Your search keyword '"Rheological Properties"' showing total 12,249 results

1. Green Roads Ahead: Integrating Gum Arabic in Tunisian Asphalt Formulas

Author

Nciri, Nader, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Varma, Anurag, editor, Chand Sharma, Vikas, editor, and Tarsi, Elena, editor

Published

2025

2. Recent advances in natural gums as additives to help the construction and application of edible biopolymer gels: the example of hydrogels and oleogels.

Author

Miao, Wenbo, Jiang, Han, Li, Xiaojing, Sang, Shangyuan, Jiang, Liming, Lin, Qianzhu, Zhang, Zhiheng, Chen, Long, Long, Jie, Jiao, Aiquan, Wang, Jinpeng, Jin, Zhengyu, and Qiu, Chao

Abstract

Novel, innovative approaches like edible gels (hydrogels and oleogels) are important food materials with great scientific interest due to their positive impacts on structural and functional foods and other unique properties. Biopolymers (protein, starch and other polysaccharides) can be excellent and cost-effective materials for the formed edible gels. Recently, natural gums, although also as biopolymers, are preferred as additives to further improve the textural and functional properties of edible gels, which have received extensive attention. However, these studies have not been outlined in previous reviews. In this review, we highlighted the advantages of gums as additives to construct edible gels. Moreover, the various roles (including electrostatic or covalent interactions) for natural gums in regulation of food gel properties (solvent-holding and rheological properties) are highlighted. Finally, the use of natural gums as additives to improve the stability and targeted delivery of phytochemicals in food gels and their application in food systems are summarized. The information covered in this article may be useful for the design of functional foods that can better meet personalized needs of people. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effect of phosphorylated modification on natural inulin: structural characterisation and gel properties.

Author

Chen, Qiang, Luo, Denglin, Yue, Chonghui, Bai, Zhouya, Li, Peiyan, Wang, Libo, and Han, Sihai

Subjects

*FOURIER transform infrared spectroscopy, *ABSORPTION spectra, *INULIN, *SCANNING electron microscopy, *RHEOLOGY

Abstract

Summary: To improve the gel properties of natural inulin (FI), in this study, FI was phosphorylated to prepare natural inulin phosphodiester (PDFI). The structures of FI and PDFI were characterised by Fourier transform infrared spectroscopy (FTIR), particle size and scanning electron microscopy. FI and PDFI gels (mass fraction 20%–40%) were prepared and stored for 0–7 days to study their effects on water‐holding capacity, rheology and texture properties. The FTIR spectra showed absorption peaks of P‐O‐C and P=O bonds, indicating that some hydroxyl groups were replaced and phosphorylation was successful. Compared with FI, the specific surface area of PDFI was increased 7.7‐fold and the microstructure was smoother. When the fraction of PDFI was 35%, the water‐holding rate of PDFI gel was 21.2%, 23.3%, 19.7%, 19.1% and 19.3% higher than FI gel at different storage time, respectively. PDFI gel with higher mass fraction (25%–40%) had lower hardness. Rheological analysis showed that PDFI gels had stronger viscoelastic and solid‐like properties. These results reveal native inulin phosphorylation improved gel properties. [ABSTRACT FROM AUTHOR]

Published

2024

4. The impact of nanofiller composition and nature on the enhancement of mechanical and rheological properties of poly(lactic acid) (PLA) nanobiocomposite films is achieved by regulating the spacing of organic fillers and PLA crystallinity.

Author

Khiati, Zoulikha, Guella, Soufiane, Mrah, Lahouari, and Mezrai, Abdelmoumin

Subjects

*LACTIC acid, *RHEOLOGY, *THERMAL properties, *MOLECULAR weights, *CELLULOSE, *POLYLACTIC acid

Abstract

This study examines the morphology and various thermal, mechanical, and rheological properties of polylactic acid (PLA)-based nanobiocomposites. The objective of this investigation is to evaluate the potential of modified Algerian clay as a nanofiller through an examination of the characteristics of PLA/Mag-CTA and PLA/CMC nanobiocomposites with varying levels of prepared fillers. This study is concerned with the synthesis of poly(lactic acid)/Maghnite-CTA (PLA/Mag-CTA) and poly(lactic acid)/microcrystalline cellulose (CMC) nanobiocomposites, with two distinctive catalysts and organic reinforcements produced in solution. The outcomes of the various techniques employed demonstrate that PLA nanobiocomposites exhibit a mixed morphology, comprising intercalation and exfoliation. The results from the diverse techniques used show that the PLA nanobiocomposites developed have a mixed intercalated-exfoliated morphology. The dispersion of the Maghnite-CTA filler and microcrystalline cellulose was enhanced during the production of the various materials, as well as the presence of aggregates at high levels. The best rheological performance, corresponding to the optimal dispersion of the nanofiller, was observed for a low quantity of organic filler. Thermal behavior properties were significantly enhanced with the incorporation of the two nanofillers. Analysis by steric exclusion chromatography showed that the fillers used in the nanobiocomposite synthesis increased the average molecular weights of the PLA chains, while the polydispersity index remained constant. [ABSTRACT FROM AUTHOR]

Published

2024

5. Investigation of anionic group characteristics of PCEs on the behaviour of fly ash cementitious systems.

Author

Karakuzu, Kemal, Kobya, Veysel, Mardani, Ali, Felekoğlu, Burak, and Ramyar, Kambiz

Subjects

*FLY ash, *RHEOLOGY, *COMPRESSIVE strength, *MORTAR, *PHOSPHATES

Abstract

The compatibility of polycarboxylate-based water-reducing admixtures (PCEs) having different carboxylate, phosphate and sulfonate anionic groups with paste and mortar mixtures containing fly ash (FA) was investigated. It was found that, with an increase in the FA content of the mixtures, the PCE requirement for the target flow decreased and the consistency retention performance was improved due to the decrease in the amount of hydrated cement. An improvement in rheological parameters was observed with an increase in FA content from 15% to 30%. However, increasing the FA replacement level beyond 30% caused stability problems in the mixtures. This problem was eliminated with the addition of PCE. In the paste and mortar mixtures, regardless of the FA substitution ratio, the best performance was obtained with PCEs containing 7% and 5% phosphate and sulfonate, respectively. The most suitable FA replacement ratio in terms of rheological parameters and 28-day compressive strength was 30% and 15%, respectively. It was observed that the PCE anionic group content did not have any significant effect for all FA substitution ratios. [ABSTRACT FROM AUTHOR]

Published

2024

6. Rheological and Textural Characterisation of Chickpea Dough and Baked 3D-Printed Snacks Enriched with Alphitobius diaperinus and Locusta migratoria Powders.

Author

García-Gutiérrez, Nerea, Salvador, Ana, Sanz, Teresa, Ferrando, Montse, Güell, Carme, Méndez, Carmen, and de Lamo-Castellví, Silvia

Subjects

*EDIBLE insects, *MIGRATORY locust, *RHEOLOGY, *3-D printers, *THREE-dimensional printing

Abstract

Edible insect powder is a new ingredient that can be used to create innovative functional and nutritional properties in food products. However, adding insect powder to bakery goods could impact the dough's technological and sensory attributes. This study aims to investigate possible alterations in dough enriched with insect powder and examine the texture of salty snacks produced using a 3D food printer. The doughs were prepared using varying quantities of two types of edible insect powders. The stiff flow properties showed a pseudoplastic behaviour that fit well with a power-law equation. Viscosity and pseudoplasticity increased in proportion to insect powder concentration, with the strongest effect observed for L. migratoria. The linear viscoelastic behaviour exhibited G′ values exceeding G″ values, and both moduli increased with insect concentration. A. migratoria displayed a greater elastic contribution (lower tan δ) compared to A. diaperinus, which correlates with the lower printability of A. migratoria. The texture of the snacks prepared with A. diaperinus demonstrated a rise in the breaking force as the insect concentration increased and exhibited a corresponding texture profile to the control and the 4.6% sample. Moreover, the addition of A. diaperinus heightened the crispiness. [ABSTRACT FROM AUTHOR]

Published

2024

7. Preparation of 3D-Printed Concrete from Solid Waste: Study of the Relationship between Steel Slag Characteristics and Early Performance in 3D Printing.

Author

Zhao, Wanting, Zhao, Yu, Zhu, Lingli, and Guan, Xuemao

Subjects

*NUCLEAR magnetic resonance, *SLAG cement, *RHEOLOGY, *SOLID waste, *THREE-dimensional printing, *MORTAR

Abstract

Using steel slag in architectural three-dimensional (3D) printing not only enhances its utilization efficiency but also significantly reduces cement consumption, thereby mitigating carbon emissions. This study evaluated the substitution of steel slag for cement in 3D printing and examined its impact on rheological properties, fluidity, green strength, and early hydration microstructure based on alkalinity level, particle-size distribution, and blending quantity. The relationship between the early properties of 3D-printed steel slag cementitious materials and their pore microstructures was investigated using low-field nuclear magnetic resonance (NMR) tests. The results showed that high-alkalinity steel slag has superior rheological characteristics and generates a larger amount of gel water within the initial 30 min of hydration. Steel slag particles ranging from 5 to 20 μm had the most significant influence on enhancing the rheological properties of 3D-printed steel slag cementitious materials by facilitating the formation of a flocculated mesh structure during early hydration. Optimal rheological performance was achieved with a dosage level of 10% steel slag, effectively reducing porosity and improving compactness in the mortar. [ABSTRACT FROM AUTHOR]

Published

2024

8. Assessing the Utilization of Sawdust in Water-Based Drilling Fluid for Managing Fluid Loss and Enhancing Viscosity.

Author

Ysbaa, Saadia, Safi, Brahim, Sid, Asma Nour El Houda, Mhadhbi, Mohsen, and Essafi, Wafa

Subjects

*DRILLING fluids, *DRILLING muds, *CARBOXYMETHYLCELLULOSE, *RHEOLOGY, *YIELD stress

Abstract

The evaluation of the use of sawdust in drilling fluid formulation is covered in this study. The investigation focused on the physicochemical and rheological properties of water-based mud (WBM) drilling fluids that included four different dosages of sawdust. These properties included yield stress, plastic viscosity, rheological behavior, gel strength, filtration test (API filtrate; American Petroleum Institute), and pH. The sawdust was employed as a substitute for the polymers commonly used in water-based muds (WBMs) to serve either as a viscosifier or as a fluid loss controller. The current study set out to evaluate how sawdust (diameter ≤630 µm) affected the primary characteristics of the drilling muds. Sawdust was utilized in place of carboxymethyl cellulose polymer (CMC) as a viscosifier and polyanionic cellulose polymer (PAC) as a filtrate reducer at several dosages (0, 10, 20, 50, and 100 g/L). It was found that the sawdust dosage and its role had a significant impact on the rheological characteristics of the drilling fluids. At amounts between 20 and 50 g/L, the sawdust was added as a viscosifier to the drilling fluids under study, resulting in a significant improvement in their physicochemical and rheological parameters (yield stress, plastic viscosity, and gel strength). However, the drilling fluids showed extremely high rheological properties and a viscosity that can slow down fluid circulation in the well when 100 g/L of sawdust were used, totally substituting for the polymers. [ABSTRACT FROM AUTHOR]

Published

2024

9. The Interaction and Rheological Behavior of Preformed Gel Particles with Surfactants.

Author

Jiang, Zuming and Shi, Jing

Subjects

*SPECIFIC heat capacity, *NONIONIC surfactants, *RHEOLOGY, *COCONUT oil, *SURFACE active agents

Abstract

Heterogeneous combination flooding systems are composed of surfactant and viscoelastic preformed gel particles (PGP) that can migrate in the pores. The interactions between PGP and surfactants have an important impact on the system. In our research described here heterogeneous aqueous suspensions of PGP and an anionic surfactant (sodium dodecyl benzene sulfonate, SDBS) or a nonionic surfactant coconut oil alkanolamide, (CDEA) were prepared. The effects of SDBS and CDEA on the swelling and rheological properties of the PGP was investigated. In addition, the influence of SDBS and CDEA on the thermal effects of PGP was studied. The results showed that the swelling ratio, apparent viscosity and storage modulus of the PGP decreased with the increase of SDBS concentration. On the contrary, the CDEA increased the swelling ratio and the rheological properties of PGP. The specific heat capacity ( C p ) of PGP increased with the SDBS concentration and decreased with the CDEA concentration. Similar to the rheological behavior, the influence of interactions on the PGP molecular thermal motion was related to the concentration of the surfactants. Therefore, studying the variation of C p with concentration can provide reference for the reasonable dosage of surfactants in heterogeneous oil displacement systems and a new perspective for investigating the interaction between surfactant and PGP or other polymers. [ABSTRACT FROM AUTHOR]

Published

2024

10. Rheological analysis of blended vs. recovered asphalt binders in rejuvenated mixtures with high reclaimed asphalt pavement.

Author

Imaninasab, Reza, Loria-Salazar, Luis, and Carter, Alan

Abstract

Higher reclaimed asphalt pavement (RAP) in asphalt mixtures requires efficient rejuvenation. The efficiency of the rejuvenation can be evaluated by studying the rejuvenator, new and old binder blend. The blend must represent the binder blend inside the asphalt mixture to reflect reality. Extracting and recovering the binder of the rejuvenated asphalt mixtures containing RAP is the best practice to obtain the binder blend inside the asphalt mixture. However, extraction and recovery is not a common practice to study rejuvenation efficiency since it is time-consuming and energy-demanding with exposure to hazardous chemicals. Instead, blending rejuvenator, new binder and the extracted and recovered (E&R) binder from RAP limits the extraction and recovery to the RAP and minimizes efforts for studying rejuvenation efficiency. This study aims to find the blending conditions under which the blend of the rejuvenator, new and RAP binder represents the E&R binder from asphalt mixture concerning rheological performance and behavior properties. The rheological properties of three binder blends prepared under intense, moderate, and low blending conditions were compared with those of the E&R binder. Performance grade (PG), rutting potential (multiple stress creep and recovery test), fatigue resistance (linear amplitude sweep test) and behavioral characteristics (linearity and complex modulus tests) are the rheological properties of this study. It was found that intense and moderate blending conditions are good representatives of the E&R binder with regard to PG and PG+ designation. In addition, intense, moderate, and low blending conditions can be a surrogate for the PAV-aged E&R binder. It can be claimed that any intensity of blending conditions between intense and moderate lead to binder specimen that is almost identical to E&R binder with respect to rutting potential and characterization. [ABSTRACT FROM AUTHOR]

Published

2024

11. Experimental and Computational Study of Modified Biopolymer Xanthan Gum with Synthetic Vinyl Monomers for Enhanced Oil Recovery.

Author

Abou-alfitooh, Samah A. M., El-Hosiny, F. I., and El-hoshoudy, A. N.

Subjects

ENHANCED oil recovery, POLYSACCHARIDES, ATOMIC force microscopy, RHEOLOGY, BIOPOLYMERS, XANTHAN gum

Abstract

Utilizing xanthan gum, a biodegradable polymer, in enhanced oil recovery (EOR) is imperative wherever there is a need for innovation in oil production that is both cost-effective and environmentally friendly. Xanthan, chosen for its natural sourcing, availability, controllability, eco-friendliness, and biodegradability, proves resilient against harsh reservoir conditions owing to its rigid structure and elongated polysaccharide chains. This study investigates two modified xanthan gum composites, achieved by grafting with synthetic vinyl monomers through emulsified polymerization. Spectroscopic characterization using FTIR and 1H-NMR, along with surface morphology analysis via atomic force microscopy (AFM) and thermal behavior screening through TGA analysis, elucidates the properties of these modified composites. Rheological behavior under reservoir conditions, including stress scanning and viscosity/shear rate dependency, was evaluated. Material modeling with the Materials Studio program simulated the equilibrium adsorption of xanthan and modified biopolymer chains on SiO2-quartz crystal to assess wettability alteration. Simulation results indicate that XG-g-AM, MMA&TEVS exhibit greater stability and surface coverage with more negative electrostatic energies compared to XG and XG-g-AM&MMA. The laboratory runs on a sandstone-packed model to identify the disclosed XG-g-AM&MMA and XG-g-AM, MMA&TEVS biopolymers as promising EOR candidates and wettability modifiers in challenging sandstone reservoirs, as per experimental outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

12. Analysis of elastic and rheological properties of tunnel anchorage support structure under the action of seepage flow.

Author

Wang, Gang, Zheng, Chengcheng, Jiang, Feng, Yuan, Wenpeng, He, Peng, and Xiao, Zhiyong

Abstract

The large deformation and strong rheological characteristics of the underground rock body under complex geological conditions have led to the failure of the support system and even the instability of tunnels from time to time. Based on the theory of groundwater seepage, the elastic solution of the mechanical model of the tunnel anchorage support system under seepage is solved, which reveals the influence of seepage on the peripheral rock and the support parameters of the anchorage support system; the viscoelastic solution is solved according to the corresponding principle of elasticity—viscoelasticity, which analyses the influence of seepage on the rheological process of the anchorage support system; and the model is simulated with the help of finite element software, which analyses the agreement and discrepancy of the numerical solution and the theoretical solution. The results show that the analytical and numerical solutions are basically consistent. This study can provide important guidance for controlling long-term stability of water-rich tunnel rocks. [ABSTRACT FROM AUTHOR]

Published

2024

13. Relaxor-like behavior of the dielectric response of dense ferroelectric composites.

Author

Pylypchuk, Oleksandr S., Ivanchenko, Serhii E., Zagorodniy, Yuriy O., Yelisieiev, Mykola E., Shyrokov, Oleksandr V., Leschenko, Oksana V., Bereznykov, Oleksii, Stetsenko, Denis, Skapin, Sreco Davor, Eliseev, Eugene A., Poroshin, Vladimir N., Vainberg, Victor V., and Morozovska, Anna N.

Subjects

*DIPOLE moments, *POLYVINYL butyral, *TAPE casting, *NANOPARTICLES, *FINITE element method, *DIELECTRIC properties

Abstract

We study experimentally and theoretically the influence of size effects and structural factors on the dielectric and ferroelectric properties of the dense ferroelectric composites. The composites have the form of the tape-casted films with 28 vol% of nanosized or submicron BaTiO 3 particles dispersed in the polyvinyl butyral. We measured and analyzed the temperature dependences of the capacitance and dielectric losses in the temperature range (−200 – +200)oC and frequency range (102–105) Hz. The nonmonotonic temperature dependences of dielectric permittivity of the studied composite films have a wide plateau-like maxima located between 80oС and 160oС, in contrast to the relatively sharp maximum near the Curie temperature (∼124oC) observed in the fine-grained and coarse-grained ceramics, sintered from the same nanosized or submicron BaTiO 3 particles at 1250oC. The shift of the dielectric permittivity and losses maxima (in more than 40oC) and their strong frequency dispersion do not agree with the behavior expected for the systems with a weak interaction between ferroelectric particles and a polymeric matrix. In contrast, we reveal the relaxor-like behavior of the composite dielectric response. To explain the observed results, we propose the analytical model, which considers the strong dipole-dipole cross-interaction of the BaTiO 3 particles in the dense nanocomposite. The analytical model is corroborated by the structural studies of the BaTiO 3 nanosized and submicron particles by X-ray phase analysis and static 137Ba NMR spectra, as well as by the finite element modelling of the composite polar properties, which confirms the strong cross-interactions between the dipole moments of single-domain nanoparticles and/or between the domain walls of different submicron polydomain particles. The obtained results may be useful for development of cheap and flexible lead-free dense ferroelectric nanocomposites with relaxor-like behavior of the dielectric response, which are promising for non-volatile memory and energy-saving elements, modulators, electrical converters and piezoresistive elements. [ABSTRACT FROM AUTHOR]

Published

2024

14. Research on the Rheological Properties and Diffusion Law of Coal-Based Solid Waste Geopolymer Grouting Material.

Author

Wang, Xinyi, Zhou, Mei, Bai, Jinting, Liao, Yue, Li, Dong, and Zhang, Boqun

Abstract

The rheological properties and diffusion law of coal-based solid waste geopolymer grouting material (CGGM) slurry were investigated by rheological property test and diffusion theory model derivation. Based on the power-law fluid constitutive equation, a theoretical model of slurry diffusion in an inclined fissure aquifer was established, and the effect of slurry grouting time on the slurry diffusion distance under different fissure widths, fissure inclination angles, and grouting pressures were analyzed. The results show that when coal gangue:cement:fly ash = 5:4:1, sodium silicate modulus 2.0, sodium silicate content is 10%, CGGM slurry's bleeding rate of 1%, the liquidity of 227 mm, the initial and final setting time is 412 min and 825 min, respectively, to meet the requirements of the grouting project. CGGM slurry is a typical viscosity time-varying power-law type fluid, and the slurry diffusion distance is positively correlated with the grouting pressure, fissure width, fissure inclination angle, and negatively correlated with the rheological index. The established theoretical model can provide a reference for the parameter design of CGGM slurry in grouting construction. [ABSTRACT FROM AUTHOR]

Published

2024

15. Effect of Composition on Processing and Mechanical Properties of TPE for Injection Molding Automotive Skin.

Author

Liu, Shuwen, Wang, Dong, Guo, Guomin, Zhang, Jihai, Qiu, Jun, and Zhang, Aimin

Subjects

*THERMODYNAMICS, *ELECTRIC vehicles, *AUTOMOTIVE materials, *THERMOPLASTIC elastomers, *RHEOLOGY, *POLYVINYL chloride

Abstract

With the development of new energy vehicles, there is a growing demand for automotive interior materials that meet higher standards. In this case, thermoplastic elastomer (TPE), being a completely recyclable environment‐friendly polymer material, possesses advantages such as plasticizers and solvents free, excellent mechanical properties, less volatile organic compounds (VOC) release and low processing cost compared with polyvinyl chloride (PVC), polyurethane (PU), and thermoplastic polyolefin (TPO) skins, become a desirable choice for automotive injection molding automotive skin. Hence, this work investigates the influence of hydrogenated styrene‐butadiene‐styrene block copolymer (SEBS) molecular weight, chemical structure, and polypropylene (PP) doping amount on thermodynamic, crystallinity, rheological, and mechanical properties of TPE, which provides a scientific basis for guiding the material selection of TPE injection molding skin. [ABSTRACT FROM AUTHOR]

Published

2024

16. OSA 改性木薯淀粉基 Pickering 乳液制备 及特性研究.

Author

芒 莱 and 范方宇

Abstract

Copyright of Science & Technology of Food Industry is the property of Science & Technology of Food Industry 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

17. A comprehensive study on the rheological properties of desulfurized rubberized asphalt and establishment of micro-scale mechanical models.

Author

Chang, Yingjie

Subjects

*RUBBER powders, *MECHANICAL behavior of materials, *STRAINS & stresses (Mechanics), *RHEOLOGY, *FATIGUE cracks, *ASPHALT

Abstract

Recently, understanding the complex relationship between the mechanical properties and material characteristics of desulfurized rubber asphalt has received significant research attention. In this study, the rheological properties of rubber asphalt prepared by three kinds of desulfurized rubber powder are analyzed, and the mechanical response of rubber asphalt mixture is predicted using various mathematical models. Firstly, the rheological properties of desulfurized rubber asphalt are assessed through multiple stress creep recovery test, linear amplitude scanning test, and low-temperature creep test. The results indicate that the high-temperature performance index of desulfurized rubber asphalt is highly sensitive to the degree of desulfurization. As the degree of desulfurization of the rubber powder increases, the fatigue damage rate of asphalt gradually decreases, leading to an increase in the fatigue life. Notably, the difference between the m-critical temperature and stiffness-critical temperature (ΔTc) for only ML40MA does not exceed the threshold value, indicating that it has the best low-temperature cracking resistance. Additionally, the swelling capacity of desulfurized rubber powder in asphalt is better than that of ordinary rubber powder. Finally, the comprehensive performance of desulfurized rubber asphalt is characterized based on the gray correlation method. The gray correlation coefficient of ML60MA is 0.78, which is higher than that of ML40MA and ML80MA, indicating its best overall performance. [ABSTRACT FROM AUTHOR]

Published

2024

18. Effect of Varietal Differences and Nixtamalization Conditions on the Textural, Rheological, and Nutritional Properties of Corn (Zea mays)–Based Masa Flour: Kassaï and Atp-Y Corn Varieties.

Author

Dongmo, Hygride, Teboukeu Boungo, Gires, Kohole Foffe, Hermann Arantes, Nanga Ndjang, Marie Madeleine, Fotso Saah, Bruno, Naïm, Saturnin, Tamokou, Jean de Dieu, Mathilde Julie, Klang, and Punia Bangar, Sneh

Subjects

RHEOLOGY, RESPONSE surfaces (Statistics), TORTILLAS, GELATION, FOOD industry

Abstract

Nixtamalization is a process used in the production of tortillas. This process offers many advantages, such as improving the rheological, nutritional, and textural properties of the masa. This process is carried out under different steps which affect the quality of the final product such as the cooking and soaking conditions and the quantity of ash. In addition, the fragility of the masa makes the tortillas brittle. The present work was initiated with the aim of determining the nixtamalization conditions that would improve the textural, rheological, and nutritional properties of masa. The response surface methodology, using the central composite design was applied to three factors including the ash content and cooking and soaking times, and the responses evaluated were the adhesiveness, cohesion, final viscosity, and gelatinization temperature of masa obtained from two varieties of maize (Atp-Y and Kassaï). The optimums masa flours obtained were characterized using standard methods. Results showed that, the masa made from Kassaï variety needed a cooking time of 51.21 min and soaking time of 16.10 h in the presence of 0.80 g of ash. For the Atp-Y variety, the conditions included a cooking time of 49.17 min and a soaking time of 23.4 h in the presence of 0.24 g of ash. The responses obtained showed an adhesiveness of 0.10 kg/f and 0.05 kg/f, cohesion of 1.08 kg/f and 1.23 kg/f, final viscosity of 1504.80 cP and 1328.30 cP, gelatinization temperature 73.50 °C and 71.50 °C, and finally retrogradation 435.50 cP and 316 cP, respectively, for Kassaï and Atp-Y. Chemical characterization of the optimum masa showed that the white masa had a high protein content (10.50%), carbohydrates (71.70%), and fiber (2%) while the yellow masa presented the highest lipid content (5.47%). These finding demonstrated that Kassaï (white) maize‐masa flour obtained in optimal conditions can be recommended for the production of good quality tortillas because tortillas made with this masa are less crumbly and more elastic. [ABSTRACT FROM AUTHOR]

Published

2024

19. Effects of Essential Oils and Ultrasonic Treatments on Properties of Edible Coatings and Their Application on Citrus Fruits.

Author

Kumar, Nishant, Upadhyay, Ashutosh, and Shukla, Shruti

Abstract

In present study, the effects of orange peel essential oil and ultrasonic treatment on properties of corn starch based edible coating and films including their effects on the shelf life of citrus (Kinnow) fruits are investigated. The ultrasonic approach and essential oil significantly improves the quality characteristics of edible coating formulations, stability, and rheological behaviour of coating materials by reducing the particle size, including antimicrobial activity. The particle size of the coating materials reduces from 2495 nm (control) to 298.8 nm by ultrasonication treatment with improved stability (−39.251 mV) as well as antimicrobial activity. The tensile strength (720 N) and solubility (32.40%) of the CSEOU edible film are also improved as compared to CSEO and CS edible films. The coating formulation enriched with essential oil and ultrasonic treatment (CSEOU) improves the shelf‐life of Kinnow by retarding weight loss (PLW) and microbial load, as well as maintaining higher acidity (TA), total soluble solids (TSS), and higher antioxidant activity. CSEOU treated samples indicate lowest weight loss (24.57%), pH (3.89) with higher TA (3.999%), firmness (494.229 N), phenolic (26.17 mg 100 g−1), flavonoid (34.11 mg 100 g−1), antioxidant (49.04%), and antimicrobial activity against A. niger, E. coli and S. aureus as compared to other samples. [ABSTRACT FROM AUTHOR]

Published

2024

20. Preharvest Gibberellic Acid Treatment Increases Both Modulus of Elasticity and Resistance in Sweet Cherry Fruit (cv. 'Bing' and 'Lapins') at Harvest and Postharvest During Storage at 0 °C.

Author

Carrión-Antolí, Alberto, Zoffoli, Juan Pablo, Serrano, María, Valero, Daniel, and Naranjo, Paulina

Abstract

Fruit firmness in sweet cherries (Prunus avium L.) is a critical quality parameter highly valued by consumers as it is associated with fruit freshness. In general, firm fruit also cope better with storage and handling. Gibberellic acid (GA) is commonly used by sweet cherry producers to increase firmness, soluble solids content and fruit size. This study evaluated the effects of GA on the rheological properties of sweet cherry fruit at harvest and postharvest storage. Specifically, GA's influence on susceptibility to mechanical damage during handling was evaluated. The following GA treatments were applied to two sweet cherry cultivars 'Bing' and 'Lapins': T0, control, T30—GA at 15 ppm applied at pit-hardening and straw-colour stages; T45—GA at 25 ppm at pit-hardening and GA at 20 ppm at straw-colour; and T60—GA at 30 ppm applied at pit-hardening and straw-colour. The results indicate that GA delayed harvest by two to four days in both cultivars, with 'Lapins' also showing a significant increase in fruit size. Regardless of spray concentration, GA increased the modulus of elasticity and fruit resistance evaluated as stress at the maximum point at harvest. These effects persisted after 35 days of storage at 0 °C and an additional three days of shelf-life at 15 °C. While the strain or deformation capacity of the fruit at bioyield at harvest was constant across treatments, it was, however, lower in the GA-treated fruit than in the controls during storage at 0 °C under the high-humidity conditions of modified atmosphere packaging. The less mature fruit harvested at colour 3.0 (red/mahogany) were stiffer (reduced deformation) and more sensitive to induced mechanical injury than the fruit harvested later at colour 3.5 (mahogany). The GA treatments increased fruit resistance to damage without increasing tissue deformability. Other questions associated with stiffer tissues and lower deformability during storage at 0 °C under high humidity should be further studied, specifically cultivars that are naturally high in box-cracking sensitivity during storage. [ABSTRACT FROM AUTHOR]

Published

2024

21. Emulsifiers: Their Influence on the Rheological and Texture Properties in an Industrial Chocolate.

Author

Pombal, Maria, Marcet, Ismael, Rendueles, Manuel, and Diaz, Mario

Subjects

*RHEOLOGY, *YIELD stress, *VISCOSITY, *RAW materials, *THIXOTROPY

Abstract

The complexity of the chocolate matrix leads to it having characteristic rheological properties that may pose difficulties for its industrial manufacture. Many factors influence the flow behaviour of chocolates, such as raw materials, the amount of fat, the moisture content, particle-size distribution, the concentration of emulsifiers, or manufacturing conditions, among others. This study focusses on the rheological properties of an industrially manufactured chocolate with a 48% cocoa content, and the effect caused by the addition of two emulsifiers (soya lecithin and polyglycerol polyricinoleate (PGPR)) on the rheological properties. In the case of lecithin, a clear effect has been observed on the plastic viscosity and the yield stress. Plastic viscosity decreases until a concentration of 0.6% lecithin is reached, and thereafter remains relatively constant, while yield stress increases over the studied range. This effect is not observed when PGPR is used as the emulsifying agent. In this case, a small concentration of PGPR decreases the yield stress. Thixotropy was determined using the Casson model, and its behaviour was found to be similar to that of plastic viscosity with respect to changes in the PGPR and lecithin concentrations. Textural determinations were also carried out, relating the rheology characteristics to the texturometry. [ABSTRACT FROM AUTHOR]

Published

2024

22. Impact of Buriti Oil from Mauritia flexuosa Palm Tree on the Rheological, Thermal, and Mechanical Properties of Linear Low-Density Polyethylene for Improved Sustainability.

Author

Leite-Barbosa, Odilon, Oliveira, Marcelo Ferreira Leão de, Braga, Fernanda Cristina Fernandes, Monteiro, Sergio Neves, Oliveira, Marcia Gomes de, and Veiga-Junior, Valdir Florêncio

Subjects

*VEGETABLE oils, *DIFFERENTIAL scanning calorimetry, *RHEOLOGY, *CONTACT angle, *SCANNING electron microscopy, *LOW density polyethylene

Abstract

Recent advancements highlight the utilization of vegetable oils as additives in polymeric materials, particularly for replacing conventional plasticizers. Buriti oil (BO), extracted from the Amazon's Mauritia flexuosa palm tree fruit, boasts an impressive profile of vitamins, minerals, proteins, carotenoids, and tocopherol. This study investigates the impact of incorporating buriti oil as a plasticizer in linear low-density polyethylene (LLDPE) matrices. The aim of this research was to evaluate how buriti oil, a bioactive compound, influences the thermal and rheological properties of LLDPE. Buriti oil/LLDPE compositions were prepared via melt intercalation techniques, and the resulting materials were characterized through thermogravimetric analysis (TGA), differential scanning calorimetry (DSC), Fourier-transform infrared (FTIR) spectroscopy, scanning electron microscopy (SEM), mechanical property testing, and contact angle measurement. The addition of buriti oil was found to act as a processing aid and plasticizer, enhancing the fluidity of LLDPE polymer chains. TGA revealed distinct thermal stabilities for buriti oil/LLDPE under different degradation conditions. Notably, buriti oil exhibited an initial weight loss temperature of 402 °C, whereas that of LLDPE was 466.4 °C. This indicated a minor reduction in the thermal stability of buriti oil/LLDPE compositions. The thermal stability, as observed through DSC, displayed a nuanced response to the oil's incorporation, suggesting a complex interaction between the oil and polymer matrix. Detailed mechanical testing indicated a marked increase in tensile strength and elongation at break, especially at optimal concentrations of buriti oil. SEM analysis showcased a more uniform and less brittle microstructure, correlating with the enhanced mechanical properties. Contact angle measurements revealed a notable shift in surface hydrophobicity, indicating a change in the surface chemistry. This study demonstrates that buriti oil can positively influence the processability and thermal properties of LLDPE, thus expanding its potential applications as an effective plasticizer. [ABSTRACT FROM AUTHOR]

Published

2024

23. Evaluation of dimensional stability, setting time, tensile strength, and rheological properties of kaolin clay incorporated alginate impression material.

Author

Anwar, Sumbal, Liaqat, Saad, Ullah, Riaz, Iqbal, Zafar, Rahman, Fozia, Ali, Essam A., Nishan, Umar, Feroz, Sandleen, and Muhammad, Nawshad

Subjects

*MECHANICAL behavior of materials, *RHEOLOGY, *YOUNG'S modulus, *TENSILE strength, *KAOLIN, *EXPERIMENTAL groups

Abstract

This study aims to determine and compare the dimensional stability, setting time, tensile strength, and rheological properties of kaolin clay powder-modified and unmodified alginate impression material. Commercially available alginate-based impression material was considered as a control (C) while experimental groups E-1, E-2, and E-3 were fabricated by adding 2%, 4%, and 8% of kaolin clay powder in the control, respectively. Analytical techniques were used for the characterization of the samples. A tensile strength, rheological property, dimensional stability, and setting time were recorded for control and experimental groups. FTIR analysis confirmed the presence of kaolin clay powder in all experimental groups. SEM showed a round solid structure and irregular shape particle appearance in all experimental groups as well as a control group. The dimensional stability was improved by the addition of kaolin clay powder to the alginate impression material. The percentage dimensional change at 5 min, 6, and 12 h was increased for E3 adding (8% kaolin clay powder) and decreased for the control group. The mean value of tensile strength was highest for E3 followed by E2, E1, and least in control groups. Higher Young's Modulus and lower deformation values were measured for E3. The mean value of setting time was highest for E3 and the least was in the control group. The results for both setting time and tensile strength were very highly statistically significant (p < 0.001). The mean values of viscoelasticity, flow, and drip test were increased statistically by adding various concentrations of kaolin clay powder to the alginate impression material. [ABSTRACT FROM AUTHOR]

Published

2024

24. Improvement in the thermal, mechanical and rheological properties of polyamide-11 (PA11) nanobiocomposite films as a result of the influence of the composition and type of nanofiller.

Author

Khiati, Zoulikha, Mezrai, Abdelmoumin, and Mrah, Lahouari

Abstract

The structures and properties of different polyamide-11 (PA11) and organically modified Algerian clay nanobiocomposite systems are investigated in this work. The objective of this investigation is to evaluate the potential of modified Algerian clay as a nanofiller by studying of the properties of PA11/Mag-CTA nanobiocomposites with different levels of prepared fillers. Considering the different techniques used, the results show the full potential of the modified Algerian clay, with improvements in both thermal and mechanical properties after incorporation of the nanofiller (Mag-CTA). The intercalated and exfoliated morphology of the developed PA11 nanobiocomposites is demonstrated by the results of the different techniques used. The results indicate that the modified clay has a more significant impact on the thermal, mechanical, and rheological properties of the material than virgin polyamide-11 (PA11) at an equivalent rate of incorporation and low concentration. The optimal loading rate is estimated to be between 3 % and 5 % based on clay mass (Mag-CTA). [ABSTRACT FROM AUTHOR]

Published

2024

25. Ultraflexible liposomes for transdermal delivery of atorvastatin calcium: Rheological and ex vivo evaluation.

Author

Akl, Mohamed A., Ryad, Sherif, Ibrahime, Mohamed F., and Kassem, Alaa A.

Subjects

*TRANSDERMAL medication, *MEDICAL personnel, *ORAL drug administration, *DRUG delivery systems, *RHEOLOGY

Abstract

Our research aims to explore the possibility of incorporating atorvastatin calcium (ATC) in ultraflexible nanovesicles (UFNVs) to avoid the hepatic first metabolism and enhance its effectiveness as a potential alternative to oral treatment. ATC nanovesicles were developed utilizing the rotary evaporation‐sonication method and assessed in vitro concerning their vesicle diameter, zeta potential (ZP), entrapment efficiency (EE), as well as in vitro release studies. The chosen formulation of ATC‐UFNVs was integrated into a different gel base that was evaluated for content uniformity, pH, spreading ability, viscosity, and rheological behavior. The skin permeation of the prepared nanovesicles was assessed using an ex vivo permeation and confocal laser microscopy images (CLSM). In vitro evaluation of the ATC‐loaded UFNVs showed that the mean diameter of the nanovesicles ranging between 60.84 ± 0.53 nm and 91.68 ± 2.11 nm, the Zeta potential values ranged from of –15.8 ± 0.31 to –25.1 ± 0.81 mV, the EE% were between 84.33 ± 1.94 and 86.53 ± 2.02%, and the ATC release from the formulations was 75.25–90.89%. All release patterns were analyzed kinetically following Higuchi's diffusion approach. Carbapol 934 gel bases containing ATC‐UF exhibited non‐Newtonian pseudo‐plastic flow with thixotropy equal to 2.013 cm2. Ex vivo data showed that ATC‐UFNVs had better penetration compared to free AC. CLSM revealed that the UF‐nanovesicle exhibited stronger and deeper fluorescence signals up to 90 µm depth of permeation in skin versus the rhodamine B‐free solution (50 µm). The transdermal ability of the ATC‐UFNVs gel formulation has been conclusively demonstrated by our research. Practical Applications: The successful development of atorvastatin calcium‐loaded ultraflexible nanovesicles (ATC‐UFNVs) in this study offers promising applications for researchers and healthcare professionals. The ability of these nanovesicles to bypass hepatic first‐pass metabolism and enhance drug delivery to the skin presents a potential alternative to oral administration, which can be associated with gastrointestinal side effects and variable absorption. The findings of this research can be applied in the development of novel transdermal drug delivery systems for the treatment of various cardiovascular conditions. ATC‐UFNVs may be incorporated into topical formulations for the management of hypercholesterolemia, reducing the need for systemic medication. Additionally, the insights gained from this study could be utilized to explore the feasibility of using nanovesicles for the delivery of other lipophilic drugs, expanding their potential therapeutic applications. [ABSTRACT FROM AUTHOR]

Published

2024

26. Improvement of powder properties of milk protein isolate by fluidised bed agglomeration with guar gum binder.

Author

Lee, Wonjae, Bak, Juneha, and Yoo, Byoungseung

Subjects

*GUAR gum, *MILK proteins, *RHEOLOGY, *DRIED milk, *POWDERS

Abstract

A goal of this study was to investigate the influence of fluidised bed agglomeration process with guar gum (GG) binder (0–0.3%) on the physical and rheological properties of agglomerated milk protein isolate (MPI). Larger and more porous particles were formed by the agglomeration process, resulting in an improvement in powder flowability, wettability and solubility. The agglomerate with 0.1% GG binder exhibited higher viscoelastic properties than other agglomerates, with viscoelastic moduli values decreasing as the binder concentration increased (0.1–0.3%). The findings demonstrate that the agglomeration process with GG improved the powder characteristics of MPI and influenced its rheological properties. [ABSTRACT FROM AUTHOR]

Published

2024

27. Effects of various acids on physical stability, rheological characteristics and curcumin encapsulation of whey protein isolate Pickering emulsion gels.

Author

Guo, Shiyi, Mu, Zhishen, Jiang, Qiuwan, Zhang, Wenjuan, Jiang, Zhanmei, and Zhang, Ligang

Subjects

*WHEY proteins, *RHEOLOGY, *FOOD industry, *LOCAL delivery services, *EMULSIONS

Abstract

Acid treatment can alter the functional properties of whey protein isolate (WPI), but the effect of different acids on properties of WPI‐stabilised Pickering emulsion gel (PE) is unknown. Compared with WPI‐PE, droplet size of the acid‐treated WPI‐PE decreased but its zeta potential, apparent viscosity, binding water capacity and curcumin encapsulation were enhanced. Due to the formation of the tightest gel structure of malic acid‐Pickering emulsion gel, it showed the highest viscoelastic modulus, bound water content and gel stability. This work would introduce a novel method for the development of PEs with good gelatinisation and curcumin delivery system for food processing. [ABSTRACT FROM AUTHOR]

Published

2024

28. Effect of Thermal and Non-thermal Plasma Treatment on Particle Size Distribution, Protein Secondary Structure, Fuzzy Logic Sensory Evaluation, Rheological, and Selected Quality Attributes of Pineapple Juice: A Comparative Analysis.

Author

Pipliya, Sunil, Kumar, Sitesh, and Srivastav, Prem Prakash

Subjects

*NON-thermal plasmas, *PINEAPPLE juice, *PARTICLE size distribution, *ENZYME inactivation, *PROTEIN structure, *THERMAL plasmas

Abstract

This study presents the comparative analysis of untreated, optimized non-thermal plasma (NTP)–treated (38 kV/631 s), extreme NTP–treated (45 kV/900 s), and thermally treated (95 ℃/12 min) pineapple juice (PJ) on enzyme activity, microbial count, protein structure, particle size, bioactive substances and, sensory, rheological, and biochemical attributes. The PJ treated with optimized NTP demonstrated merits over extreme NTP–treated and thermally treated in terms of the retention of bromelain, bioactive components, and biochemical attributes. Moreover, the fuzzy logic evaluation showed that optimized NTP–treated juice had superior sensory characteristics than extremely NTP– and thermally treated juice. The NTP approach, like thermal treatment (95 ℃/12 min), extends shelf life by assuring microbiological safety (<1 log10 cfu/mL) and enzyme inactivation (>90%). However, the thermal treatment resulted in loss of bioactive, sensory, and biochemical attributes. Particle size distribution indicates that NTP significantly (p < 0.05) reduced the sauter mean and volume mean diameter from 1617 to 894 nm and 1688 to 917 nm, respectively, which stabilized juice after treatment. NTP treatment substantially reduced the consistency from 1.22 to 0.31 mPa.sn and showed a pseudo-plastic behavior of juice. These results collectively imply that NTP has a tremendous ability to maintain bioactive compounds, and sensory and physicochemical attributes, as well as extend the shelf life of PJ. [ABSTRACT FROM AUTHOR]

Published

2024

29. Study of the Aging Behavior of Asphalt Mastic: Impact of the Powder-to-Binder Ratio and the Aging Method.

Author

Li, Huixia, Liang, Yan, Chen, Ruohan, Zhuang, Jinping, He, Zhengtao, and Xie, Xiang-bing

Subjects

*MODULUS of rigidity, *RHEOLOGY, *PREDICTION models, *DUCTILITY, *POWDERS, *ASPHALT, *MORTAR

Abstract

This research conducted a comprehensive assessment of how aging processes and the powder to binder ratio (P/B ratio) influence asphalt mortar's performance. Analysis demonstrated that all tested performance metrics significantly differed (P<0.05), signifying a notable effect of the aging process, particularly long-term thermal oxidation aging, on key properties such as ductility and the complex shear modulus (G*). Adjusting the P/B ratio enables precise control over the rate of aging and the asphalt mixture's functional characteristics. The optimal P/B ratio, found to be between 0.8 and 1.0, effectively balances aging properties with mechanical strength. Moreover, a detailed analysis of the four main asphalt components shed light on aging's effects on both the composition and functionality of asphalt, highlighting the critical role of component dynamics in designing and assessing asphalt mixtures. Additionally, the study introduces a predictive model that uses linear regression to compute five parameters (β0 to β4), forming equations for various performance metrics. This facilitates optimized selection and combination of asphalt components at the design stage. [ABSTRACT FROM AUTHOR]

Published

2024

30. Rheological and Physical Properties of Aged Bitumen Rejuvenated by Biobitumen.

Author

Hassan, Hassan N., Abd, Duraid M., and Ahmed, Taher M.

Subjects

*EDIBLE fats & oils, *RHEOLOGY, *BITUMEN, *SULFURIC acid, *DYNAMIC testing

Abstract

Scientific and technical developments toward improving bio-oil are under investigation, with an emphasis on research into upgrading bio-oil bitumen. The current study presents a new development of eco-friendly bio-oil bitumen produced using some local materials as well as studying its physical and rheological properties. Two bitumen sources with penetration grade of 40/50 were used, Dora and Nasiriyah, which were locally obtained from Dora and Nasiriyah refineries in Iraq. Biobitumen was prepared by vacuum distillation after esterification of waste cooking oil, which was freely collected from local households and cafeterias. Methanol, sulfuric acid (as a catalyst agent), and zeolite were used in the biobitumen preparation process. Physical and rheological properties were tested in evaluating the performance. The physical tests included viscosity, softening point, and penetration, and the rheological properties involved sweep frequency and creep tests using a dynamic shear rheometer (DSR). Three percentages (10%, 20%, and 30%) of biobitumen were blended with aged petroleum bitumen, which was obtained from excessive aging of the virgin bitumen by thin-film oven test (TFOT). It was found that a ratio of 1∶5 of biobitumen and aged petroleum bitumen exhibited the best performance. Results also highlighted that the new modified bitumen with biobitumen showed superior performance compared with that of traditional bitumen, taking into consideration the influence of biobitumen percentage and level of the age of the virgin bitumen. The current development and outcomes of the study can be considered as promising and encouraging for further investigations into sustainable and environmentally friendly production. [ABSTRACT FROM AUTHOR]

Published

2024

31. Evaluation of the Rheological Properties of Asphalt Binder Modified with Polyvinylpyrrolidone Grafted onto Water-Soluble Graphene and Analysis of the Modification Mechanism.

Author

Xu, Zhenghong, Zhang, Weikun, Xiong, Zijia, Gong, Minghui, Si, Wei, and Hong, Jinxiang

Subjects

*FOURIER transform infrared spectroscopy techniques, *ASPHALT pavements, *STRAINS & stresses (Mechanics), *RHEOLOGY, *SCANNING electron microscopy, *ASPHALT, *ASPHALT modifiers

Abstract

Graphene and its derivatives have garnered significant attention as novel nanomodifiers in the asphalt industry. Despite its vast potential, poor compatibility and dispersion between graphene and asphalt have been persistent challenges for researchers. To prepare well-dispersed graphene materials, polyvinylpyrrolidone (PVP) was grafted onto water-soluble graphene (WG), resulting in PVP-WG composites. This PVP-WG composite was introduced into matrix asphalt as a modifier to improve the compatibility and dispersion of graphene with asphalt. Various advanced techniques such as Fourier transform infrared spectroscopy, laser particle size analyzer, scanning electron microscopy, and X-ray diffraction confirmed the successful attachment of PVP to the surface of water-soluble graphene, thereby increasing the spacing between WG and promoting the intercalation of asphalt molecules. The loose structure of PVP facilitated the effective binding between WG and asphalt molecules. The multiple stress creep recovery and dynamic shear rheometer tests demonstrated that PVP-WG was effective in enhancing the elastic recovery performance, high temperature resistance to deformation, and viscoelastic properties of the asphalt binder. In addition, the results of the bending beam rheometer test showed that PVP-WG slightly reduces the low-temperature performance of asphalt, but PVP significantly improves the low-temperature cracking resistance of WG-modified asphalt. This study provides valuable insights into the potential application of graphene in asphalt pavement materials. [ABSTRACT FROM AUTHOR]

Published

2024

32. Rheological behaviors of the multi-wall carbon nanotubes/polyethylene composites prepared by a master batch method.

Author

Zhang, Li-Ming, He, Fu-An, and Xiao, Jian-Wu

Subjects

*RHEOLOGY, *CARBON nanotubes, *YIELD stress, *TEMPERATURE effect, *POLYETHYLENE

Abstract

In this work, the rheological properties of four multi-wall carbon nanotubes (MWCNTs)/polyethylene (PE) composites containing 1 wt.% (mPEC1), 3 wt.% (mPEC3), 5 wt.% (mPEC5), and 10 wt.% (mPEC10) MWCNTs prepared by the masterbatch method were investigated and compared with those of the pure PE. The rheological investigation includes strain sweeping, frequency sweeping, stress relaxation behavior, yield stress, characteristic relaxation time, temperature effect on linear viscoelastic behavior, and gel behavior. It is mainly found that (1) the MWCNTs-MWCNTs interaction resulting in MWCNTs network structure in the PE matrix and the MWCNTs-PE interfacial interaction increase the storage and loss moduli of the MWCNTs/PE composite in comparison with those of pure PE; (2) the time-temperature equivalence principle is applicable only for pure PE and mPEC1; (3) for gel behavior of MWCNTs/PE composite at 160–180 °C, the φ g value decreases with the increase of temperature and the highest S g value is obtained at 170 °C. [ABSTRACT FROM AUTHOR]

Published

2024

33. Effects of Moisture Content and Heat Treatment on the Viscoelasticity and Gelation of Polyacrylonitrile/Dimethylsulfoxide Solutions.

Author

Yang, Jae-Yeon, Kuk, Yun-Su, Kim, Byoung-Suhk, and Seo, Min-Kang

Abstract

Polyacrylonitrile (PAN) gels create significant obstacles in industrial fiber spinning by forming insoluble networks that compromise solution stability and uniformity. This study investigates the rheological properties of PAN/dimethyl sulfoxide (DMSO) solutions, examining how aging time, moisture content, and polymer concentration affect gelation behavior. Dynamic rheological analysis revealed that both physical and chemical crosslinks play crucial roles in gel formation, with gelation accelerating markedly when moisture content exceeds 3% and aging progresses. Under heat treatment at 80 °C, samples with increased moisture content demonstrated rapid transitions to solid-like states, indicating a critical moisture threshold for enhanced gelation kinetics. Additionally, reductions in polymer concentration disrupted physical crosslink density, thereby mitigating gel formation. These results underscore the importance of precisely controlling moisture and concentration parameters in PAN solutions to stabilize solution properties and minimize gel formation, thus enhancing process efficiency and quality in PAN-based carbon fiber production. [ABSTRACT FROM AUTHOR]

Published

2024

34. 缓释型石膏微粒豆腐凝固剂制备工艺研究.

Author

马勇, 柏亚萱, 高子鑫, 杨柳莺, 杨金玉, 陈志豪, and 盘赛昆

Abstract

Copyright of China Condiment is the property of China Condiment 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

35. 明胶对凝胶油基植脂奶油搅打性能的影响机制.

Author

刘莹婕, 冯鑫, 朱瀚昆, 余永, 周鸿媛, 马良, and 张宇昊

Subjects

WHIPPED cream, YIELD stress, INTERFACIAL tension, RHEOLOGY, VISCOSITY

Abstract

Copyright of Food & Fermentation Industries is the property of Food & Fermentation Industries 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

36. Covalent Pectin/Arabinoxylan Hydrogels: Rheological and Microstructural Characterization.

Author

Lara-Espinoza, Claudia, Rascón-Chu, Agustín, Micard, Valérie, Antoine-Assor, Carole, Carvajal-Millan, Elizabeth, Troncoso-Rojas, Rosalba, Ohlmaier-Delgadillo, Federico, and Brown-Bojorquez, Francisco

Subjects

*RHEOLOGY, *FERULIC acid, *OXIDATIVE coupling, *SUGAR beets, *CORN

Abstract

This research aimed to evaluate the gelation process of ferulated pectin (FP) and ferulated arabinoxylan (AXF) in a new mixed hydrogel and determine its microstructural characteristics. FP from sugar beet (Beta vulgaris) and arabinoxylan from maize (Zea mays) bran were gelled via oxidative coupling using laccase as a crosslinking agent. The dynamic oscillatory rheology of the mixed hydrogel revealed a maximum storage modulus of 768 Pa after 60 min. The scanning electron microscopy images showed that mixed hydrogels possess a microstructure of imperfect honeycomb. The ferulic acid content of the mixed hydrogel was 3.73 mg/g, and ferulic acid dimer 8-5′ was the most abundant. The presence of a trimer was also detected. This study reports the distribution and concentration of ferulic acid dimers, and the rheological and microstructural properties of a mixed hydrogel based on FP and AXF, which has promising features as a new covalent biopolymeric material. [ABSTRACT FROM AUTHOR]

Published

2024

37. Mechanistic Study on the Optimization of Asphalt-Based Material Properties by Physicochemical Interaction and Synergistic Modification of Molecular Structure.

Author

Cao, Jiashuo and Wang, Lifeng

Subjects

*ATTENUATED total reflectance, *POLYESTER fibers, *ASPHALT testing, *REFLECTANCE spectroscopy, *MODULUS of rigidity, *ASPHALT, *LIGNIN structure, *LIGNANS

Abstract

In order to investigate the relationship between the molecular structure of fibers and the differences in physicochemical interactions between fibers and asphalt on the performance of fiber-modified asphalt, this paper chose two types of fibers with different chemical structures: straw fiber and polyester fiber. First, the differences in molecular interactions between the two fibers and asphalt were explored using molecular dynamics, then the differences in the adsorption capacity of the two fibers on asphalt components were tested by attenuated total reflection infrared spectroscopy experiments, and finally, the differences in the rheological properties of the two fiber-modified asphalts were tested by dynamic shear rheology and low-temperature creep experiments. The molecular dynamics simulation findings reveal that polyester fibers may intersperse into asphalt molecules and interact with them via structures such as aromatic rings, whereas straw fibers are merely adsorbed on the asphalt's surface. Straw fibers and asphalt exhibit hydrogen bonding, whereas polyester fibers and asphalt display van der Waals interactions. The results of attenuated total reflectance infrared spectroscopy indicated that polyester fiber absorbed asphalt components better than straw fiber. The rheological tests revealed that the polyester fiber had the highest complex shear modulus in the temperature range of 46–82 °C, and at 64 °C, the phase angle was 4.289° lower than that of the straw fiber-treated bitumen. Polyester fiber-modified asphalt had a 32.48%, 15.72%, and 6.09% lower creep modulus than straw fiber-modified asphalt at three low-temperature conditions: −6 °C, −12 °C, and −18 °C. It is clear that fibers with aromatic rings as a chemical structure outperform lignin-based fibers in terms of improving asphalt characteristics. The research findings can serve as a theoretical foundation for the selection of fibers to produce fiber-modified asphalt. [ABSTRACT FROM AUTHOR]

Published

2024

38. The effect of TiO2 on the crystallization and fiber spinnability of sodium-calcium-magnesium phosphate glasses.

Author

Li, Sheng and Liu, Shiquan

Subjects

*GLASS fibers, *TITANIUM dioxide, *LIQUIDUS temperature, *TRANSITION temperature, *MOLECULAR volume, *PHOSPHATE glass

Abstract

Titanium dioxide-enriched phosphate glasses are esteemed for their applicability in the biomaterial area, yet the investigation into the influence of TiO 2 on the crystallization dynamics of glass melts and the spinnability of sodium-calcium-magnesium phosphate glasses remains unclear. To elucidate these effects, sodium-calcium-magnesium phosphate glasses with 0, 5, and 10 mol% of TiO 2 have been prepared using the melt-quenching method, and glass fibers were drawn from the correspondent glass melts. FTIR and Raman spectroscopy have disclosed that the introduction of TiO 2 induces a depolymerization in phosphate network, causing a transition from Q2 species to Q1 units, and reduction in both the theoretical network connectivity (NC theor) and the average chain length (n theor). Meanwhile, the interposition of TiO 2 also gives rise to the replacement of P–O–P linkages with P–O–Ti bonds, along with the formation of [TiO 5 ] groups. This structural transformation resulted in the increase in molar volume and the coefficient of thermal expansion (CTE), concurrently lowering the glass transition and softening points. Evidently, the TiO 2 -free glass exhibited crystallization across a temperature range spanning from its transition to the liquidus temperature. However, the introduction of TiO 2 and the subsequent formation of P–O–Ti bonds effectively inhibited crystallization, which is favorable for drawing glass fibers. Analyses of viscosity-temperature relationships using various rheological models suggested that TiO 2 raises fragility for all glasses, suggesting a more "open" structure in the glass melts, which can be supported by the increment in free volume. The m-D diagram failed to describe the enhancement in spinnability imparted from TiO 2. While, the quantitative fiber spinnability index (K fib) increases with higher TiO 2 content, as a successful indicative of an improved ability to form fibers. [ABSTRACT FROM AUTHOR]

Published

2024

39. Flaxseed mucilage—a green additive for the enhancement of water-based mud system characteristics.

Author

Kanwal, Faiza, Lalji, Shaine Mohammadali, Ali, Syed Imran, Burney, Muneeb, Tariq, Muhammad Ovais, Ahmed, Leena Hasan, Khan, Umer Ahmed, Sheikh, Aashan, and Salman, Muhammad

Subjects

DRILLING fluids, RHEOLOGY, DRILLING muds, GEOLOGICAL formations, CONTACT angle

Abstract

Geological formations rich in clay tend to undergo expansion upon contact with water-based drilling fluids. The principal mechanism responsible for the disintegration and swelling of these formations is the migration of hydrogen ions into the nano-scale gaps between layers of shale platelets. Effectively mitigating the challenge of clay swelling involves introducing various materials tailored for shale stabilization into water-based drilling mud. In this article, flaxseed mucilage is used as an environmentally friendly drilling fluid additive in a water-based mud system, with the goal of enhancing the rheological, filtration, and hydrophobic characteristics of the water-based mud. The flaxseed extract was added in the mud in four different concentrations (5 mL, 10 mL, 20 mL, and 50 mL). The result of the study reveals that the rheological properties at 38 and 65 degree centigrade after the addition of 10 mL and 20 mL flaxseed extract remained well within the recommended range set by the American Petroleum Institute (API). Both these samples also demonstrated transport index > 1.5 at both the temperatures. Moreover, the flaxseed extract was also effective in minimizing the fluid loss from the base mud. The 20 mL of flaxseed extract causes only 15 mL of fluid loss from the base mud, which was also three times lower than the base mud. Additionally, the flaxseed extract muds were also tested on the Ranikot shale sample for its stability. According to the immersion test, samples collected from flaxseed mud demonstrated a smooth surface with no cracks and fractures. Furthermore, these immersed shale pellets also revealed high hydrophobic behavior when tested through contact angle measurement. The 20-mL sample showed the highest hydrophobic behavior with contact angle of 56.056 degrees. Besides this, the 20-mL sample also displayed the highest cutting recovery of 70% out of all the samples. In addition, the 20-mL flaxseed sample also showed less shale swelling behavior in linear dynamic swell-meter test. Almost 1.5 times reduction in shale swelling was recorded with the addition of 20 mL flaxseed extract in the base mud. In light of these compelling findings, the study underscores flaxseed's potential as an eco-friendly and sustainable alternative to traditional clay stabilizers in drilling operations, with the aim of minimizing formation damage. [ABSTRACT FROM AUTHOR]

Published

2024

40. Quantitative Characterization of Metal Powder Morphology, Size Distribution, and Flowability for Additive Manufacturing.

Author

Murtaza, Hussain Ali, Mukhangaliyeva, Aishabibi, Golman, Boris, Perveen, Asma, and Talamona, Didier

Subjects

PARTICLE size distribution, RHEOLOGY, FOURIER series, RANK correlation (Statistics), STAINLESS steel

Abstract

The properties of the powder utilized in powder bed-based additive manufacturing are crucial in determining both the process parameters and the final quality of the fabricated components. Therefore, it is essential to assess powder characteristics, particularly particle morphology, size distribution (PSD), and rheological properties. This study aims to quantitatively characterize the PSD, morphology, and flowability of metal powders commonly used in additive manufacturing, such as AlSi10Mg, Inconel-718, Ti6Al4V, titanium, and stainless steel. To achieve this, we utilize a range of PSD models to accurately fit the measured size distributions based on volume and number, followed by conducting statistical analyses to determine the best-fitting models. Furthermore, we conducted a shape analysis using the elliptic Fourier series to characterize particle morphology quantitatively. Additionally, we examined the correlations between the powder rheological properties, measured by a Hall flowmeter, tapped density tester, and FT4 powder rheometer, and the PSD and shape indices using Spearman's coefficient test. [ABSTRACT FROM AUTHOR]

Published

2024

41. A review of geopolymer binder as a grouting material.

Author

Sierra, Karla, An, Jinwoo, Shamet, Ryan, Chen, Jiannan, Kim, Yong Je, Nam, Boo Hyun, and Park, Philip

Subjects

RHEOLOGY, PORTLAND cement, BINDING agents, GROUTING, YIELD stress, COMPRESSIVE strength

Abstract

The utilization of geopolymer as a grouting material has gained significant attention in research and construction applications. Geopolymer grout is a type of binding material that differs from traditional grouts, typically based on Portland cement. Researchers have explored its effectiveness and potential applications in grouting processes, considering its unique properties and characteristics. In this paper, various studies employing and utilizing geopolymer as a grouting material are reviewed. The emphasis is on mixture design of geopolymer grout, physical property, chemical composition of geopolymer grout, rheological behavior of geopolymer grout such as yield stress (in case of Bingham fluid) and viscosity, and engineering properties such as compressive strength, expansion, shrinkage, etc. [ABSTRACT FROM AUTHOR]

Published

2024

42. SBS 相对分子质量对改性沥青性能影响分析.

Author

陈向东, 邹佳慧, 李恩泽, and 孔德智

Abstract

In order to clarify the effect of star and linear styrene butadiene styrene block polymer( SBS) with different relative molecular weights on the performance of modified asphalt, modified asphalt with different relative molecular weights was prepared by internal blending method (5% content). The results show that the addition of SBS has a significant promotional effect on improving the performance of asphalt, which is mainly marked by the improvement of three key indicators such as penetration, softening point and ductility, as well as the improvement of high temperature rheological performance. At the same time, there are differences in the performance improvement of modified asphalt by SBS with different relative molecular weights. Within a certain range, SBS with a higher relative molecular weight exhibits better performance improvement effect. It can be seen that for road projects with different needs, choosing the appropriate SBS relative molecular weight has important guiding significance for optimizing the performance of asphalt materials and improving the quality and durability of road projects. [ABSTRACT FROM AUTHOR]

Published

2024

43. Preparation and rheological properties of organic zirconium crosslinked KGM/HPAM gel.

Author

Li, Jie, Jiang, Qiyun, Gao, Shanjun, and Shen, Chunhui

Subjects

OIL fields, RHEOLOGY, KONJAK, ANALYTICAL chemistry, PETROLEUM prospecting

Abstract

Konjac glucomannan (KGM) and partially hydrolyzed polyacrylamide (HPAM) have good application prospects in the field of petroleum fracturing field, but few studies on the rheological properties of KGM and HPAM double polymer gel systems have been reported. Optimal conditions for the high temperature and shear resistant organozirconium crosslinked double polymer gel system for petroleum fracturing were explored through optimization experiments. The thickener contained a mass ratio of 2:1 of KGM to HPAM, while the organic zirconium crosslinking agent had controlled molar ratios of 1:4:3:3 of zirconium butoxide to ligand acetylacetone, triethanolamine, and glycerol. This work presents a systematic analysis of the chemical structure, microstructure, delayed crosslinking performance, temperature resistance, and shear resistance of the gel system. The study found that the crosslinking ratio of 100:2 resulted in a controllable delayed crosslinking time of the gel formed by the organic zirconium crosslinking agent and 4.0 g/L KGM/HPAM thickener within 5–25 min at room temperature. The viscosity remained above 81 mPa·s even after shearing for 100 min at 140°C and 170 s−1. These findings provide a useful reference for the application of organic zirconium crosslinked KGM/HPAM gel system in the petroleum fracturing field. [ABSTRACT FROM AUTHOR]

Published

2024

44. Development of SBS composite modified asphalt incorporating polydopamine-enhanced MoS2.

Author

Hou, Y. L. and Bai, L. Z.

Subjects

*ASPHALT modifiers, *STRAINS & stresses (Mechanics), *RHEOLOGY, *CHARGE transfer, *CONTACT angle, *ASPHALT

Abstract

This study investigated the development of a novel composite modified asphalt incorporating PDA-MoS2 into styrene-butadiene-styrene (SBS) modified asphalt. The successful synthesis of PDA-MoS2 was confirmed through various characterization techniques. The incorporation of PDA-MoS2 into SBS modified asphalt resulted in significant improvements in performance properties. With a PDA-MoS2 content of 0.7 wt%, the modified asphalt showed a notable 15.1% rise in softening point and a 24% drop in penetration in comparison to the control SBS modified asphalt. Dynamic Shear Rheometer tests revealed a 2.4-fold increase in the rutting factor at 60°C. Multiple Stress Creep Recovery tests demonstrated enhanced rutting resistance, with a 72.2% reduction in nonrecoverable creep compliance at 0.1 kPa stress level. Electrochemical measurements showed improved corrosion resistance, evidenced by lower current densities and higher charge transfer resistance. Microstructural analysis revealed well-dispersed PDA-MoS2 particles forming a compact network structure within the asphalt matrix. The hydrophilicity of the modified asphalt increased, with a 35.3% decrease in water contact angle. The synergistic effect between PDA-MoS2, SBS, and asphalt components, facilitated by enhanced interfacial interactions and chemical bonding, contributed to the observed performance improvements. The results indicate that PDA-MoS2 has the potential to improve the characteristics of SBS modified asphalt as a modifier. [ABSTRACT FROM AUTHOR]

Published

2024

45. Factors Influencing the Rheological Characteristics of Modified Corn Stalk Fiber Asphalt Mortar.

Author

Kun Wang, Lu Qu, Zongwen Hu, Peng Hu, Hao Xu, Xiongao Li, and Yuzhu Zhu

Subjects

*HIGHWAY engineering, *CONSTRUCTION materials, *RHEOLOGY, *ROAD construction, *CORNSTALKS, *ASPHALT, *MORTAR

Abstract

As the demand for sustainable and environmentally friendly road construction materials increases, corn stalk fiber modified with NaOH is a promising candidate due to its renewable and eco-friendly nature. This study employs an orthogonal experimental design to optimize the investigation of multiple factors (corn stalk fiber length, content, and modifier concentration) in the experiments, ensuring that the effects of different factors on the high and low temperature performance of asphalt binder can be independently estimated. Dynamic shear rheometer (DSR) and bending beam rheometer (BBR) tests were conducted. The bonding between fiber and asphalt was analyzed by infrared spectroscopy, and the action mechanism of fiber in asphalt was revealed from a microscopic perspective by scanning electron microscopy and fluorescence microscopy. Evidently, the concentration of modifier is the main factor affecting the rheological properties of fiber asphalt mortar. Considering the influence of various factors on the rheological properties of modified corn stalk fiber asphalt mortar, the optimal modifier concentration is 7%, the fiber length is 6mm, and the content is 1.5%. After adding modified corn stalk fiber, the asphalt mortar did not produce new characteristic peaks, and the fiber and asphalt were mainly bonded by physical action. The large surface roughness of the modified corn stalk fiber determines its good adsorption capacity, which is conducive to increasing the bonding force of the asphalt. Fibers with a large aspect ratio are easy to bridge with each other, restraining the expansion of cracks and thus enhancing the crack resistance of the mortar. [ABSTRACT FROM AUTHOR]

Published

2024

46. Fabrication of High-Performance Asphalt Mixture Using Waterborne Epoxy-Acrylate Resin Modified Emulsified Asphalt (WEREA).

Author

Chen, Dongwei, Wu, Hao, Chen, Xiaobao, Zhan, Yiqun, and Wada, Surajo Abubakar

Subjects

*FATIGUE limit, *ASPHALT pavements, *VISCOELASTIC materials, *SHEAR strain, *STRAIN rate, *ASPHALT

Abstract

Existing research shows that using waterborne epoxy resin (WER) instead of emulsified asphalt as the binder for cold mix asphalt (CMA) can enhance the rutting resistance, high-temperature performance, fracture performance, and early performance of CMA. In order to eliminate the potential drawbacks such as insufficient strength and low-temperature performance of CMA during application, a novel method was proposed in this study for the preparation of waterborne epoxy-acrylate resin (WER), specifically tailored to modify emulsified asphalt, resulting in waterborne epoxy-acrylate resin emulsified asphalt (WEREA). The modification effect of WER on emulsified asphalt was evaluated through rheological tests and direct tensile tests. A modified design method based on the conventional Marshall design method was proposed to determine the optimal mix proportions, including the key parameters of specimen compaction and curing. The results revealed that the incorporation of WER led to a substantial improvement in the complex shear modulus and a concurrent decrease in the phase angle. When the temperature exceeded 60 °C, the phase angle exhibited a diminishing trend, indicative of a reduced viscosity as temperatures escalated. As the WER content increased, a decrease in the direct tensile strain rate was observed, accompanied by a substantial elevation in direct tensile strength. At various stress levels, the shear strain of WEREA decreases with increased content of WER, indicating that the incorporation of WER can enhance the hardness of emulsified asphalt and improve its deformation resistance. The results from MSCR tests indicate that WER could significantly improve the elasticity and hardness of emulsified asphalt, transitioning it from a viscoelastic material to an elastic material, thereby improving its deformation resistance, resistance to rutting, and high-temperature performance. The results of fatigue life are consistent with those of the amplitude sweep, both reflecting the improvement of resistance to deformation of emulsified asphalt by WER. This indicates that WER has a significant improving effect on the fatigue resistance of emulsified asphalt. Furthermore, the Marshall design tests further confirmed the advantages of WEREA in asphalt mixtures. The optimal preparation for the WEREA mixture was proposed as follows: double-sided compaction for 50 times each, aging at 60 °C for 48 h, optimal moisture content of 5.14%, cement content of 2.5%, and emulsion content of 8.4%. The optimal mix proportions identified through these tests yielded asphalt mixtures with significantly improved stability, reduced flow value, and enhanced rutting resistance compared to the hot-mix asphalt mixture (HMA) of AC-16. These findings suggest that WEREA has the potential to significantly enhance the durability and longevity of asphalt pavements. For future applications, it can be explored for use in producing cold recycled asphalt mixtures. In addition to designing the WEREA mixture according to AC-16 gradation, consideration can also be given to using a gradation with a smaller nominal maximum aggregate size for the application in the surface layer or ultra-thin wearing course. [ABSTRACT FROM AUTHOR]

Published

2024

47. Aqueous ozone effects on wheat gluten: Yield, structure, and rheology.

Author

Fan, Xiangqi, Jiang, Jiarui, Wang, Jing, Liu, Chong, Shang, Jiaying, and Zheng, Xueling

Subjects

*GLUTELINS, *FOURIER transform infrared spectroscopy, *MOLECULAR structure, *GLUTEN, *TERTIARY structure, *WHEAT starch

Abstract

This study investigates the impact of aqueous ozone (AO) on the yield, molecular structure, and rheological properties of wheat gluten separated using the batter procedure. Employing strong gluten flour (SGF) and weak gluten flour (WGF), we demonstrate that AO pretreatment significantly enhances the yield and purity of separated starch and gluten. Surface hydrophobicity, free sulfhydryl groups, Fourier transform infrared spectroscopy (FTIR), Raman, and size exclusion‐high‐performance liquid chromatography (SE‐HPLC) analyses were used to evaluate the effects of AO on the molecular structure of gluten. Our analysis reveals that low concentrations of AO induce specific modifications in gluten proteins. AO treatment increases cross‐linking in glutenin macropolymer (GMP), reduces surface hydrophobicity, and stabilizes secondary and tertiary structures. These changes include an increase in β‐sheet content by approximately 9% and a corresponding decrease in β‐turn structures, leading to enhanced viscoelastic properties of the gluten. The research highlights AO's potential as a sustainable and efficient agent in wheat flour processing, offering advancements in both product quality and eco‐friendly processing techniques. Future research should optimize AO treatment parameters and explore its effects on different cereal types further to enhance its applicability and benefits in food processing. Practical Application: Our work substantially advances the existing knowledge on wheat flour processing by demonstrating the multifaceted benefits of AO pretreatment. We unveil significant improvements in the yield and purity of starch and gluten when compared to conventional separation methods. Moreover, our in‐depth analysis of molecular changes induced by AO, including increased cross‐linking, alterations in surface hydrophobicity, and modifications in glutenin macropolymer content, provides new insights into how AO affects the viscoelastic properties of gluten. This contribution is pivotal for the development of more efficient, sustainable, and eco‐friendly wheat flour processing technologies. [ABSTRACT FROM AUTHOR]

Published

2024

48. Cold plasma processing of kiwifruit juice: Effect on physicochemical, nutritional, microstructure, rheological properties and sensory attributes.

Author

Kumar, Sitesh, Pipliya, Sunil, Srivastav, Prem Prakash, Srivastava, Brijesh, Battula, Satyanarayana Reddy, and Sen, Ramkrishna

Subjects

*LOW temperature plasmas, *PARTICLE size distribution, *RHEOLOGY, *PLASMA materials processing, *VITAMIN C, *KIWIFRUIT

Abstract

This study aimed to compare the untreated, cold plasma (CP)‐optimized (30 kV/5 mm/6.7 min), CP‐extreme (30 kV/2 mm/10 min), and thermally treated (TT) (90 ℃/5 min) kiwifruit juices based on the physicochemical (pH, total soluble solids (TSS), titratable acidity (TA), total color change (ΔE)), physical (particle size and rheology), microstructure (optical microscope), bioactive compounds (polyphenol, ascorbic acid, and sugar compounds), and sensory characteristics of kiwifruit juice. The pH, TSS, and TA were not significantly affected in CP and TT juice, whereas the ΔE (6.52) of TT juice lies in the range of "greatly visible." The microstructure characteristics of juice significantly changed after CP and thermal treatment. The cell and tissue disruption in CP‐extreme and thermally treated juice was more than CP‐optimized. The particle size of juice decreased irrespective of treatment, but the span value of CP‐optimized juice was the lowest. Further, the CP treatment showed a lower consistency index, apparent viscosity, and pseudoplasticity of juice than the thermal treatment. The CP‐treated juice retained bioactive and nutritional attributes more than thermally treated juice. The CP‐optimized, CP‐extreme, and thermal treatment reduced the sucrose content by 54, 55, and 23%, while the fructose and glucose content were increased by 17, 12, & 93%, and 17, 11 & 99%, respectively. Among the CP‐treated juice, CP‐optimized (71.36 mg/100g) contained a higher amount of ascorbic acid than the CP‐extreme (64.36 mg/100g). Based on the similarity values in the fuzzy logic analysis, the sensory attributes of CP‐optimized treated juice were superior to CP‐extreme and thermal treated. Practical Application: In this era, non‐thermal processing techniques are trending for retaining the nutrition and stability of juice. The old plasma (CP)‐treated kiwifruit juice had better nutritional, bioactive compounds, and sensory attributes than the thermally treated juice. Further, the CP‐treated juice had higher flowability and lower viscosity, making it ideal for juice processing. The conclusions drawn suggest that CP processing is a better alternative for processing kiwifruit juice than thermal processing. [ABSTRACT FROM AUTHOR]

Published

2024

49. Potassium-based emulsifying salts in processed cheese: A rheological, textural, tribological, and thermal approach.

Author

Šantová, K., Salek, R.N., Kůrová, V., Mizera, A., Lapčíková, B., Vincová, A., Zálešáková, L., Kratochvílová, A., Lorencová, E., Vinter, Š., Opustilová, K., and Karhánková, M.

Subjects

*RHEOLOGY, *THERMAL properties, *DAIRY industry, *HARDNESS, *CHEESE

Abstract

The list of standard abbreviations for JDS is available at adsa.org/jds-abbreviations-24. Nonstandard abbreviations are available in the Notes. The aim of the study was to investigate the effect of potassium-based emulsifying salts (ES; 2% wt/wt concentration) with different phosphate chain lengths (dipotassium hydrogenphosphate [K 2 HPO 4 ; DKP], tetrapotassium diphosphate [K 4 P 2 O 7 ; KTPP], pentapotassium triphosphate [K 5 P 3 O 10 ; TKPP]) on the physicochemical, viscoelastic, textural, tribological, thermal, and sensory properties of processed cheese (PC; 40% wt/wt DM, 50% wt/wt fat in DM) during a 60d storage period (6°C ± 2°C). On the whole, the hardness of all PC samples increased with the increasing chain length of ES (DKP < TKPP < KTPP) and the prolonging storage period. Moreover, the hardness results were in accordance with those of the rheological analysis. All PC samples exhibited a more elastic character (G′ > G″; tan δ < 1). The type of potassium-based ES affected the binding of water into the structure of the PC. Furthermore, the study confirmed that the manufactured PC received optimal sensory scores, without any excessive bitterness. It could be concluded that the type of applied ES and storage length affected the functional properties of PC. Finally, the information provided in this study could serve as a tool for the dairy industry to help appropriately select potassium-based ES for PC manufacture with desired properties. [ABSTRACT FROM AUTHOR]

Published

2024

50. Rheology Deterioration and Damage Evaluation of SBS Modified Asphalt Under Two Salt Erosion Modes.

Author

Cheng, Yongchun, Liang, Jiaxiang, Wang, Wensheng, Wang, Haitao, Zhao, Wenshuo, and Xia, Wenlei

Subjects

*FATIGUE limit, *DETERIORATION of materials, *GLASS transition temperature, *ASPHALT testing, *ASPHALT pavements, *ASPHALT

Abstract

Salt erosion is an important negative factor on the performance deterioration of asphalt-based materials. The basic properties of asphalt in salt erosion environments have been extensively studied; however, there is a certain lack of research on the rheological property of styrene–butadiene–styrene (SBS) modified asphalt under various salt erosion conditions. This study aims to identify the rheology deterioration of SBS modified asphalt under the action of salt freeze–thaw or saline immersion cycles through laboratory experiments. Rheological properties and creep recovery properties of SBS modified asphalt were tested based on the dynamic shear rheometer, and their rutting resistance capacity and fatigue cracking resistance were analyzed. Viscoelastic properties and low-temperature property of SBS modified asphalt were investigated by Burgers model, Christensen–Anderson–Marasteanu model and glass transition temperature. Results showed that the rutting capacity increased by an average of 34.5% and 39.7% after 21 times salt freeze–thaw and saline immersion cycles, respectively, while the fatigue cracking resistance decreased by 34.2% and 40.1%. Multi-stress creep recovery test manifested that both salt erosion modes had slight influence on the creep recovery property. However, the non-recoverable creep compliance at 3.2 kPa decreased by 37.5% and 32.3% after 21 times salt freeze–thaw and saline immersion cycles, respectively. Based on glass transition temperature, the low-temperature performance of asphalt decreased significantly after salt erosion. The rheological behavior and damage degree of asphalt were different for different salt erosion modes. The study may provide a theoretical basis for the construction and maintenance of asphalt pavement in salt-rich areas. [ABSTRACT FROM AUTHOR]

Published

2024