Low Particle Research Articles

Investigation of MoSe2 filled MAO Coating on TC6 alloy- tribological and corrosion characterization of multiple interface structure

To enhance the tribological properties and corrosion resistance of titanium alloys, this study proposes a novel tribological interface structure combining micro-arc oxidation ceramic coatings with MoSe2. Comprehensive analysis using X-ray diffractometry, profilometry, energy-dispersive spectroscopy, and scanning electron microscopy was conducted to evaluate the tribological characteristics of this structure under dry friction and liquid lubrication conditions. Electrochemical experiments assessed the corrosion resistance of the structure. The results indicated that under 3 N-2.5 cm/s, oil lubrication, the structure exhibited the best friction-reducing and lubricating performance, with the friction coefficient reduced by 75 %. The synergistic interaction between the low shear force MoSe2 particles and the TiO2-rich ceramic coating formed a lubricating layer on the surface, thereby achieving reduced friction and enhanced wear resistance. Additionally, this structure demonstrated excellent corrosion resistance. This study provides valuable insights for integrating micro-arc oxidation with new materials in engineering applications.

Effect of ultrasonic treatment on the structure and emulsification properties of soybean isolate protein-hyaluronic acid complexes and the stability of their loaded astaxanthin emulsions

The purpose of this work was to prepare an astaxanthin emulsion stabilized by a soybean isolate protein (SPI)-hyaluronic acid (HA) complex and to investigate its protective effect on astaxanthin. In order to examine the impact of various ultrasonic energies (0 W–300 W) on the structural characteristics of the complex and the stability of the emulsion, the SPI-HA complex was created via ultrasonography. The findings demonstrated that ultrasonication may had an impact on the hydrophobic, electrostatic, and hydrogen bonding interactions between SPI and HA, which caused the protein structure to unfold and reveal the interior hydrophobic amino acid residues. Moreover, ultrasonication enhanced the emulsification qualities of SPI-HA complexes by lowering their average particle size. The rheological findings demonstrated that the emulsion's viscosity and energy storage modulus (G′) were considerably decreased by the ultrasonic treatment. The appearance of the emulsions and optical microscopy results further indicated that the emulsions prepared from SPI-HA had superior storage stability, pH stability, and light stability compared to pure SPI. SPI-HA exhibited superior emulsion stability and lower particle size at 150 W ultrasonic power. The AST incorporated in the emulsion was also well protected. The emulsion effectively slows down the degradation of AST. The findings of this study may help create more robust and natural emulsion delivery systems that guarantee the continuous or regulated release of lipophilic bioactive compounds.

Surfactant-Nanoparticle Formulations for Enhanced Oil Recovery in Calcite-Rich Rocks.

Aqueous surfactant-nanoparticle mixtures have received great attention recently for promoting a more sustainable and efficient enhanced oil recovery (EOR) process. However, colloidal stability under reservoir conditions is considered a great challenge. In addition, the way synergy operates in EOR is not clearly understood. This study aims to formulate a cost-effective surfactant-nanoparticle mixture in a formation brine for efficient EOR in calcite-rich oil reservoirs. For this, bare silica nanoparticles were covalently grafted using an epoxysilane and blended with two commercial surfactants, namely a zwitterionic alkyl hydroxysultaine (AHS) and a binary zwitterionic-nonionic (ZN) surfactant, for both additional steric stabilization and EOR. The effects of additives alone or their mixtures were examined at solid-fluid and fluid-fluid interfaces to explore their impact on EOR. The surfactant-nanoparticle blend often showed a pH-responsive behavior at solid-fluid and fluid-fluid interfaces with particles serving as carriers or surface activity improvers for surfactant resulting in different extents of rock wettability alteration and emulsification. In oil recovery tests, optimum surfactant concentrations were found to significantly increase crude oil recovery of formation brine by 36 ± 1% original oil in place (OOIP) in secondary spontaneous imbibition which was further enhanced by 14 ± 0.5% OOIP upon adding a low particle concentration (0.01 wt %). The surfactant-nanoparticle formulation was also efficient in producing residual crude oil in tertiary mode (6% OOIP additional oil recovery after formation brine). The oil recovery results disclosed a high dependence on the emulsification ability of the blends with AHS-particle dispersions producing more stable emulsions and thus more crude oil compared to that of ZN.

Improving the removal of fine particles in cyclone using heterogeneous vapor condensation enhanced by atomization

Using a heat exchanger to cool high humidity flue gas can create a supersaturated water vapor environment, allowing fine particles to grow into large droplets by heterogeneous vapor condensation, which is conductive to the removal of fine particles by traditional equipment. However, due to the limited condensable vapor obtained by cooling, this technology can only be used in the flue gas with low particle concentration. In this study, atomization droplets were added before the heat exchanger to improve the effect of heterogeneous vapor condensation at high particle concentration, and then coupled with a cyclone separator, which was used for the deep treatment of the flue gas after the wet dedusting system. The particle removal characteristics were investigated through laboratory experiments and bypass experiments in a metallurgical company. The experimental results show that the application of atomization-heterogeneous condensation reduced the particles concentration after cyclone by 74.2 % compared with that of single heterogeneous condensation. Temperature-drop and atomized volume affected the removal of particles with size < 2 μm and > 2 μm, respectively. The industrial flue gas bypass experiment indicated that the system had strong adaptability to fluctuating conditions. When the inlet particle concentration did not exceed 2000 mg/Nm3, the outlet particle concentration can be maintained within 20 mg/Nm3.

Fabrication of stable oleogel-in-water nanoemulsions with ethyl cellulose nanoparticles

Nanoemulsions (NEs) are liquid-based nanosized colloidal systems offering advantages (superior kinetic stability and rheology) compared to macro- and microemulsions. However, stabilization of these emulsions is difficult, since the small droplet sizes in NEs present large surface area-to-volume ratios. Thus, they need to be stabilized by superb emulsifiers to maintain stability. Herein, we report the construction of novel oleogel-in-water NEs with excellent stability against coalescence and phase separation. To do this, nanoparticles (NPs), based on ethylcellulose (EC), were first prepared, and then NEs were made using EC oleogel as the oil phase, ECNPs solution as the water phase, and tween-80 (TW80) as the surfactant. It was observed that NE stabilized by ECNPs, EC oleogel, and TW80 had a significantly lower particle size (201.86±1.57 nm), polydispersity index (0.13±0.06), with no phase separation over 30 days of storage as well as a higher zeta potential (-79.68±1.36 mV), and complex modulus (21441.80±418.21 kPa), as compared to the control NE (stabilized only by TW80). According to the findings, the developed NE has the potential for food and drug delivery applications.

Effect of ultrasound assisted H2O2 degradation on longan polysaccharide: degradation kinetics, physicochemical properties and prebiotic activity

This study aimed to investigate the effect of ultrasound-assisted H2O2 (US/H2O2) reaction on degradation parameters and kinetics, physicochemical properties and prebiotic activity of longan polysaccharide (LP). Results showed that US/H2O2 had a synergistic effect on the degradation of LP, and its kinetic equation followed to the fist – order model. US/H2O2 degradation did not change the chemical and monosaccharide composition of LP but altered their ratio. Compared with LP, three degraded polysaccharides (DLPs) displayed lower molecular weight, particle size and viscosity, but higher solubility. SEM and AFM revealed that US/H2O2 degradation led to significant differences in the microstructure and solution conformation of LP. Moreover, LP and DLPs showed different proliferation effects on four lactobacilli and bifidobacteria strains, among which DLP-8 (degraded for 8 h) exhibited the strongest prebiotic activity. US/H2O2 could be effectively applied to the degradation of LP to improve its physicochemical properties and bioactivities.

Association between lipoprotein particle concentration and size and progression of coronary plaque: the MACS Longitudinal Coronary CT angiography study

Abstract Background People living with HIV have greater risk of cardiovascular diseases (CVD) than people without HIV and tend to have different risk profiles, including higher serum triglycerides and lower LDL cholesterol levels. Nuclear magnetic resonance (NMR) provides a detailed phenotype of lipoproteins. Purpose To examine the associations between lipoprotein particle concentrations and size and progression of coronary artery plaque among people living with and without HIV, and whether these associations differ by HIV serostatus. Methods Men with no clinical CVD in the Multicenter AIDS Cohort Study (MACS) who underwent a coronary CT angiography at baseline (2010-13) and follow-up (2015-17) were included. NMR spectroscopy was completed on fasting serum samples at baseline. Logistic regression models for the change in total coronary plaque volume (in tertiles) were estimated with NMR-derived lipoproteins as predictors. Levels were log-transformed and standardized to make results comparable. Models were adjusted for demographics, statin use and HIV serostatus (model 1) with addition of CVD risk factors (model 2). Interactions by HIV serostatus were also tested. Results A total of 549 men (314 with HIV; 235 without HIV) were included. Mean age was 53 ±7 years; 58% were White, 30% Black, and 12% Hispanic. Coronary plaque was present in 70% and plaque volume progressed in 79% of the cohort. Among men with HIV, 81% had undetectable HIV RNA and 12% had a diagnosis of AIDS at baseline. Men with HIV had significantly higher levels of small LDL-P, and total, medium and large VLDL-P levels compared to men without HIV, and lower levels of total, small and large HDL-P (Table 1). Men with HIV had significantly greater progression of plaque volume (37 mm3) compared to men without HIV (31 mm3, p&amp;lt;0.05). Levels of total and small LDL-P concentrations were directly associated with plaque progression, whereas large HDL-P was inversely associated with plaque progression in the combined sample (Model 2). Associations between total and small LDL-P with plaque progression were stronger in men with HIV than in men without HIV in models 1 and 2 (interaction p&amp;lt;0.01). While associations in fully adjusted models for total VLDL-P and small VLDL-P were significant in men without HIV, there were no significant associations between these particle concentrations with coronary plaque progression among men without HIV (interaction p&amp;lt; 0.01) (Model 2, Table 2). Conclusion Associations between lipid particle concentrations and coronary plaque progression differed between men with and without HIV, with stronger associations seen in men without HIV for total and small LDL-P. Despite having higher VLDL and lower HDL particle concentrations at baseline, these particle concentrations were only associated with plaque progression in men without HIV. Further research is needed to elucidate HIV specific factors for plaque progression to tailor risk reduction strategies.

Improving the Mechanical, Thermoelectric Insulations, and Wettability Properties of Acrylic Polymers: Effect of Silica or Cement Nanoparticles Loading and Plasma Treatment.

The acrylic polymer composites in this study are made up of various weight ratios of cement or silica nanoparticles (1, 3, 5, and 10 wt%) using the casting method. The effects of doping ratio/type on mechanical, dielectric, thermal, and hydrophobic properties were investigated. Acrylic polymer composites containing 5 wt% cement or silica nanoparticles had the lowest abrasion wear rates and the highest shore-D hardness and impact strength. The increase in the inclusion of cement or silica nanoparticles enhanced surface roughness, water contact angle (WCA), and thermal insulation. Acrylic/cement composites demonstrated higher mechanical, electrical, and thermal insulation properties than acrylic/silica composites because of their lower particle size and their low thermal/electrical conductivity. Furthermore, to improve the surface hydrophobic characteristics of acrylic composites, the surface was treated with a dielectric barrier discharge (DBD) plasma jet. The DBD plasma jet treatment significantly enhanced the hydrophobicity of acrylic polymer composites. For example, the WCA of acrylic composites containing 5 wt% silica or cement nanoparticles increased from 35.3° to 55° and 44.7° to 73°, respectively, by plasma treatment performed at an Ar flow rate of 5 L/min and for an exposure interval of 25 s. The DBD plasma jet treatment is an excellent and inexpensive technique for improving the hydrophobic properties of acrylic polymer composites. These findings offer important perspectives on the development of materials coating for technical applications.

Preparation and properties of a rigid hemp shiv insulation particle board using citric acid-glycerol mixture as an eco-friendly binder

Particle boards are commonly manufactured from wood-based material bound with a thermosetting adhesive based on the reaction of formaldehyde with phenol, urea, melamine, or co-condensates. The use of formaldehyde is a cause for concern due to its harmful emissions. This study investigates the use of an alternative binder combined with particles derived from a short-cycle crop as an alternative to timber derived particles. A low density particle board was developed using hemp shiv as an aggregate with a binder made with crude glycerol, derived from the waste stream of the bio-diesel industry, esterified with citric acid under heat activation. This board was characterized and found to have good mechanical properties, low thermal conductivity, and good moisture buffering. Dimensional stability was compromised by swelling when exposed to water, but it will be possible to address this shortcoming using hydrophobic additives. The acoustic properties of the board were also found to be excellent, showing potential for use as a thermally insulating acoustic separator for internal walls.

A promise of nose to brain delivery of bevacizumab intranasal sol-gel formulation substantiated in rat C6 glioma model.

Glioblastoma is one of the rapidly spreading cancers, with its potent malignancy often linked to pronounced angiogenesis within tumors. To mitigate this vascularization profile, bevacizumab (Avastin®), a monoclonal antibody, has been utilized for its antiangiogenic activity. However, its effectiveness is hindered by challenges in crossing the blood-brain barrier and the risk of off-target organ toxicity. Delivering drugs directly from the nose to the brain through the olfactory or trigeminal nerves bypassing the blood-brain barrier offers enhanced bioavailability and a more precise targeting strategy. To overcome these challenges, we aimed to develop bevacizumab in situ gel loaded mesoporous silica nanoparticles for intranasal delivery and further examine their pharmacokinetic and pharmacodynamic characteristics. The intranasal gel of mesoporous silica nanoparticles loaded with bevacizumab was optimized and formulated using a factorial and quality by design approach. In the case of bevacizumab mesoporous silica nanoparticles, lower particle size and most negative zeta potential were selected as quality target product profiles which is important for drug loading on the mesoporous silica nanoparticles and also transport of these nanoparticles across the nasal mucosa to the brain. A design space with a multidimensional combination of input variables and process parameters has been demonstrated to assure quality. To optimize the design space and achieve the desired quality standards, the base catalyst and surfactant concentration were chosen as the critical process parameters, while particle size and zeta potential were identified as the critical quality attributes. The novel formulation was assessed for physicochemical parameters such as particle size, zeta potential, entrapment efficiency, appearance, color, consistency, and pH. Additionally, studies on in vitro release, ex vivo permeation, stability, nasal toxicity, organ safety, and bioavailability were conducted. The efficacy study was conducted in an orthotopic murine glioblastoma rat model in which C6 Luc cells were instilled in the striatum of the rat's brain. In vivo, bioluminescence imaging of brain tumors was carried out to observe the tumor regression after treatment with the intranasal and intravenous bevacizumab formulation. Biochemical parameters and histopathology were performed for organ safety studies. The optimized intranasal formulation exhibited an average particle size of 318.8nm and a zeta potential of - 14.7mV for the mesoporous silica nanoparticles. The formulation also demonstrated an entrapment efficiency of 91.34% and a loading capacity of 45.67%. Further pharmacokinetic studies revealed that the optimized intranasal bevacizumab formulation achieved a significantly higher brain concentration Cmax = 147.9ng/ml, indicating improved bioavailability compared to rats administered with intravenous bevacizumab formulation (BEVATAS®), which had a Cmax of 127.2ng/ml. Moreover, this nanoparticle formulation entirely mitigated systemic exposure to bevacizumab. Organ safety evaluation of different biochemical parameters and histopathological analyses revealed that the intranasal bevacizumab-treated group was showing less off-target organ toxicity compared to the group treated with intravenous bevacizumab formulation. Subsequently, the efficacy of this nanosystem was evaluated in an orthotopic glioblastoma rat model, monitoring tumor growth over time through in vivo bioluminescence imaging and assessing anti-angiogenic effects. Twenty-one days post-induction, mesoporous silica nanoparticles loaded with bevacizumab in situ gel exhibited a marked reduction in average bioluminescence radiance (4.39 × 103) from day 7 (1.35 × 107) emphasizing an enhanced anti-angiogenic effect compared to the group treated with intravenous bevacizumab formulation which showed a gradual decrease in average bioluminescence radiance (4.82 × 104) from day 7 (1.42 × 107). These results suggest that the proposed novel formulation of mesoporous silica nanoparticles loaded bevacizumab in situ gel could serve as a promising avenue to enhance glioblastoma treatment efficacy, thereby potentially improving patient quality of life and survival rates significantly. Furthermore, the success of this delivery method could open new avenues for treating other neurological disorders, such as Alzheimer's disease, Parkinson's disease, multiple sclerosis, and stroke. By providing effective brain-targeted therapies, this approach has the potential to revolutionize treatment options and improve outcomes for a broad spectrum of neurological conditions.

Cryoprotective effect of magnetic field-assisted freezing in combination with curdlan on myofibrillar protein of Litopenaeus vannamei: Oxidative aggregation, protein structure and thermal stability

To counteract the negative effects of conventional freezing methods on frozen surimi products, the present study investigated the effects of magnetic field (MF) freezing in combination with different amounts of curdlan (CUR) on oxidative denaturation, structural alterations, and thermal stability of myofibrillar protein (MP) in shrimp surimi. The results indicated that the intervention of magnetic fields alone improved the quality of frozen muscle proteins. Under the dual intervention of magnetic field-assisted freezing and CUR, small ice crystals formed with MF6 treatment resulted in significantly lower solubility, turbidity, and mean particle size than the control group (p < 0.05). Moreover, the oxidation of MP was also significantly slowed down by inhibiting the formation of hydrophobic groups and carbonyl groups, maintaining a high content of sulfhydryl groups. MF6 also exhibited a high Ca2+-ATPase activity. The α-helix content, the increase in fluorescence intensity under this condition also tend to make the secondary and tertiary structures of myofibrillar protein more stable. Meanwhile, electrophoretic profiles and CLSM showed that this condition maintains the integrity of the MP. In addition, the MF6 samples also had high protein thermal stability. However, excess CUR reduces the excellence of MP cryoprotection. As a result, MF6 has better protection and improvement effects on protein function, structure and thermal stability, and CUR was also found to have the potential for cryoprotectant development.

Green synthesis of polyphenol-grafted lignin nanoparticles and their application as sustainable anti-acne, antioxidant, and UV-blocking agents

Acne is a persistent infectious skin condition primarily caused by Propionibacterium acne that affects 80 % of teenagers. The rise of antibiotic resistance in P. acnes has led to an increasing interest in exploring alternative antimicrobial agents. This study explored the effects of natural polyphenol (gallic and tannic acid)-grafted lignin nanoparticles on P. acnes and other pathogens causing skin infections. The process involved functionalizing lignin by grafting with gallic acid and tannic acid using laccase, followed by mechanical homogenization to synthesize lignin-gallic acid (LGAL-NPs) and lignin-tannic acid (LTAL-NPs) nanoparticles. LGAL-NPs and LTAL-NPs exhibited average low polydisperse particles of less than 60 nm and increased total phenolic content. Testing against P. acnes, S. aureus, and S. epidermidis showed that the nanoparticles had an MIC of 0.625 mg/mL. The effectiveness of LGAL-NPs and LTAL-NPs against acne-causing bacteria was attributed to their high phenolic content and nanosize. Furthermore, studies on the mechanism of action have revealed the interaction of LGAL-NPs with bacterial surfaces, destabilization of membranes, increase in ROS levels, and reduction of metabolic activity. Molecular docking results indicated that these nanoparticles effectively inhibited bacterial growth and compromised their pathogenic abilities by targeting and disrupting key virulence factors. Additionally, these nanoparticles exhibited antioxidant and UV-protecting properties, making them potentially useful in the cosmetic and pharmaceutical industries for developing skincare products. Their natural, low toxicity, cost-effective nature, and eco-friendly attributes make them a sustainable option for skincare applications.

Using zero nano-valent iron/thin film composite (ZNVI/TFC) membrane for brackish water desalination and purification

This study looked at the use of synthetic Zero Nano-valent Iron (ZNVI) particles in a unique interfacial polymerization technique on a polyamide thin film PA(TF) composite membrane for the treatment and desalination of brackish wastewater. Zero nano-valent iron (ZNVI) particles were created utilizing chemical reduction technique. ZNVI/PA(TF) NCs membrane is the outcome of advancing the PA(TF) membrane by combining with different concentration of ZNVI particles into the organic phase 1,3,5-benzenetricarbonyl trichloride (TMC). ZNVI/PA(TF) NCs membranes and ZNVI particles' surface properties were examined by the use of mechanical activity, contact angle, BET, FTIR, SEM, XRD, zeta potential, TEM analysis, and EDX studies. Using a variety of salt solutions, such as NaCl, Na2SO4, MgSO4, NaHCO3, CaSO4, CaCl2, and MgCl2, the ZNVI/PA(TF) NCs membrane performance towards salt rejection, flux (at varying pressure), anti-fouling activity, and ZNVI particles stability was assessed. This work investigated the removal efficiency of four dyes: methylene blue (MB), methyl orange (MO), Congo red (CR), and malachite green oxalate (MG). The water flux of the pristine PA(TF) membrane improved from 22 to 35 L/m2.h at 15 bar, indicating a 63% flux enhancement and the NaCl rejection was improved from 88.5 to 98.6%, indicating an 11.4% rejection improvement by incorporation of 0.3 wt.% of ZNVI particles into PA(TF) matrix. The ZNVI/PA(TF) NCs membrane's separation performances were evaluated using 5000 mg/L feed solutions of various salts at 15 bar. It was discovered that the water flux and salt rejection are, respectively, 33.4, 33, 32.7, 32, 31, 30 and 29 L/m2.h for CaSO4, MgSO4, Na2SO4, NaCl, CaCl2, MgCl2, and NaHCO3, and 97.4, 97, 96.5, 96, 94, 93.2, and 92.8%. It demonstrates that the flux recovery ratio (FRR) of the ZNVI/PA(TF) NCs membrane is greater than that of pristine PA(TF) (78%), coming in at 87%. High stability and fixing of the ZNVI particles on the modified membrane surface is indicated by the low overall ZNVI particles release rate over the course of the 10-day experiment.

Significant Improvement in Magnetorheological Performance by Controlling Micron Interspaces with High Permeability Submicron Particles.

The shear yield strength, sedimentation stability and zero-field viscosity of magnetorheological fluids (MRFs) are crucial for practical vibration damping applications, yet achieving a balanced combination of these performances remains challenging. Developing MRFs with excellent comprehensive performance is key to advancing smart vibration damping technologies further. Theoretically, incorporating a multiscale particle system and leveraging synergistic effects between their can somewhat enhance MRFs' performance. However, this approach often faces issues such as insignificant increases in shear yield strength and excessive rise in zero-field viscosity. In response, this study employs a DC arc plasma method to synthesize a high magnetic permeability, low coercivity submicron FeNi particles, and further develops a novel CIPs-FeNi bidisperse MRFs. The introduction of submicron FeNi particles not only significantly enhances the shear2019 yield strength of MRFs under low magnetic fields but also promotes improvements in sedimentation stability and redispersibility without excessively increasing viscosity. Comprehensive performance analysis is conducted to explore the optimal content ratio, and detailed mechanisms for the enhancement of performance are elucidated through analysis of parameters such as chain-like structure, magnetic flux density and friction coefficient. Most importantly, the superior comprehensive performance combined with straightforward fabrication methods significantly enhances the engineering applicability of the CIPs-FeNi bidisperse MRFs.

Silver and Copper Nanoparticles Hosted by Carboxymethyl Cellulose Reduce the Infective Effects of Enterotoxigenic Escherichia coli:F4 on Porcine Intestinal Enterocyte IPEC-J2.

Zero-valent copper and silver metals (Ms) nanoparticles (NPs) supported on carboxymethylcellulose (CMC) were synthesized for treating Enterotoxigenic Escherichia coli fimbriae 4 (ETEC:F4), a major cause of diarrhea in post-weaned pigs. The antibacterial properties of Cu0/CMC and Ag0/CMC were assessed on infected porcine intestinal enterocyte IPEC-J2, an in vitro model mimicking the small intestine. The lower average particle size (218 nm) and polydispersity index [PDI]: 0.25) for Ag0/CMC, when compared with those of Cu0/CMC (367 nm and PDI 0.96), were explained by stronger Ag0/CMC interactions. The minimal inhibitory concentration (MIC) and half inhibitory concentration (IC50) of Ag0/CMC were lower in both bacteria and IPEC-J2 cells than those of Cu0/CMC, confirming that silver nanoparticles are more bactericidal than copper counterparts. IPEC-J2, less sensitive in MNP/CMC treatment, was used to further investigate the infective process by ETEC:F4. The IC50 of MNP/CMC increased significantly when infected IPEC-J2 cells and ETEC were co-treated, showing an inhibition of the cytotoxicity effect of ETEC:F4 infection and protection of treated IPEC-J2. Thus, it appears that metal insertion in CMC induces an inhibiting effect on ETEC:F4 growth and that MNP/CMC dispersion governs the enhancement of this effect. These results open promising prospects for metal-loaded biopolymers for preventing and treating swine diarrhea.

Proton Predominance At UHE Cosmic Rays Through Analysis Of Different Mass Composition Models

Recently, detection of giant (1017 to 1020eV ) and super giant ( Ep &gt;1020 eV ) air showers is gaining importance as the investigation of EAS in these energy ranges is expected to give necessary information on characteristics of high energy nuclear interactions in one hand and for solving the astrophysical problem of Cosmic Ray origin , beyond the Greisen-Zatsepin-Kuzmin cut-off energy near 1020 eV. Due to the very low Cosmic Ray flux in the UHE range ( &gt; 1017 eV ) direct measurement by balloons or satellites are not possible. The experimental approach realized conventionally uses extended ground-based installations catching data of the induced air showers . An alternative approach is to use a low cost particle detector array called mini-array for detecting UHE cosmic rays by Linsley’s method of arrival time measurement. The miniarray consist of eight plastic scintillation counters covering an area of 2m2 operating for detecting EAS particles of primary energy 1017 -1018 eV based on Linsley’s method of arrival time measurement. An optical detector (5 inch diameter PMT) has been installed at the centre of the miniarray to record the associated optical Cerenkov pulse produced by the ultra-relativistic shower particles in the atmosphere with an aim to derive primary mass composition above 1017 eV. Optical pulses are recorded in one channel of the DSO and the stored data in the wave form memory are transferred to the computer via GPIB interface. The particle detector pulses are triggered with the help of trigger circuit and recorded through other channel of the DSO and transferred to the same DSO. However, the data are subjected to large fluctuation both in particle detection and optical photon detection. Primary energy is estimated through the parameter shower size which is also indirectly measured from a small sample of shower front using miniarray data. Mass composition estimated indirectly relies on simulation model. On the basis of pulse height distribution measurement, the inferred mass composition is predominantly protons, with a tendency of mass composition becoming lighter at the highest energies.

An experimental setup for studying conduction and radiation heat transfer in a rotary drum

This study presents the development of a novel heating system that aims to bridge the experimental gap for analyzing both radiation and conduction heat transfer in a rotary drum. The experiments were conducted by loading the drum with 4 mm silica glass beads at varying fill levels (10 %, 17.5 %, and 25 %) and rotation rates (2, 5, and 10 RPM), and monitoring the temperature evolution with an infrared camera. Higher fill levels resulted in lower average particle bed temperatures, while rotation rate influenced the contact time between particles and the drum wall and the exposure to radiative heat. A rotation rate of 5 RPM resulted in the highest average bed temperature due to optimal contact and exposure time for conduction and absorption of radiative heat, respectively. Thus, a balance between adequate particle mixing and optimal contact/exposure time is crucial for maximizing heat transfer efficiency in rotary drums exhibiting conduction and radiation.

Influence of solvent selection and RESS processing conditions on formation of a praziquantel-malonic acid cocrystal in supercritical CO2

Praziquantel (PZQ) is an anthelmintic drug with low solubility, therefore cocrystallization and particle size reduction is desirable to improve bioavailability. In this study, a PZQ-malonic acid cocrystal was micronized by rapid expansion of supercritical solution (RESS). Due to low solubility in scCO2, four cosolvents were screened as RESS modifiers. While addition of acetone or THF yielded mixtures of PZQ and its cocrystal, MeOH and EtOH produced pure cocrystal. Impact of pressure (15–30 MPa), temperature (35–55 °C), and cosolvent loading (3–10 volumes) on phase-purity, yield, and particle size were investigated. Adding cosolvent to RESS facilitated dissolution of cocrystal formers in scCO2 and crystallization of the cocrystal with yields up to 68.5 wt% and particle size as low as 600 nm. Results show that for APIs with low solubility in scCO2, cosolvent-modified RESS is a suitable approach for simultaneous crystallization and micronization.

Impact of Interplanetary Shock on Thermospheric Cooling Emission: A Case Study

AbstractInterplanetary (IP) shock is one of the most common phenomena that controls the shape and size of the magnetosphere. It affects the whole magnetosphere‐ionosphere‐thermosphere (MIT) system. We utilized the NO 5.3 m radiative emission, as observed by SABER (Sounding of the Atmosphere using Broadband Emission Radiometry) onboard NASA's TIMED (Thermosphere Ionosphere Mesosphere Energetics Dynamics) satellite, to investigate its response to fast forward shock during 26 January 2017. The high latitude NO emission exhibits a strong enhancement (three times with respect to pre‐event value) during IP shock within 5 hr of onset. We analyzed both the energy dissipation sources and subsequent chemical mechanisms. The Field‐Aligned‐Current observations from Active Magnetosphere and Planetary Response Experiment (AMPERE), EISCAT measurements of Pederson conductivity and the defense Meteorological Satellite Program (DMSP F18) calculated hemispheric power demonstrate a strong intensification. The low energy particle precipitation from DMSP F18 spacecraft shows an early enhancement for energy less than 1 keV. The particle flux of higher energy responds later which remained elevated for longer duration. The thermospheric density and temperature also experience significant variation during IP shock. The NO molecule and temperature displayed an early enhancement. NO density increased by an order of magnitude with respect to the pre‐event value. About 20 increase is noticed in the temperature variation. The atomic oxygen and atomic nitrogen illustrate an early depletion during IP event. The enhanced response of NO cooling to IP shock can be attributed to the combined effects of energy input and subsequent chemical mechanisms.

Creating High Yield Stress Particle-Laden Oil/Water Interfaces Using Charge Bidispersity.

Interfacial engineering has been increasingly used to stabilize Pickering emulsions in commercial products and biomedical applications. Pickering emulsion stabilization is aided by interfacial viscoelasticity; however, typically the primary means of stabilization are steric hindrances between high surface concentration shells of particles around the drops. In this work, the concept of creating large interfacial viscoelastic yield stresses with low particle surface concentrations (<50%) using bidisperse charged particle systems is tested to evaluate their potential efficacy in emulsion stabilization. To explore this hypothesis, interfacial rheology and visualization experiments are conducted at o/w interfaces using positively charged amidine, negatively charged carboxylate, and negatively charged sulfate-coated latex spheres and compared to a model based on interparticle forces. Bidisperse particle systems have been observed to create more networked structures than monodisperse systems. For surface concentrations of <50%, bidisperse interfaces created measurable viscoelastic moduli ∼1 order of magnitude larger than monodisperse interfaces. Furthermore, these interfaces have measurable yield stresses on the order of 10-4 Pa·m when monodisperse systems have none. Bidispersity impacts surface viscoelasticity primarily by increasing the overall magnitude of attraction between particles at the interface and not due to changes in the microstructure. The developed model predicts the relative surface fraction that creates the largest moduli and shows good agreement with the experimental data. The results demonstrate the ability to create large viscoelastic moduli for small surface fractions of particles, which may enable stabilization using fewer particles in future applications.