1、Preparation of High

Lewis acid-based deep eutectic solvents (DESs) were applied for catalyzing the polymerization of β -pinene to obtain high-quality terpene resin for the first time.

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

In this study, it was aimed to synthesize and model the natural terpene-rosin phenolic resin (TRPR) by (a) reacting terpene and resin acids together in a single step without predistillation and (b) using an environmentally friendly and reusable ion-exchange catalyst (Amberlyst15).

3、Terpene

Ionic liquids (ILs) were explored to solve the challenges associated with amines. ILs are nonflammable and have low vapor pressure, which makes them sustainable for high-temperature applications. CO 2 solubility in ILs is mainly governed by the free volume and the interactions between CO 2 and ions during absorption.

Polymerization of α

A series of low-cost Lewis acidic deep eutectic solvents (DESs) was synthesized and applied for the first time for catalyzing the polymerization of α-pinene to produce terpene resins.

Terpene resin T

Solvent-based adhesives for SBR rubber, natural rubber and acrylic. Others are widely used in: high temperature tape, electronic tape, printing ink, coating and other industries.

Preparation of High

<p>Lewis acid-based deep eutectic solvents (DESs) were applied for catalyzing the polymerization of <i>β</i>-pinene to obtain high-quality terpene resin for the first time.

多萜_百度百科

多萜（terpene resin）又称萜烯树脂或多萜树脂，是由松节油、β-蒎烯、萜二烯等萜烯类聚合制得的黏稠液至脆性固体的热塑性树脂，其是一种植物天然香料，属烃类树脂，常用作涂料助剂等化工产品。

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.

TERPENE RESINS IN PRESSURE SENSITIVE ADHESIVES

Terpene resins are primarily synthesized by a cationic polymerization process where a suitable solvent and a Lewis acid catalyst are employed.

Terpene based resin TC

Solvent-based adhesives for SBR rubber, natural rubber and acrylic. Others are widely used in: high temperature tape, electronic tape, printing ink, coating and other industries.

In modern industry, the rapid advancement of chemical engineering and materials science has underscored the growing importance of terpene resin co-solvents as specialized chemicals. Terpene resin, a high-molecular-weight compound derived from natural plants, boasts unique chemical and physical properties that have unlocked broad application potential across various fields. This article delves into the concept, classification, preparation methods, performance characteristics, and applications of terpene resin co-solvents in coatings, adhesives, lubricants, and other domains, while also forecasting future development trends.

I. Concept and Classification of Terpene Resin Co-solvents

Terpene resin co-solvents are solvents primarily composed of terpene resins, designed to enhance the solubility of other organic solvents and improve material processing performance. Based on their origin and chemical structure, they can be divided into two categories: natural terpene resins and synthetic terpene resins. Natural terpene resins typically originate from plant sources such as turpentine oil and camphor oil, whereas synthetic terpene resins are produced through chemical synthesis.

II. Preparation Methods for Terpene Resin Co-solvents

The preparation of terpene resin co-solvents involves diverse methods, including distillation, extraction, and polymerization. Distillation entails heating to evaporate volatile components from terpene resin, followed by condensation to collect purified products. Extraction relies on mixing terpene resin with other solvents and separating components based on solubility differences. Polymerization leverages functional groups in terpene resin molecules to form polymers with specific properties.

III. Performance Characteristics of Terpene Resin Co-solvents

Terpene resin co-solvents exhibit distinctive properties that enable their widespread use:

1. Low Volatility: Suitable for low-temperature applications, reducing energy consumption.
2. Excellent Solubility and Penetration: Effectively dissolve a range of organic solvents and substances.
3. Stability and Corrosion Resistance: Maintain performance under harsh conditions.

IV. Applications in Coatings, Adhesives, and Lubricants

Terpene resin co-solvents play critical roles in multiple industries:

• Coatings: Enhance gloss, hardness, and wear resistance while reducing viscosity for easier application.
• Adhesives: Improve bonding strength and weather resistance, extending product lifespan.
• Lubricants: Optimize low-temperature fluidity and minimize sludge/carbon buildup.

V. Future Development Trends

Driven by technological progress and stricter environmental standards, terpene resin co-solvents hold promising prospects:

• Innovation: Development of more efficient, eco-friendly formulations to meet industrial demands.
• Sustainability: Advances in biotechnology may position natural terpene resins as a sustainable source, aligning with green chemistry principles.

As a vital chemical additive, terpene resin co-solvents offer expansive potential in chemical engineering and materials science. Research and development in this field not only elevate product quality and performance but also promote environmental protection and resource sustainability. With ongoing technological advancements and market growth, terpene resin co-solvents are poised to play an even greater role across diverse sectors.