Group 1 - The article discusses the characteristics and requirements of 5G communication technology, emphasizing the need for high-frequency electromagnetic waves to meet the increasing data transmission demands [4][5][6]. - It highlights the Shannon theorem, which relates signal transmission capacity to bandwidth and signal-to-noise ratio, indicating that higher frequencies can enhance data transmission rates [5][6]. - The article outlines the specific material requirements for circuit substrates used in high-frequency communication, including low dielectric constant and low dielectric loss to minimize signal attenuation [7][8][10]. Group 2 - The preparation and performance study of fluorinated thermosetting polyphenylene ether (PPO) is presented, focusing on the effects of physical and chemical modifications on its dielectric properties [11][12][14]. - The article details the synthesis methods for modified PPO, including physical blending and chemical modification, and their impact on the material's thermal and dielectric performance [12][13][14]. - It discusses the dielectric constant and loss of various modified PPO samples, indicating that the introduction of fluorinated groups can enhance dielectric performance [22][38]. Group 3 - The article examines the preparation and performance of hydrocarbon-based thermosetting polyphenylene ether, detailing the structural characterization and curing studies [25][30][31]. - It presents the thermal properties of different hydrocarbon-modified PPOs, noting the influence of curing conditions on their thermal stability and mechanical properties [31][35]. - The dielectric performance of hydrocarbon-modified PPOs is analyzed, showing variations in dielectric constant and loss based on the type of hydrocarbon modification [37][38]. Group 4 - The article explores the application of modified boron nitride/thermosetting polyphenylene ether composites in circuit boards, emphasizing their thermal and dielectric properties [40][58]. - It discusses the impact of filler content on the thermal conductivity and mechanical strength of the composites, indicating that optimal filler levels can enhance performance [54][63]. - The study highlights the microstructural characteristics of the composites, demonstrating effective dispersion of boron nitride within the polymer matrix [61][62].