Category Ranking
98%
Total Visits
921
Avg Visit Duration
2 minutes
Citations
20
Article Abstract
Polymer matrix wave transparent composites are used in a variety of high-speed communication applications. One of the applications of these involves making protective enclosures for antennas of microwave towers, air vehicles, weather radars, and underwater communication devices. Material performance, structural, thermal, and mechanical degradation are matters of concern as advanced wireless communication needs robust materials for radomes that can withstand mechanical and thermal stresses. These polymer composite radomes are installed externally on antennas and are exposed directly to ambient as well as severe conditions. In this research, epoxy resin was reinforced with a small amount of quartz fibers to yield an improved composite radome material compared to a pure epoxy composite with better thermal and mechanical properties. FTIR spectra, SEM morphology, dielectric constant (Ɛ) and dielectric loss (δ), thermal degradation (weight loss), and mechanical properties were determined. Compared to pure epoxy, the lowest values of Ɛ and δ were 3.26 and 0.021 with 30 wt.% quartz fibers in the composite, while 40% less weight loss was observed which shows its better thermal stability. The mechanical characteristics encompassing tensile and bending strength were improved by 42.8% and 48.3%. In high-speed communication applications, compared to a pure epoxy composite, adding only a small quantity of quartz fiber can improve the composite material's dielectric performance, durability, and thermal and mechanical strength.
Download full-text PDF |
Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10610360 | PMC |
| http://dx.doi.org/10.3390/polym15204133 | DOI Listing |
Publication Analysis
Top Keywords
Similar Publications
We demonstrate a rapidly tunable waveplate based on a rotating z-cut quartz plate in a double-pass configuration. In contrast to previous single-pass implementations, where angular rotation of birefringent crystals causes significant beam path displacement, we show that the double-pass geometry effectively suppresses beam walk-off, reducing lateral shifts to below 10 m, which is stable enough to have a fiber coupling. We present a full theoretical description of the polarization changes using Jones matrix calculations and verify it through polarization-resolved measurements.
View Article and Find Full Text PDFNoncontact Fiber Optic Probe for Clinical Applications of Raman Spectroscopy.
Appl Spectrosc
July 2025
Vanderbilt Biophotonics Center, Nashville, Tennessee, USA.
Clinical applications of Raman spectroscopy (RS) typically rely on fiber optic probes that directly interface with the tissue site. These devices are designed with small diameters, enabling them to navigate narrow body cavities and seamlessly integrate into routine medical instruments. However, the performance of conventional RS fiber probes suffers during noncontact operation due to decreased collection efficiency and a larger laser spot size that restricts spatial precision.
View Article and Find Full Text PDFA Parametric Study of Epoxy-Bonded CF/QF-BMI Composite Joints Using a Method Combining RBF Neural Networks and NSGA-II Algorithm.
Polymers (Basel)
June 2025
School of Advanced Manufacturing, Nanchang University, Nanchang 330029, China.
The epoxy-bonded joint between carbon-fiber-reinforced bismaleimide (CF-BMI) and quartz-fiber-reinforced bismaleimide (QF-BMI) composites can meet the structure-function integration requirements of next-generation aviation equipment, and the structural design of their bonding zones directly affects their service performance. Hence, in this study, the carbon-fiber-reinforced bismaleimide composite ZT7H/5429, the woven quartz-fiber-reinforced bismaleimide composite QW280/5429, and epoxy adhesive film J-116 were used as research materials to investigate the influence of the bonding area size on the mechanical properties, and this study proposes a novel design methodology combining radial basis function (RBF) neuron machine learning with the NSGA-II algorithm to enhance the mechanical properties of the bonded components. First, a finite element simulation model considering 3D hashin criteria and cohesion was established, and its accuracy was verified with experiments.
View Article and Find Full Text PDFEstimation of compressive strength of ultra-high performance lightweight concrete (UHPLC) using neural network.
PLoS One
July 2025
School of Electrical Engineering and Automation, Harbin Institute of Technology, Harbin, Heilongjiang, China.
High strength and lightweight are key trends in concrete development. Achieving a balance between these properties to produce high structural efficiency (strength-to-weight ratio) concrete is challenging due to the complex relationship between compressive strength and material components. In this study, two artificial neural network (ANN) models-the BP and Elman networks were used to predict the compressive strength of ultra-high-performance lightweight concrete (UHPLC), based on a robust database of 115 test datasets from previous studies.
View Article and Find Full Text PDFThe impact of using two fiber-reinforced composites with different placement methods on the flexural strength of two resin materials: an in vitro study.
BMC Oral Health
July 2025
Department of Dental Materials Science, Digital Prosthodontic Department, School and Hospital of Stomatology, China Medical University, Shenyang, China.
Background: This in vitro study assessed the influence of using two types of fiber-reinforced composite with different placement methods on the flexural strength of two resin materials.
Methods: Specimens were fabricated using two FRC products (QUARTZ SPLINT UD(UD) / WOVEN (WO)) with two resin composites (BEAUTIFIL II (BT II) and BEAUTIFIL Flow Plus (BF+)). Seven placements were employed to prepare specimens for each composite, including one control group without FRCs, two using UD, and the other four using WO.