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247,248 results on '"Process Chemistry and Technology"'

1. Distributed Control of an Ill-Conditioned Non-Linear Process Using Control Relevant Excitation Signals

Author

Sha’aban, Yusuf Abubakar and Sha’aban, Yusuf Abubakar

Abstract

Efficient control schemes for ill-conditioned systems, such as the high-purity distillation column, can be challenging and costly to design and implement. In this paper, we propose a distributed control scheme that utilizes well-designed excitation signals to identify the system. Unlike traditional systems, we found that a summation of correlated and uncorrelated signals can yield better excitation of the plant. Our proposed distributed model predictive control (MPC) scheme uses a shifted input sequence to address loop interactions and reduce the computational load. This approach deviates from traditional schemes that use iteration, which can increase complexity and computational load. We initially tested the proposed method on the linear model of a highly coupled 2 × 2 process and compared its performance with decentralized proportional-integral-derivative (PID) controllers and centralized MPC. Our results show improved performance over PID controllers and similar results to centralized MPC. Furthermore, we compared the performance of the proposed approach with a centralized MPC on a nonlinear model of a distillation column. The results for the second study also demonstrated comparable performance between the two controllers with the decentralised control slightly outperforming the centralised MPC in some cases. These findings are promising and may be of interest to practitioners that are more comfortable with tuning decentralised loops.

Published
2024

2. Texaphyrin-Based Calcium Sensor for Multimodal Imaging

Author

Thiabaud, Grégory D., Schwalm, Miriam, Sen, Sajal, Barandov, Ali, Simon, Jacob, Harvey, Peter, Spanoudaki, Virginia, Müller, Peter, Sessler, Jonathan L., Jasanoff, Alan, Thiabaud, Grégory D., Schwalm, Miriam, Sen, Sajal, Barandov, Ali, Simon, Jacob, Harvey, Peter, Spanoudaki, Virginia, Müller, Peter, Sessler, Jonathan L., and Jasanoff, Alan

Abstract

The ability to monitor intracellular calcium concentrations using fluorescent probes has led to important insights into biological signaling processes at the cellular level. An important challenge is to relate such measurements to broader patterns of signaling across fields of view that are inaccessible to optical techniques. To meet this need, we synthesized molecular probes that couple calcium-binding moieties to lanthanide texaphyrins, resulting in complexes endowed with a diverse complement of magnetic and photophysical properties. We show that the probes permit intracellular calcium levels to be assessed by fluorescence, photoacoustic, and magnetic resonance imaging modalities and that they are detectable by multimodal imaging in brain tissue. This work thus establishes a route for monitoring signaling processes over a range of spatial and temporal scales., National Institutes of Health (NIH)

Published
2024

3. An Effective Med-VQA Method Using a Transformer with Weights Fusion of Multiple Fine-Tuned Models

Author

Al-Hadhrami, Suheer, Menai, Mohamed El Bachir, Al-Ahmadi, Saad, Alnafessah, Ahmad, Al-Hadhrami, Suheer, Menai, Mohamed El Bachir, Al-Ahmadi, Saad, and Alnafessah, Ahmad

Abstract

Visual question answering (VQA) is a task that generates or predicts an answer to a question in human language about visual images. VQA is an active field combining two AI branches: NLP and computer vision. VQA in the medical field is still at an early stage, and it needs vast efforts and exploration to reach practical usage. This paper proposes two models that are utilized in the latest vision and NLP transformers that outperform the SOTA and have not yet been utilized in medical VQA. The ELECTRA-base transformer is used for textual feature extraction, whereas SWIN is used for visual feature extraction. In the SOTA medical VQA, selecting the model is based on the model that achieves the highest validation accuracy or the last model in training. The first proposed model, the best-value-based model, is selected based on the highest validation accuracy. The second model, the greedy-soup-based model, uses a greedy soup technique based on the fusion of multiple fine-tuned models to set the model parameters. The greedy soup selects the model parameters by fusing the model parameters that have significant performance on the validation accuracy in training. The greedy-soup-based model outperforms the best-value-based model, and both proposed models outperform the SOTA, which has an accuracy of 83.49%. The greedy-soup-based model is optimized with batch size and learning rate. During the optimization, seven extra models exceed the SOTA accuracy. The best model trained with a learning rate of 1.0×10−4 and batch size 16 achieves an accuracy of 87.41%.

Published
2024

4. A Rapid Control Prototyping and Hardware-in-the Loop Approach for Upper Limb Robotic Exoskeletons Control

Author

Bodo, Giulia, Tessari, Federico, Buccelli, Stefano, Laffranchi, Matteo, Bodo, Giulia, Tessari, Federico, Buccelli, Stefano, and Laffranchi, Matteo

Abstract

In the last decade, robotic-mediated rehabilitation has emerged as a potential solution to improve repetitive task training. Each device in this field has a unique development history shaped by engineers’ expertise in specific programming languages or platforms. In this work we adopt an approach that tries to abstract from the final implementation with the aim to make control logic more shareable and understandable. The authors will present the outcomes of the application of a Rapid Control Prototyping strategy to an upper-limb robotic exoskeleton. A model-based design approach implemented on a real-time target machine is presented. This modern design approach was explored with several control strategies and was used to test the exoskeleton’s performances. The proposed method highlights how it is possible to develop the entire control architecture in a single programming environment.

Published
2024

5. Analytical chemistry meets art: The transformative role of chemometrics in cultural heritage preservation

Author

Química Analítica i Química Orgànica, Universitat Rovira i Virgili, Riu J; Giussani B, Química Analítica i Química Orgànica, Universitat Rovira i Virgili, and Riu J; Giussani B

Abstract

This review intends to illustrate the fruitful collaboration between chemometrics and cultural heritage science. It showcases past achievements, aiming to inspire numerous cultural heritage researchers who have yet to incorporate multivariate techniques in analysing their research findings. The goal is to practically discuss applications with examples extracted from the literature. These range from the most basic early applications, influenced by the limited laboratory equipment available at those times, to the more contemporary research endeavours. Recently, numerous new analytical instrumentations have gained widespread adoption, some of which were previously inconceivable for field use or analysing micro-samples, characteristics needed to work with cultural heritage. Chemometrics serves as the binding element in this process. It handles the multivariate data generated by analytical instruments, even from multiple instruments used to characterize the same sample and yields easily interpretable graphs that encapsulate all the information considered simultaneously. This review will delve into the challenges of achieving commendable results and constructing effective descriptive or predictive models. Additionally, it will offer essential theoretical insights crucial for a comprehensive grasp of the fundamental algorithms employed. We have explored fundamental qualitative and quantitative models capable of addressing most issues encountered in studying a historical or artistic artifact. Additionally, focus was directed towards data pre-processing, at times essential for enhancing model outcomes.

Published
2024

6. Enhanced CO2 Sensing by Oxygen Plasma-Treated Perovskite-Graphene Nanocomposites

Author

Universitat Rovira i Virgili, Casanova-Chafer, J; Garcia-Aboal, R; Llobet, E; Atienzar, P, Universitat Rovira i Virgili, and Casanova-Chafer, J; Garcia-Aboal, R; Llobet, E; Atienzar, P

Abstract

Carbon dioxide (CO2) is a major greenhouse gas responsible for global warming and climate change. The development of sensitive CO2 sensors is crucial for environmental and industrial applications. This paper presents a novel CO2 sensor based on perovskite nanocrystals immobilized on graphene and functionalized with oxygen plasma treatment. The impact of this post-treatment method was thoroughly investigated using various characterization techniques, including Raman spectroscopy, X-ray diffraction, and X-ray photoelectron spectroscopy. The detection of CO2 at parts per million (ppm) levels demonstrated that the hybrids subjected to 5 min of oxygen plasma treatment exhibited a 3-fold improvement in sensing performance compared to untreated layers. Consequently, the CO2 sensing capability of the oxygen-treated samples showed a limit of detection and limit of quantification of 6.9 and 22.9 ppm, respectively. Furthermore, the influence of ambient moisture on the CO2 sensing performance was also evaluated, revealing a significant effect of oxygen plasma treatment.

Published
2024

7. ProSpecTool: A MATLAB toolbox for spectral preprocessing selection

Author

Química Analítica i Química Orgànica, Universitat Rovira i Virgili, Ezenarro, J.; Schorn-García, D.; Busto, O.; Boqué, R., Química Analítica i Química Orgànica, Universitat Rovira i Virgili, and Ezenarro, J.; Schorn-García, D.; Busto, O.; Boqué, R.

Published
2024

14. Interfacial behavior of intravitreally injected drugs in silicone-oil-filled eye models

Author

Anfisa Ayalon, Alexander Rubowitz, Pritam Kumar Roy, Shraga Shoval, Irina Legchenkova, and Edward Bormashenko

Subjects
Process Chemistry and Technology, Materials Chemistry, Surfaces, Coatings and Films
Abstract

This paper is devoted to the interfacial aspects of the intraocular behavior, migration and distribution of commonly injected ophthalmic drugs in eyes filled with medical-grade 1300 cSt silicone oil used as a retinal tamponade agent. Novel in vitro and ex vivo models were created for studying the physical properties of the retinal surface and interfacial spreading of the ophthalmic drugs over retinas. In vitro model experiments showed that the droplets of all tested drugs sank rapidly in the silicone oil to contact with the plasma-treated glass and then rapidly spread over the glass surface. In the ex vivo model, the migration phase was followed by contact with and rapid spread/absorption by the retinal interface. The wetting behavior of drugs under contact with the glass substrate and retinas was similar. The characteristic timescales of drug spreading, controlled by the viscous dissipation, were close. All tested drugs migrated to the retinal surface and rapidly spread across the retinal surface. This suggests that intravitreal drugs might be used effectively in eyes filled with silicone oil tamponade, as they rapidly migrate to and spread over the retinal surface.

Published
2023

15. Innovative isolation of colorant from Butea monosperma for surface-modified silk dyeing

Author

Shahid Adeel, Shafqat Abbas, Noman Habib, Manel Ben Ticha, Fatima Batool, and Rony Mia

Subjects
Process Chemistry and Technology, Materials Chemistry, Surfaces, Coatings and Films
Abstract

Recently, there has been a surge of interest in adopting natural dyes to avoid the environmental difficulties connected with synthetic coloring compounds. This research focuses on extracting natural dyes from Butea monosperma plants and on developing sustainable dyeing methods for silk fabric. Natural colorants were extracted using an aqueous and an acidic extraction procedure, and silk fabrics were dyed with the extracts using mordanting with a variety of metal mordants and bio-mordants. The treatment of fabric and extracts was carried out using microwave (MW) irradiation. It was found that the bio-mordants have shown higher color strength than metallic mordant. It was also observed that the acacia and pine nut hull at 80°C and before dyeing pomegranate extract at 80°C and after dyeing of silk fabric at 40°C using bio-mordants gave higher color strength than metallic mordants. For comparative analysis, aluminum (Al) salt at 40°C, iron (Fe) salt at 60°C and tannic acid at 80°C gave acceptable results. The colorfastness characteristics were also found good to excellent. The bio-mordants not only provide the higher color strength and fastness properties, but these extracts have also shown an environmental friendly approaches. Scanning electron microscopy image and Fourier transform infrared spectroscopy analyses revealed the difference between irradiated and unirradiated silk fabrics. Therefore, it is recommended that MW rays and bio-mordants should be used in the natural dyeing of silk fabric to produce colorfast shades of acceptable strength.

Published
2023

16. Ion-irradiation-induced effects on the surface characteristics of Ge–Bi–Se thin films

Author

Mostafa M Abdelhamid, Ali A Atta, Ahmed M Abdel Reheem, and Ahmed H Ashour

Subjects
Process Chemistry and Technology, Materials Chemistry, Surfaces, Coatings and Films
Abstract

In this study, fabricated amorphous chalcogenide Ge10Se70Bi20 thin films were irradiated with nitrogen (N+), argon (Ar+), hydrogen (H+) and oxygen (O+) ion beams. The compositions of the pure and irradiated films were investigated using X-ray diffraction, which confirmed the amorphous structures of the pristine and the irradiated Ge10Se70Bi20 thin films. The optical parameters such as optical bandgap, absorption edge, Urbach energy, Tauc parameter and extinction coefficient of the unirradiated and irradiated films were determined using ultraviolet/visible spectroscopy. The energy gap was found to reduce from 1.355 eV for unirradiated Ge10Se70Bi20 to 1.02, 0.73, 0.60 and 0.51 eV after irradiation with nitrogen, argon, hydrogen and oxygen ion beams, respectively. Meanwhile, the band tail of Ge10Se70Bi20, which is 0.12 eV, increased to 0.16, 0.40, 0.45 and 0.48 eV after irradiation with nitrogen, argon, hydrogen and oxygen ion beams, respectively. In particular, the conductivity increased by two orders after the pristine film had been exposed to an oxygen beam. The direct current electrical conductivity of the pristine film increased from 1.5 × 10−7 to 1.4 × 10−5 Ω−1 cm−1 after irradiation with an oxygen ion beam. Furthermore, the activation energy and Mott’s parameters of the original and irradiated Ge10Se70Bi20 films were deduced. The reported modifications of the optical and electrical parameters suggest the use of irradiated Ge10Se70Bi20 thin films in important applications – for example, optical data storage and optoelectronic devices.

Published
2023

17. The influence of copper substrate temperature on the wettability of graphene coating

Author

Sergey Y Misyura, Vladimir A Andryushchenko, and Vladimir S Morozov

Subjects
Process Chemistry and Technology, Materials Chemistry, Surfaces, Coatings and Films
Abstract

The influence of the parameters of a copper substrate on wettability at different temperatures was studied experimentally and theoretically. It is known that water condensation on graphene leads to a change in the electrical properties and affects graphene sensor sensitivity. To date, there are no data on the effect of temperature on the surface properties of graphene synthesized on copper. It is shown for the first time that a change in the (111), (110) and (100) crystal orientations of copper leads to different structuring of water on copper and on the graphene layer. An increase in temperature alters the density of water distribution and the pattern of water structuring. The analysis of the influence of grain boundaries on graphene synthesis is given. A change in the size of defects is shown to alter the qualitative nature of roughness for copper and graphene. Various methods of roughness processing allow explanation of the inconsistency of existing works comparing the roughness of the metal and graphene coating. The roughness measurement serves to prove the authors’ previously proposed hypothesis about the local stratification of graphene and copper due to large surface defects. The results obtained are important for the development of graphene-based sensor technologies.

Published
2023

18. Fabrication of radiative cooling film with superhydrophobic self-cleaning property

Author

Dong-Mei Zhang, Hui-Di Wang, Meng-Chen Huang, Ting-Ting Fan, Fu-Quan Deng, Chao-Hua Xue, and Xiao-Jing Guo

Subjects
Process Chemistry and Technology, Materials Chemistry, Surfaces, Coatings and Films
Abstract

Radiative cooling materials can cool terrestrial objects without any energy input but are susceptible to rain wetting and dust contamination, which affects badly their cooling characteristics. Herein, this work fabricated a radiative cooling porous film with superhydrophobic self-cleaning properties using poly(vinylidene fluoride-co-hexafluoropropylene) (PVDF-HFP) and poly(vinylidene fluoride) (PVDF). The PVDF-HFP/PVDF film consists of micropores with nanoparticles both inside and at the surface. The micro/nanostructures enhanced the scattering of solar light, which in combination with the infrared emissivity of both PVDF-HFP and PVDF polymers makes the film show excellent radiative cooling ability with a sub-ambient temperature drop of 16°C. The micro/nanostructures roughened the surface of the film, which in combination with the low surface energy property of both PVDF-HFP and PVDF polymers endows the film with superhydrophobic self-cleaning properties. The self-cleaning function defends the film from contamination and maintains sustainable radiative cooling for lasting applications. The integration of cooling and self-cleaning into a film paves the way for multifunctional and long-life radiative cooling materials.

Published
2023

19. Osseointegration and anti-infection of dental implant under osteoporotic conditions promoted by gallium oxide nano-layer coated titanium dioxide nanotube arrays

Author

Yao, Litao, Al-Bishari, Abdullrahman M., Shen, Jiating, Wang, Zhen, Liu, Tingting, Sheng, Lieping, Wu, Gang, Lu, Lei, Xu, Lihua, Liu, Jinsong, Oral Cell Biology, and Oral Implantology

Subjects
Antibacterial, Nanotube, Titanium, Gallium oxide, Process Chemistry and Technology, Materials Chemistry, Ceramics and Composites, Osteointegration, Magnetron sputtering, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Abstract

The insufficient osteointegration between titanium (Ti) based dental implants and surrounding bone tissue under osteoporotic conditions, as well as implant-associated infections usually associate with dental implant failure. Gallium (Ga) has drawn increasing attention due to its antibacterial ability and pro-osteogenic property. Herein, we established a facile strategy to deposit gallium oxide (Ga2O3) nano-layer on titanium dioxide nanotube (TNT) arrays by magnetron sputtering. Both Ga2O3@TNT/50 W and Ga2O3@TNT/100 W specimens were prepared at different powers (50 W and 100 W), respectively, which all achieved a sustained release of Ga3+ ion for over 14 days. In vitro results showed that Ga2O3@TNT/50 W sample has good biocompatibility and osteogenic activity, compared with TNT and Ga2O3@TNT/100 W samples. Moreover, both Ga2O3@TNT/50 W and Ga2O3@TNT/100 W samples possess potent antibacterial properties, due to the released Ga3+ ion. Furthermore, in vivo results indicated that the Ga2O3@TNT/50 W showed excellent in vivo antibacterial ability and promoted new bone formation effectively compared with TNT implants in an osteoporotic rat model with Staphylococcus aureus (S. aureus) infection. Therefore, such Ga2O3 deposition coating strategy provides a valuable guidance for the potential future development of Ga-doped dental implants and TNT based drug loading surfaces for clinical applications.

Published
2023

22. Evolution of alumina phase structure in thermal plasma processing

Author

Kimmo Kaunisto, Juha Lagerbom, Mari Honkanen, Tommi Varis, Aloshious Lambai, Gaurav Mohanty, Erkki Levänen, Päivi Kivikytö-Reponen, and Erkka Frankberg

Subjects
AlO (D), Process Chemistry and Technology, solid state reaction (A) [Powders], X-ray methods (B), Materials Chemistry, Ceramics and Composites, Powders: solid state reaction (A), Electron microscopy (B), Transition phases, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Abstract

Alumina (Al2O3) remains one the most important engineering ceramic for industrial applications. In addition to the α phase, transition alumina phases have interesting characteristics. Controlling the obtained phase structure from alumina melt requires processes with extreme cooling rates and therefore limits the tailoring capabilities. This study investigates how the cooling rate of pure alumina affects its microstructural properties and phase structure in plasma-based processing. The paper reports phase changes in micron sized granulated alumina particles in high-temperature plasma spheroidization and compares the results to plasma sprayed alumina coatings. Both plasma processes involve melting of the material followed by subsequent rapid cooling. Direct comparison on the alumina phase transitions is obtained for the two methodically distinct processing routes, creating unique microstructures due to difference in their cooling rates.

Published
2023

31. Micro-welding of sapphire and metal by femtosecond laser

Author

Rui Pan, Dong Yang, Taoshuai Zhou, Yinghao Feng, Zhisen Dong, Zhaoyang Yan, Peng Li, Jin Yang, and Shujun Chen

Subjects
Process Chemistry and Technology, Materials Chemistry, Ceramics and Composites, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Published
2023

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