1、A Novel Approach to the Development of Natural Resin‐Based Biopolymer

Natural resin (NR) is secreted by pine trees, and it is a great monomer source for synthesizing biopolymers. The objective of this study is to produce terpene rosin phenolic resin (TRPR) from NR, turpentine, and phenol by applying a novel polymerization technique.

2、Improving the Performance of Photoactive Terpene

Photocurable liquid formulations have been a key research focus for the preparation of mechanically robust and thermally stable networks. However, the development of renewable resins to replace petroleum-based commodities presents a great challenge in the field.

3、Research progress on modification of phenolic resin

In recent years, more and more researchers have focused on the discussion of the properties of modified phenolic resins and gradually ignored the research on the synthesis processes that can affect the molecular structure and properties of phenolic resins.

4、Preparation of High

Under the optimized reaction conditions (10 g of β -pinene, 3 g of DES catalyst, reaction temperature 0 °C, and reaction time 4 h), the softening point of the obtained terpene resin was as high as 142.0 °C (global method), and the terpene resin yield reached 94.2%.

5、MODELING AND OPTIMIZATION BY THE EXPERIMENTAL DESIGN OF THE SYNTHESIS

By following the theoretical results obtained through modeling, we synthesized a newterpene phenolic resin, prepared by oligomerization of terpene and phenol. The resinsynthesis was characterized by Fourier transform (FTIR), 1 H, 13 C analyzes.

Introduction of Terpene Phenolic Resin

Terpene Phenolic Resin is derived from renewable resources and has low VOC (volatile organic compound) emissions, making it a more environmentally friendly option compared to other resin types.

Terpene

This modification not only preserves the inherent advantages of phenolic resins but also endows them with superior thermal stability, electrical insulation, and mechanical strength, making terpene-modified phenolic resins an ideal choice for high-performance applications.

Improving the Performance of Photoactive Terpene

ABSTRACT: Photocurable liquid formulations have been a key research focus for the preparation of mechanically robust and thermally stable networks. However, the development of renewable resins to replace petroleum-based commodities presents a great challenge in the field.

Formulation Approaches for Polyterpene Resins, SBS Elastomers and

Key formulation approaches for polyterpene resins, SBS elastomers, and petroleum resins. This article explores the properties of terpene resins, including those based on α-pinene, highlighting their light colour, low odour, and excellent compatibility.

Structural and thermal behavior of a novel phenolic resin and its

NaOH and trisilanolphenyl polyhedral oligomeric silsesquioxane (TPOSS) were used as catalysts to synthesize a novel boron-containing phenolic resin (TBPR). NaOH/TPOSS results in more para -methylene linkage in TBPR structure, which is the key to the remarkable initial decomposition temperature.

In the vast realm of modern materials science, terpene resin and phenolic resin stand out as two critical synthetic resins, each playing distinct roles and functions. These resins exhibit significant differences in their properties but demonstrate exceptional performance in their respective application fields. This paper aims to explore the performance characteristics of these two resins in depth, providing valuable insights for researchers and engineers in related fields.

Terpene Resin is a thermosetting polymer with a highly cross-linked structure, primarily characterized by its excellent heat resistance and chemical resistance. The presence of numerous carbon-carbon double bonds in its molecular structure allows terpene resin to maintain stable chemical properties under high temperatures. This feature has led to its widespread use in applications such as electronics, electrical insulation materials, and thermosetting coatings. Additionally, terpene resin boasts superior mechanical properties, including high hardness and impact resistance, making it an ideal raw material for manufacturing high-performance composites.

Phenolic Resin, on the other hand, is a thermosetting phenolic resin renowned for its exceptional electrical insulation properties and high mechanical strength. Its molecular structure, rich in hydroxyl and ether groups, enables rapid curing when exposed to heat or electric fields. Phenolic resin is extensively employed in electronics, electrical insulation materials, and thermosetting coatings. Furthermore, its excellent wear resistance and corrosion resistance have made it a popular choice for applications such as wear-resistant floor materials and anticorrosive coatings.

Performance Comparison From a performance standpoint, terpene resin and phenolic resin each have unique advantages. Terpene resin is celebrated for its outstanding heat and chemical resistance, making it suitable for applications requiring long-term stability, such as electronic and electrical equipment. In contrast, phenolic resin is favored for its superior electrical insulation and mechanical strength, finding utility in scenarios demanding high strength and wear resistance, such as wear-resistant flooring and anticorrosive coatings.

Limitations both resins have drawbacks. While terpene resin offers good heat resistance, it tends to degrade at high temperatures, limiting its use in extreme thermal environments. Phenolic resin, despite its excellent electrical properties, exhibits relatively lower mechanical strength and is prone to deformation under external forces.

Practical Applications In practice, terpene resin and phenolic resin are often combined based on specific requirements. For instance, terpene resin may serve as the primary component in high-performance composites to enhance mechanical properties, while phenolic resin could be the go-to choice for wear-resistant flooring to improve durability. Through optimized formulation design and process control, the优势互补 (complementary advantages) of these resins can be effectively leveraged to meet diverse industry needs.

terpene resin and phenolic resin are invaluable resources in modern materials science, each with distinctive performance traits. When selecting and utilizing these resins, it is crucial to thoroughly understand their properties and application scopes to better fulfill practical demands. With advancements in technology and ongoing research in new materials, it is anticipated that more innovative resins will emerge, opening up broader possibilities for the development of materials science.