalt sulfide embedded in a heteroatomic sulfur (S) ‐doped carbon aerogel, a preferential reaction strategy of modulating point defects and hollow microstructures via controllable S atoms migration is proposed to improve the EM wave absorption. S atoms contribute to the creation of hollow structures via Kirkendall effects, as well as inducing point defects in the carbon lattice through doping. More significantly, the mechanisms prioritizing the formation of hollow structures over defects have been discovered, with low‐velocity atomic migration primarily modulating the microstructure for interfacial polarization and impedance matching, and high‐velocity atom migration focused on introducing defects to achieve polarization and conductive loss. The resulting aerogel exhibits an exceptionally maximum reflection loss of −52.82 dB and an effective absorption bandwidth of 8.82 GHz, which far exceeds most of the currently reported materials. Experimental and theoretical approaches, including microwave heating, Tesla interaction, first principles, and far‐field simulation, are comprehensively employed to verify its absorption effect and mechanism. Furthermore, the combination of excellent infrared stealth and self‐cleaning properties opens up its potential applications in complex environments. [ABSTRACT FROM AUTHOR]

Published

2024

42. Emerging Novel Processing Technologies Towards the Stabilization of Anthocyanins.

Author

Zhu, Jingliang, Geng, Yaqian, Huang, Yuan, Ma, Chen, Dong, Li, Chen, Fang, Hu, Xiaosong, Ma, Lingjun, and Ji, Junfu

Subjects

*SUPERCRITICAL carbon dioxide, *MICROWAVE heating, *RESISTANCE heating, *FLAVONOIDS, *LOW temperature plasmas, *ANTHOCYANINS

Abstract

Anthocyanins, abundant flavonoid pigments in fruits and vegetables, have gained considerable attention for their attractive colors and potential health-promoting effects. However, the instability of anthocyanins during food processing, especially thermal processing, has greatly hampered their practical application. As heat-sensitive compounds, conventional thermal processing is responsible for the degradation of anthocyanins and an alteration of their stability and antioxidant properties, thus lowering the health benefits of anthocyanin-rich foods. Fortunately, novel thermal (ohmic heating and microwave) and non-thermal processing techniques (ultrasound, pulsed electric field, irradiation, ultraviolet, high pressure, supercritical carbon dioxide, cold plasma, ozone, membrane processing) have emerged as promising alternatives to maximize the retention of anthocyanins during food processing, while minimizing the negative impact of conventional thermal treatments on food nutrition and quality. This paper reviews the negative effects of conventional thermal processing on anthocyanins and the benefits of novel techniques on maintaining anthocyanins and bioactive abilities. Importantly, booming novel processing techniques are specially focused on exploring their application to retaining anthocyanins, providing potential stabilization strategies for the future processing of anthocyanin-rich foods. [ABSTRACT FROM AUTHOR]

Published

2024

43. Model-Based PID Tuning Method for a Reactor for Microwave-Assisted Chemistry.

Author

Kozłowski, Sebastian, Korpas, Przemysław, Wojtasiak, Wojciech, and Borowska, Magdalena

Subjects

*PID controllers, *MICROWAVES, *COMPUTER simulation, *RADIATION, *EBULLITION

Abstract

This paper presents a model-based PID tuning method for a reactor used in microwave-assisted chemistry. The reactor is equipped with a solid-state source of microwaves and a PID controller capable of increasing or decreasing the delivered microwave power to maintain the reacting substances at the desired temperature. The model has the form of an algorithm applied in numerical simulations of two simultaneous processes: heating a substance by absorbing microwave radiation and cooling it by dissipating heat to the surroundings. It has proven its suitability for tuning the PID controller in a time-efficient manner. Despite some noticeable inaccuracies, the presented approach easily finds PID coefficients that result in stable and repeatable controller operation. In this way, significant time savings can be achieved, as well as minimizing the risks associated with, for example, boiling liquid spills. The article demonstrates that a carefully designed, but still relatively simple, model can yield significant benefits in tuning PID controllers. [ABSTRACT FROM AUTHOR]

Published

2024

44. Microwave Hybrid Sintering and Soldering of Cu-Cr-W Composite Material for Reactive Power Breakers.

Author

Savu, Sorin Vasile, Ghelsingher, Cristian Daniel, Ștefan, Iulian, Sîrbu, Nicușor-Alin, Midan, Andrei-Angelo, Dumitru, Ilie, Savu, Ionel Dănuț, Nicolicescu, Claudiu, and David, Andrej

Subjects

*MICROWAVE sintering, *REACTIVE power, *ELECTRIC circuits, *ELECTRIC circuit breakers, *ELECTRIC power failures, *TUNGSTEN alloys

Abstract

Over 60% of reported failures for reactive power compensation systems are given for damage to electrical circuit breaker contacts. This paper presents a study on the development of microwave technology for sintering of W–Cu–Cr alloys at 1012 °C for 65 min using 623.38 W microwave power, as well as microwave joining at 231 °C of the W–Cu–Cr composite material on body contact using 475 W microwave power for 55 s. The joined components were subjected to mechanical and electrical tests in accordance with ICE standards to validate the applied technology. Tests of connection–disconnection of the electrical contacts were carried out in accordance with the maximum number of disconnections allowed by the manufacturer (2 cycles/min): 25 s rest time and 5 s operating time under load. The components of the electrical contact after 111237 switches were analyzed under a microscope revealing a reduction of the damaged area by 27% compared with the original contact. [ABSTRACT FROM AUTHOR]

Published

2024

45. Enhancement of Microwave Heating Technology for Emulsified Asphalt Mixtures Using SiC-Fe 3 O 4 Composite Material.

Author

Xu, Sheng, Xu, Wen, Chen, Yixing, Li, Jiaqi, and Li, Yueguang

Subjects

*WATER damage, *SKID resistance, *MICROWAVE heating, *WEAR resistance, *COMPOSITE materials

Abstract

The application of microwave heating technology can significantly enhance the water evaporation rate of emulsified asphalt mixtures post paving. To improve the microwave absorption and curing performance of these mixtures, SiC-Fe3O4 composite material (SF) was incorporated. This addition aims to enhance the microwave absorption efficiency and accelerate the curing process of emulsified asphalt mixtures under microwave heating. This study begins with an analysis of the microwave absorption principles pertinent to emulsified asphalt mixtures. Subsequently, the microwave heating temperature fields of ordinary emulsified asphalt mixture (EAM), SiC emulsified asphalt mixture (S-EAM), Fe3O4 emulsified asphalt mixture (F-EAM), and SiC-Fe3O4 emulsified asphalt mixture (SF-EAM) were simulated using COMSOL Multiphysics finite element software (COMSOL 6.2). The early strength variations in SF-EAM under different microwave heating durations were then examined through adhesion tests, leading to the proposal of a microwave heat curing process for SF-EAM. Finally, the wear resistance, water damage resistance, rutting resistance, and skid resistance of SF-EAM post-microwave curing were evaluated through wet wheel wear tests, wheel track deformation tests, and road friction coefficient tests. The results indicate that the optimal microwave heating time is 90 s, with the microwave absorption performance of the materials ranked as follows: EAM, S-EAM, F-EAM, and SF-EAM, from lowest to highest. The road performance of SF-EAM complies with specification requirements, and its wear resistance, water damage resistance, and rutting resistance are notably improved after microwave heating. [ABSTRACT FROM AUTHOR]

Published

2024

46. Experimental study of microwave-catalytic oxidative degradation of COD in livestock farming effluent by copper-loaded activated carbon.

Author

Cai, Qingfeng, Zhang, Xiao, Geng, Wenguang, Liu, Fang, Yuan, Dongling, and Sun, Rongfeng

Subjects

CHEMICAL oxygen demand, CHEMICAL decomposition, CATALYTIC oxidation, SCANNING electron microscopy, ACTIVATED carbon, MICROWAVE heating

Abstract

The problem of massive discharge of livestock wastewater is becoming more and more severe, causing irreversible damage to the ecological environment, and how to treat livestock wastewater efficiently and rapidly deserves to be studied in depth. In this work, CuO/granular activated carbon (GAC) loaded catalysts were prepared and characterized by scanning electron microscopy (SEM), X-ray diffraction (XRD), nitrogen adsorption/desorption techniques, and X-ray energy spectroscopy (EDS). The results showed that CuO was successfully attached to the GAC surface with good adsorption performance. The effects of catalyst dosage, H2O2 dosage, initial pH, microwave power and microwave irradiation time in different reaction systems on the degradation efficiency of chemical oxygen demand (COD) in wastewater were investigated, and the orthogonal experiments were used to explore the importance ranking of these factors. The highest degradation rate of COD was found to be enhanced by 12.1% in the reaction system of CuO/GAC, and the initial pH had the greatest effect on the COD removal rate. The combined MW/catalyst/H2O2 method used in this work provided a rapid and effective degradation of COD in wastewater, which can be helpful for reference in other microwave catalytic oxidation studies. [ABSTRACT FROM AUTHOR]

Published

2024

47. A Comparative Study of Microwave and Resistance Heating for the Efficient Thermal Desorption of Mineral Oil from Contaminated Soils.

Author

Xu, Jun, Liu, Songtao, and Chen, Chuanmin

Abstract

The contamination of soils by mineral oils presents a significant environmental challenge, particularly due to the widespread use of petroleum products in various industrial sectors. This study investigates the efficiency of microwave heating compared to conventional resistance heating for the thermal desorption of mineral oil from contaminated soils. The experimental results demonstrated that microwave heating offers superior performance in terms of pollutant removal efficiency, energy consumption, and the preservation of soil's physical and chemical properties. This study further conducted a kinetic analysis of the desorption process, revealing that microwave heating follows a first-order kinetic model and requires lower activation energy than conventional methods. The findings suggest that microwave-assisted thermal desorption is a highly effective and energy-efficient technology for soil remediation, providing a potential alternative to conventional techniques. This research offers valuable insights into optimizing thermal desorption processes for environmental remediation, with implications for broader applications in soil treatment. [ABSTRACT FROM AUTHOR]

Published

2024

48. Metallurgical and Mechanical Assessment of SS2205/SS304 Joints Fabricated Using Modified Selective Microwave Hybrid Heating-Based Joining.

Author

Kumar, Virinder and Sehgal, Shankar

Subjects

FILLER materials, MICROWAVE heating, TENSILE strength, X-ray diffraction, GRAPHITE

Abstract

This study proposes a novel modified joining technique based on selective microwave hybrid heating. Primary objective of this article is to investigate the joining of dissimilar materials, specifically SS2205 and SS304 alloys, with nickel as filler material and graphite rods as susceptors. Following input parameters were used such as power level: 900 W, frequency: 2.45 GHz, number of graphite rods: 16 (each having diameter 2 mm; length 30 mm), ceramic wool: 100 × 50 × 50 mm3, and processing time: 750 s. Mechanical testing of the joints showed an average microhardness of 494.52 HV and ultimate tensile strength of 407.83 MPa with 11.34% elongation. Joint region was analyzed using x-ray diffraction, revealing the presence of various intermetallics and carbides, including FeNi, FeNi3, CrNi3, Ni3C, Fe3C, and C2Cr3. Microstructural examination confirmed a robust metallurgical bond between the two joining surfaces, demonstrating the absence of interfacial cracking. [ABSTRACT FROM AUTHOR]

Published

2024

49. Dielectric Engineering of Perovskite BaMnO3 for the Rapid Heterogeneous Nucleation of Pt Nanoparticles for Catalytic Applications.

Author

Hughes, Lucia, Roy, Ahin, Yadav, Neelam, Downing, Clive, Browne, Michelle P., Vij, Jagdish K., and Nicolosi, Valeria

Subjects

*ELECTRON energy loss spectroscopy, *SCANNING transmission electron microscopy, *MICROWAVE heating, *DIELECTRIC loss, *HETEROGENOUS nucleation

Abstract

Microwave heating provides a rapid method for the heterogeneous nucleation of noble metal particles on perovskite support materials for electrocatalytic purposes. To succeed, dielectric tuning of perovskite materials becomes fundamental. Herein, the dielectric engineering of the BaMnO3 perovskite system is carried out through the use of B‐site doping to give BaTi0.5Mn0.5O3. Using a combination of atomic‐scale imaging and electron energy loss spectroscopy (EELS), the preferential filling of the M1 and M3 B‐sites with Mn and Ti ions in the 12R‐rhombohedral perovskite structure is established. While the addition of Ti in the BaMnO3 system has no detrimental effects on the presence of the oxygen reduction reaction (ORR) active Mn3+ states at the surface, it does alter the dielectric constant and loss tangent, thus facilitating the heterogeneous nucleation of Pt nanoparticles on BaTi0.5Mn0.5O3 via rapid microwave heating. Higher Pt loading regimes are found to increase the size and aggregation of the nucleated particles, thus reducing their ORR activity. Therefore, lower Pt loading not only reduces costs but improves overall activity. This work represents future possibilities for the dielectric engineering of perovskite and similar support materials to aid in the quick and easy formation of stable noble metal‐support catalytic systems. [ABSTRACT FROM AUTHOR]

Published

2024

50. Room-temperature synthesis of a Zr–UiO-66 metal–organic framework via mechanochemical pretreatment for the rapid removal of EDTA-chelated copper from water.

Author

Wu, Yi-nan, Cai, Junyi, Hou, Shuliang, Chen, Rui, Wang, Ziqi, Kabtamu, Daniel Manaye, Zelekew, Osman Ahmed, and Li, Fengting

Subjects

*COPPER, *METAL-organic frameworks, *HEAVY metal toxicology, *COMMODITY futures, *MICROWAVE heating, *ADSORPTION kinetics, *WATER purification

Abstract

Treatment of heavy metal pollution in complexed states within water bodies presents significant challenges in the current water treatment field. Adsorption as a means for the removal of heavy metals is characterized by its simplicity of operation, stable effluent, and minimal equipment requirements. Metal–organic frameworks (MOFs) as adsorbents hold significant interest for applications in water treatment. In this study, we investigated a green synthesis approach for the ball-milling pretreated synthesis of UiO-66(Zr) at room temperature, abbreviated as UiO-66(Zr)-rm. Besides having the same thermal stability and crystal structure as the product from microwave-assisted synthesis (UiO-66(Zr)-mw), the resulting UiO-66(Zr)-rm features smaller particle size and superior mesoporous structure. The adsorption efficiency and mechanism for removing EDTA-chelated copper (EDTA–CuII), a complexed heavy metal in water, were extensively analyzed. UiO-66(Zr)-rm presented a maximum adsorption capacity over EDTA–CuII of 43 mg g−1 and a much higher adsorption rate (0.16 g (mg h)−1) than UiO-66(Zr)-mw (0.06 g (mg h)−1). Hierarchically mesostructured defects allow the sorbate to have more effective diffusion in a shorter time to achieve faster adsorption kinetics. Benefiting from the mild synthesis conditions and nontoxic solvents, UiO-66(Zr) has the potential to be produced at a scaled-up level, thereby exhibiting excellent adsorption performance for the removal of complexed heavy metals in the future. [ABSTRACT FROM AUTHOR]

Published

2024