1、Green chemistry in coatings: Terpene based acrylates as substitutes for

Terpene-based acrylic monomers provide a sustainable and environmentally friendly alternative to conventional acrylic monomers. Due to their low volatility, they can be directly used in high-solid UV coating systems.

2、Nitrogen‐Containing Polymers Derived from Terpenes: Possibilities and

Particularly, nitrogen-containing polymers, such as important commercial polyamides, polyurethanes, polyureas, and epoxy resins, can be potentially replaced with terpene-derived analogous materials.

3、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.

Products by Application

Compatible with polyolefins such as PP and PE, our terpene resins significantly modify optical properties such as transparency and gloss, adhesiveness to substrates, heat-sealing properties, and injection molding flow properties.

Study on the Film Formation of Terpene Resins

Terpene resins are extensively used in coatings, adhesives, and composites. In coatings, their excellent adhesion and weather resistance make them ideal for automotive and construction applications.

Terpenes and Terpenoids: Building Blocks to Produce Biopolymers

The achievement of catalytic systems able to polymerize the natural monomer counterparts, such as terpenes or terpenoids, is still a challenge in the development of polymers with good mechanical, thermal, and chemical properties.

Terpene derivative

Herein, we propose a terpene-modified polysiloxane-based polyurethane that solves the above-stated problems. In the presence of the Karstedt catalyst, isobornyl acrylate (IBOA) was introduced into the branch of hydrogen-containing silicone oil (HSO) through the hydrosilylation reaction.

Improving the Performance of Photoactive Terpene

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

Green chemistry in coatings: Terpene based acrylates as

Due to their low volatility, they can be directly used in high-solid UV coating systems. The wide variety of monoterpenes allows for tailoring the properties of the acrylates by selecting the appropriate raw material, enabling them to match or even exceed the performance of petrochemical monomers.

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.

In modern industry, coatings serve as critical surface treatment materials, directly impacting product lifespan and aesthetics. With advancements in technology, the development of eco-friendly materials has become a research focus. Terpene resins, a type of synthetic resin with unique properties, have garnered attention in recent years. This article explores whether terpene resins can serve as raw materials for polyethylene (PE) coatings and analyzes their potential applications.

I. Basic Properties of Terpene Resins

Terpene resins are high-molecular-weight compounds containing multiple cyclic carbon structures. They exhibit excellent chemical stability, mechanical strength, and heat resistance. Their molecular structure endows them with broad application potential across various fields. Due to their distinct chemical properties, terpene resins show significant promise in developing high-performance coatings.

II. Composition and Requirements of PE Coatings

Polyethylene (PE) coatings primarily consist of PE resin, pigments, fillers, solvents, and additives. These components collectively ensure good adhesion, wear resistance, weatherability, and gloss. For PE coatings, factors such as environmental friendliness, cost-effectiveness, and ease of application must also be considered alongside basic physicochemical properties.

III. Feasibility of Using Terpene Resins as PE Coating Raw Materials

1. Chemical Compatibility: Terpene resins share structural similarities with PE resins, resulting in good chemical compatibility. This allows them to be blended without adverse reactions, ensuring the stability and durability of the coating.

2. Performance Enhancement: Incorporating terpene resins may improve the overall performance of PE coatings. For example, they could enhance temperature resistance, chemical corrosion resistance, and anti-aging properties. Additionally, their toughening effects could improve the impact resistance of PE coatings.

3. Eco-Friendliness: Terpene resins, derived from renewable biomass or petroleum sources, have minimal environmental impact during production and processing. Using them in PE coatings could reduce pollution and ecological harm.

4. Cost-Effectiveness: Terpene resins are relatively inexpensive and widely available, lowering the cost of PE coatings and facilitating industrial adoption.

IV. Application Prospects of Terpene Resins in PE Coatings

While terpene resins offer advantages as PE coating ingredients, technical and economic challenges remain. For instance, modification processes for terpene resins need further optimization to suit diverse applications. Extensive experimentation and research are also required to maximize the synergistic effects between terpene resins and PE resins.

terpene resins hold promise as raw materials for PE coatings. With appropriate modifications and optimizations, they could enhance performance and reduce costs. overcoming technical hurdles and market challenges is essential. As research progresses and technology advances, terpene resins are poised to play a more significant role in the future of coatings.