Pine-Derived Chemical Market - Forecasts from 2024 to 2029

Pine-Derived Chemical Market - Forecasts from 2024 to 2029


The pine-derived chemical market is evaluated at US$10.539 billion for the year 2022 and is projected to grow at a CAGR of 4.65% to reach a market size of US$15.278 billion by the year 2029.

Pine-derived chemicals are bio-based renewable chemicals obtained from the pine tree. The carbonization of wood and the distillation of oleoresin provide these compounds. Additionally, the bulk of distilled goods is made from stumps, gum, sulfate pulp byproducts, and logs.

Chemicals derived from pine trees are obtained as byproducts of the pulping process in the form of crude sulfate turpentine and crude tall oil during the papermaking process. The wood carbonization process produces products such as creosote, charcoal, methanol, essential oils, tannin, phenol, and medicament. Furthermore, adhesives, resins, surface coatings, printing inks, soaps and detergents, plasticizers, and aroma compounds all include pine-derived substances.

MARKET TRENDS:

Several important factors drive the growth and development of the pine-derived chemical industry. One important factor is the increased demand from consumers for environmentally friendly and sustainable products, which has sparked interest in bio-based substitutes for chemicals obtained from petroleum. Pine trees are widely distributed around the globe and provide a sustainable and eco-friendly source for the production of terpenes, rosin, and derivatives of tall oil, among other compounds. These compounds made from pine are used in many different sectors, including adhesives, flavors, scents, paints, coatings, and medications.

Furthermore, the creation of superior pine-derived compounds with improved purity and performance characteristics is made possible by technical breakthroughs in extraction, purification, and processing procedures. Numerous significant factors drive the expansion and advancement of the chemical industry generated from pine. A significant contributing aspect is the growing consumer demand for sustainable and eco-friendly products, which has generated interest in bio-based alternatives to petroleum-based chemicals.

Pine trees are found all over the world and offer a sustainable and environmentally beneficial way to produce terpenes, rosin, and tall oil derivatives, among other chemicals. These pine-derived chemicals find use in a wide range of industries, such as adhesives, flavors, fragrances, paints, coatings, and pharmaceuticals. Furthermore, the creation of superior pine-derived compounds with improved purity and performance characteristics is made possible by technical breakthroughs in extraction, purification, and processing procedures.

MARKET DRIVERS:

An increase in applications of pine chemicals across industries is anticipated to drive the market.

The pine-derived chemicals market is largely driven by rising demand for products in the adhesive, paints and coatings, building, and healthcare industries. The increased emphasis on natural and environmentally friendly products that result in reduced CO2 emissions is fueling the product demand. Tall oil rosins offer a wide range of applications in the building sector. Owing to their durability and resilience to abrasion, compression, and weather, these materials are utilized as binders in cement, pavement marking, and other diverse applications. According to the Italian construction association, Associazione Nazionale Costruttori EdilI (ANCE), investment in the construction industry is anticipated to rise, further fueling the market.
Rising CO2 emitted by natural gas might propel the market growth.

Increasing CO2 emissions from natural gas and crude oil, as well as increasingly strict environmental regulations, are some of the causes that have prompted the firms to make a sustainable decision which in turn fuels the market. “The Crude Tall Oil Value Chain: Global Availability and the Influence of Regional Energy Policies,” research published in 2020 by Pine Chemicals in The Journal of Cleaner Production, projects an 8% shortage of crude tall oil (CTO) global availability for all uses by 2030. This shortfall, according to the study, is attributable to the increased demand for CTOs for transportation-related biofuels. As a result, the manufacturing of pine-derived bio-based compounds will increase.

Furthermore, gum rosin, which is made from tree oleoresin, is used to improve plasticity, adhesive viscosity, and strength. Therefore, these factors are predicted to increase the consumption of pine-derived chemicals and fuel market expansion throughout the projected period.

MARKET RESTRAINTS:

Stringent government regulations might hinder the pine-derived chemical market.

Strict government rules are a major obstacle to the market for chemicals generated from pine, affecting the supply chain, market access, and several industrial processes. Pine feedstock supply and sustainability for chemical extraction can be impacted by laws about forestry management, environmental protection, and chemical safety.

Forestry laws that protect natural ecosystems and encourage sustainable forest management may impose restrictions on pine tree harvesting, which would reduce the availability of raw materials for the manufacturing of chemicals derived from pine. Additionally, producers of chemicals generated from pine may have to pay more to comply with environmental rules that control emissions, waste management, and the quality of the air and water.

North America is predicted to account for a significant share of the pine-derived chemical market.

The pine-derived chemicals market is expected to grow rapidly in the North American region. This increase can be attributed to increased product demand from adhesive and sealant applications. The region's vast pine woods offer a plentiful and sustainable supply of raw materials for the manufacturing of compounds derived from pine, such as terpenes, turpentine, tall oil, and rosin. Owing to the feedstock's accessibility, producers of chemicals generated from pine have a steady supply chain, which is predicted to promote industrial expansion.

Furthermore, the growing use of sterols and gum rosin in printing inks is anticipated to drive the market in the Asia Pacific. The rising usage of chemicals in paint and coatings applications is driving expansion in Europe. Moreover, The Middle East and Africa are expected to see substantial development due to the use of tall oil rosin in surfactant applications.

Market Developments:

In January 2024, with the completion of a $35 million investment, Kraton Corporation, a prominent global sustainable producer of specialty polymers and high-value biobased products derived from pine wood pulping by-products, upgraded its crude tall oil (CTO) biorefinery towers at its manufacturing facility in Panama City, Florida.
In March 2023, in Japan, at the Kakogawa Plant, Harima established a myrcene production plant on the grounds of its manufacturing center. Myrcene, a crucial component of scent oils and perfumes, is derived from turpentine's pinene molecule, a naturally occurring material that is taken from pine trees.

Segmentation:

By Type
Tall Oil Fatty Acid
Tall Oil Rosin
Sterols
Pitch
Gum Turpentine
Gum Rosin
Others
By Source
Living Trees
Dead Pine Stumps & Logs
By-products of Sulphate Pulping
By Process
Tapping
Kraft
By Application
Paints & Coatings
Adhesives & Sealants
Printing Inks
Surfactants
Others
By Geography
North America
USA
Canada
Mexico
South America
Brazil
Argentina
Others
Europe
United Kingdom
Germany
France
Spain
Others
Middle East and Africa
Saudi Arabia
UAE
Israel
Others
Asia Pacific
China
Japan
India
South Korea
Taiwan
Thailand
Indonesia
Others


1. INTRODUCTION
1.1. Market Overview
1.2. Market Definition
1.3. Scope of the Study
1.4. Market Segmentation
1.5. Currency
1.6. Assumptions
1.7. Base, and Forecast Years Timeline
1.8. Key Benefits for the stakeholder
2. RESEARCH METHODOLOGY
2.1. Research Design
2.2. Research Processes
3. EXECUTIVE SUMMARY
3.1. Key Findings
3.2. Analyst View
4. MARKET DYNAMICS
4.1. Market Drivers
4.2. Market Restraints
4.3. Porter’s Five Forces Analysis
4.3.1. Bargaining Power of Suppliers
4.3.2. Bargaining Power of Buyers
4.3.3. Threat of New Entrants
4.3.4. Threat of Substitutes
4.3.5. Competitive Rivalry in the Industry
4.4. Industry Value Chain Analysis
4.5. Russia-Ukraine War Impact Analysis
5. PINE-DERIVED CHEMICAL MARKET, BY TYPE
5.1. Introduction
5.2. Tall Oil Fatty Acid
5.2.1. Market Trends and Opportunities
5.2.2. Growth Prospects
5.2.3. Geographic Lucrativeness
5.3. Tall Oil Rosin
5.3.1. Market Trends and Opportunities
5.3.2. Growth Prospects
5.3.3. Geographic Lucrativeness
5.4. Sterols
5.4.1. Market Trends and Opportunities
5.4.2. Growth Prospects
5.4.3. Geographic Lucrativeness
5.5. Pitch
5.5.1. Market Trends and Opportunities
5.5.2. Growth Prospects
5.5.3. Geographic Lucrativeness
5.6. Gum Turpentine
5.6.1. Market Trends and Opportunities
5.6.2. Growth Prospects
5.6.3. Geographic Lucrativeness
5.7. Gum Rosin
5.7.1. Market Trends and Opportunities
5.7.2. Growth Prospects
5.7.3. Geographic Lucrativeness
5.8. Others
5.8.1. Market Trends and Opportunities
5.8.2. Growth Prospects
5.8.3. Geographic Lucrativeness
6. PINE-DERIVED CHEMICAL MARKET, BY SOURCE
6.1. Introduction
6.2. Living Trees
6.2.1. Market Trends and Opportunities
6.2.2. Growth Prospects
6.2.3. Geographic Lucrativeness
6.3. Dead Pine Stumps & Logs
6.3.1. Market Trends and Opportunities
6.3.2. Growth Prospects
6.3.3. Geographic Lucrativeness
6.4. By-products of Sulphate Pulping
6.4.1. Market Trends and Opportunities
6.4.2. Growth Prospects
6.4.3. Geographic Lucrativeness
7. PINE-DERIVED CHEMICAL MARKET, BY PROCESS
7.1. Introduction
7.2. Tapping
7.2.1. Market Trends and Opportunities
7.2.2. Growth Prospects
7.2.3. Geographic Lucrativeness
7.3. Kraft
7.3.1. Market Trends and Opportunities
7.3.2. Growth Prospects
7.3.3. Geographic Lucrativeness
8. PINE-DERIVED CHEMICAL MARKET, BY APPLICATION
8.1. Introduction
8.2. Paints & Coatings
8.2.1. Market Trends and Opportunities
8.2.2. Growth Prospects
8.2.3. Geographic Lucrativeness
8.3. Adhesives & Sealants
8.3.1. Market Trends and Opportunities
8.3.2. Growth Prospects
8.3.3. Geographic Lucrativeness
8.4. Printing Inks
8.4.1. Market Trends and Opportunities
8.4.2. Growth Prospects
8.4.3. Geographic Lucrativeness
8.5. Surfactants
8.5.1. Market Trends and Opportunities
8.5.2. Growth Prospects
8.5.3. Geographic Lucrativeness
8.6. Others
8.6.1. Market Trends and Opportunities
8.6.2. Growth Prospects
8.6.3. Geographic Lucrativeness
9. PINE-DERIVED CHEMICAL MARKET, BY GEOGRAPHY
9.1. Introduction
9.2. North America
9.2.1. By Type
9.2.2. By Source
9.2.3. By Process
9.2.4. By Application
9.2.5. By Country
9.2.5.1. USA
9.2.5.1.1. Market Trends and Opportunities
9.2.5.1.2. Growth Prospects
9.2.5.2. Canada
9.2.5.2.1. Market Trends and Opportunities
9.2.5.2.2. Growth Prospects
9.2.5.3. Mexico
9.2.5.3.1. Market Trends and Opportunities
9.2.5.3.2. Growth Prospects
9.3. South America
9.3.1. By Type
9.3.2. By Source
9.3.3. By Process
9.3.4. By Application
9.3.5. By Country
9.3.5.1. Brazil
9.3.5.1.1. Market Trends and Opportunities
9.3.5.1.2. Growth Prospects
9.3.5.2. Argentina
9.3.5.2.1. Market Trends and Opportunities
9.3.5.2.2. Growth Prospects
9.3.5.3. Others
9.3.5.3.1. Market Trends and Opportunities
9.3.5.3.2. Growth Prospects
9.4. Europe
9.4.1. By Type
9.4.2. By Source
9.4.3. By Process
9.4.4. By Application
9.4.5. By Country
9.4.5.1. United Kingdom
9.4.5.1.1. Market Trends and Opportunities
9.4.5.1.2. Growth Prospects
9.4.5.2. Germany
9.4.5.2.1. Market Trends and Opportunities
9.4.5.2.2. Growth Prospects
9.4.5.3. France
9.4.5.3.1. Market Trends and Opportunities
9.4.5.3.2. Growth Prospects
9.4.5.4. Spain
9.4.5.4.1. Market Trends and Opportunities
9.4.5.4.2. Growth Prospects
9.4.5.5. Others
9.4.5.5.1. Market Trends and Opportunities
9.4.5.5.2. Growth Prospects
9.5. Middle East and Africa
9.5.1. By Type
9.5.2. By Source
9.5.3. By Process
9.5.4. By Application
9.5.5. By Country
9.5.5.1. Saudi Arabia
9.5.5.1.1. Market Trends and Opportunities
9.5.5.1.2. Growth Prospects
9.5.5.2. UAE
9.5.5.2.1. Market Trends and Opportunities
9.5.5.2.2. Growth Prospects
9.5.5.3. Israel
9.5.5.3.1. Market Trends and Opportunities
9.5.5.3.2. Growth Prospects
9.5.5.4. Others
9.5.5.4.1. Market Trends and Opportunities
9.5.5.4.2. Growth Prospects
9.6. Asia Pacific
9.6.1. By Type
9.6.2. By Source
9.6.3. By Process
9.6.4. By Application
9.6.5. By Country
9.6.5.1. China
9.6.5.1.1. Market Trends and Opportunities
9.6.5.1.2. Growth Prospects
9.6.5.2. Japan
9.6.5.2.1. Market Trends and Opportunities
9.6.5.2.2. Growth Prospects
9.6.5.3. India
9.6.5.3.1. Market Trends and Opportunities
9.6.5.3.2. Growth Prospects
9.6.5.4. South Korea
9.6.5.4.1. Market Trends and Opportunities
9.6.5.4.2. Growth Prospects
9.6.5.5. Taiwan
9.6.5.5.1. Market Trends and Opportunities
9.6.5.5.2. Growth Prospects
9.6.5.6. Thailand
9.6.5.6.1. Market Trends and Opportunities
9.6.5.6.2. Growth Prospects
9.6.5.7. Indonesia
9.6.5.7.1. Market Trends and Opportunities
9.6.5.7.2. Growth Prospects
9.6.5.8. Others
9.6.5.8.1. Market Trends and Opportunities
9.6.5.8.2. Growth Prospects
10. COMPETITIVE ENVIRONMENT AND ANALYSIS
10.1. Major Players and Strategy Analysis
10.2. Market Share Analysis
10.3. Mergers, Acquisitions, Agreements, and Collaborations
10.4. Competitive Dashboard
11. COMPANY PROFILES
11.1. Harima Chemicals Group, Inc.
11.2. Arakawa Chemical Industries, Ltd.
11.3. Ingevity Corporation
11.4. DRT (Dérivés Résiniques ET Terpéniques) (Firmenich)
11.5. Foreverest Resources Ltd.
11.6. Kraton Corporation (DL Chemical Co. Ltd.)
11.7. Forchem (Respol Resinas, S.A.)

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