1、Improving the Performance of Photoactive Terpene

Resin formulations based on biobased terpenes were investigated to offer a simple, scalable, and environmentally friendly route for rapid photocuring.

2、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.

3、Sustainable antimicrobial and antibiofilm strategies: Monoterpene

We investigated natural antibacterial agents, particularly monoterpenes, to develop antimicrobial acrylate monomers and assess whether their efficacy is maintained in polymer form.

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%.

The Applications and Functions of Terpene Resins

Terpene resins, natural polymer compounds extracted from plants, have demonstrated vast application potential across multiple fields due to their unique chemical structures and physical properties.

Synthesis and Application Progress of Terpene

The synthesis and application of terpene-based epoxy resin, terpenyl-cyclic carbonate, terpene-based polyurethane and other terpene-based polymers are reviewed.

Application of Terpenoid Compounds in Food and Pharmaceutical

In pharmaceutical products, terpenes, especially limonene and elemene, have strong biological activity that reduces the mitosis of tumor cells, induces tumor cell apoptosis, and inhibits tumor cell growth. However, the low yield of terpenes limits its application.

Preparation of High

β‐Pinene is able to be polymerized to obtain terpene resin. Terpene resin is a non‐toxic polymer that is chemically inert to most substances and has a wide range of industrial applica.

Improving the Performance of Photoactive Terpene

With these principles in mind, we describe a simple yet efective approach to generating renewable resin formulations based on a modified terpenoid alcohol. The biobased resins were accessed via solvent-free methods to aford photosets with adjustable thermomechanical properties.

TERPENE RESINS IN PRESSURE SENSITIVE ADHESIVES

Terpene-based resins constitute a major portion of tackifiers, besides rosin esters, derived from renewable resources. The diverse chemistry along with their compatibility with various polymers used in the adhesive industry makes terpene resins suitable for a variety of adhesive applications.

Terpene resins, as natural macromolecular compounds, have garnered significant attention due to their unique chemical structures and biological activities. From ancient medicinal applications to modern industrial uses, terpene resins demonstrate irreplaceable roles across diverse fields.

The primary efficacy of terpene resins lies in their excellent biocompatibility and biodegradability. Due to their molecular structure, which contains numerous carbon-carbon double bonds, terpene resins can effectively promote cell growth and repair, offering broad application prospects in the medical field. For instance, in tissue engineering, terpene resins serve as scaffold materials, providing essential mechanical support and biosignal transmission to enhance cell adhesion and proliferation. Additionally, terpene resins exhibit strong antibacterial properties, inhibiting the growth of various bacteria, which makes them valuable in manufacturing medical supplies such as bandages and dressings.

In environmental protection, terpene resins also reveal unique value. Their biodegradability allows them to decompose into carbon dioxide and water, minimizing environmental impact. This characteristic positions terpene resins as green chemical products, critical for advancing sustainable development. In plastic recycling, terpene resins showcase potential applications. With superior thermal and chemical stability, they can modify plastics to improve performance. terpene resins can be produced through microbial fermentation, enabling resource circularity.

Beyond these applications, terpene resins are widely used in coatings, adhesives, and lubricants. These products often require strong adhesion, durability, and wear resistance, all of which terpene resins satisfy. For example, in coatings, terpene resins enhance gloss and coverage, creating more aesthetically pleasing and durable finishes. In adhesives, they provide robust bonding strength and aging resistance, ensuring product longevity. In lubricants, terpene resins serve as ideal base materials due to their low friction coefficients and excellent oxidation resistance.

The applications of terpene resins extend further. As scientific technology advances, researchers continue to explore their novel functions and uses. For instance, certain terpene resins have shown antiviral and antitumor potential, opening new avenues in biomedicine. Additionally, with the development of nanotechnology, terpene resins are being incorporated into nanocomposites, exhibiting exceptional mechanical and electrical properties.

as a versatile macromolecular material, terpene resins hold vast application prospects in biomedicine, environmental protection, industry, and beyond. With ongoing scientific progress, terpene resins are poised to play increasingly unique roles, contributing significantly to human society. In the future, we anticipate terpene resins will unveil further innovative applications, enhancing human life with their remarkable value.