한글목차

생분해성 및 퇴비화 포장 시장은 환경 의식 증가, 엄격한 규제, 지속 가능한 제품에 대한 소비자 선호의 변화 등으로 급속한 성장을 보이고 있습니다. 이 부서는 전통적인 플라스틱 포장을 대체하는 친환경적인 옵션을 제공하며 세계의 포장 산업의 핵심 구성 요소로 부상하고 있습니다. 현재 이 시장은 폴리유산(PLA), 폴리하이드록시알카노에이트(PHA), 전분계 혼합물, 셀룰로오스 유래 포장 솔루션 등 다양한 재료와 기술을 특징으로 합니다. 이러한 재료는 다양한 산업에서 이용되고 있지만, 식품 공급망에서 플라스틱 폐기물에 대한 우려가 높아짐에 따라 식품 포장이 가장 큰 부문이 되었습니다. 포장 산업의 주요 기업은 생분해성 재료의 성능과 비용 효과를 향상시키기 위해 연구 개발에 많은 투자를 하고 있습니다. 동시에 수많은 스타트업과 혁신적인 기업들이 해초 기반 포장과 균사체 유래 재료 등 참신한 솔루션으로 시장에 진출하고 있습니다. 이 시장에서는 산업용 퇴비 인프라의 한계를 해결하기 위해 가정용 퇴비로 분해 할 수있는 퇴비 포장의 개발에 대한 동향을 볼 수 있습니다. 게다가 생분해성뿐만 아니라 제품의 보존성을 높이거나 스마트 기술을 도입하는 다기능 포장의 개발에도 주목을 받고 있습니다.

그 성장에도 불구하고, 생분해성 포장 시장은 기존 플라스틱에 비해 높은 생산 비용, 특정 용도의 성능 한계, 적절한 폐기물 관리 인프라의 필요성 등과 같은 과제에 직면하고 있습니다. 그러나 진행 중인 기술적 진보와 규모의 경제로 인해 이러한 문제가 점차 해결되고 있습니다. 지속가능성을 추구하는 세계의 움직임이 강해짐에 따라 생분해성 및 퇴비화 포장 시장은 상승 기조를 계속할 것으로 예측됩니다. 산업은 새로운 혁신을 보이고 다양한 부문에서 채용이 진행되고 대기업이 유망한 기술을 획득함으로써 통합이 진행될 가능성도 있습니다. 이 성장은 포장 산업을 재구성하는 것뿐만 아니라 플라스틱 폐기물과 환경 오염을 줄이는 세계의적인 노력에도 크게 기여합니다.

본 보고서에서는 세계의 생분해성 및 퇴비화 포장 시장에 대해 조사 분석하고, 시장 규모와 성장 예측, 재료의 혁신의 상세, 이용 상황, 경쟁 구도, 지속가능성에 대한 영향 등의 정보를 제공합니다.

목차

제1장 주요 요약

• 세계의 포장 시장
• 생분해성 및 퇴비화 포장 시장
  • 바이오 베이스 플라스틱 유형별
  • 포장 제품 유형별
  • 최종 용도 시장별
  • 지역별
• 주요 유형
  • 셀룰로오스 아세테이트
  • PLA
  • 지방족 방향족 코폴리에스터
  • PHA
  • 전분/전분 혼합물
• 가격
• 시장 동향
• 생분해성 및 퇴비화 포장의 최근 성장 시장 성장 촉진요인
• 생분해성 및 퇴비화 포장의 과제

제2장 생분해성 및 퇴비화 포장의 바이오 베이스 재료

• 재료의 혁신
• 활성 포장
• 모노 머티리얼 포장
• 포장에 사용되는 종래의 폴리머 재료
  • 폴리올레핀:폴리프로필렌과 폴리에틸렌
  • PET 및 기타 폴리에스테르 폴리머
  • 포장용 재생 가능한 바이오베이스 폴리머
  • 합성화석 베이스 폴리머와 바이오 베이스 폴리머의 비교
  • 포장에 있어서의 바이오플라스틱의 프로세스
  • 바이오 베이스의 지속 가능한 포장의 폐기 처리
• 합성 바이오 베이스 포장 재료
  • 폴리유산(바이오 PLA)
  • 폴리에틸렌테레프탈레이트(바이오 PET)
  • 폴리트리메틸렌테레프탈레이트(바이오PTT)
  • 폴리에틸렌 푸라노에이트(바이오 PEF)
  • 바이오 PA
  • 폴리(부틸렌 아디페이트 코테레프탈레이트)(바이오 PBAT)-지방족 방향족 코폴리에스터
  • 폴리부틸렌 석시네이트(PBS)와 공중합체
  • 폴리프로필렌(바이오PP)
• 천연 바이오 베이스 포장 재료
  • 폴리하이드록시알칸산(PHA)
  • 전분계 혼합물
  • 셀룰로오스
  • 포장재료에서 단백질 기반 바이오플라스틱
  • 포장용 지질과 왁스
  • 해초 기반 포장
  • 균사체
  • 키토산
  • 바이오나프타

제3장 시장과 용도

• 종이 및 판지 포장
• 식품 포장
  • 바이오 베이스 필름, 트레이
  • 바이오베이스 파우치, 가방
  • 바이오베이스 섬유, 그물
  • 바이오 접착제
  • 배리어 코팅, 필름
  • 액티브 스마트 식품 포장
  • 항균 필름, 항균제
  • 바이오 베이스 잉크, 염료
  • 가식 필름, 코팅
• 포장에 있어서의 바이오 베이스 필름, 코팅
  • 개요
  • 바이오 베이스의 페인트 및 코팅의 사용에 있어서의 과제
  • 포장에 사용되는 바이오 베이스 코팅, 필름의 유형
• 포장용 탄소 회수 유래 재료
  • 플라스틱 원료에 탄소 이용의 장점
  • CO2 유래의 폴리머와 플라스틱
  • CO2이용제품
• 연질 포장
• 경질 포장
• 코팅, 필름

제4장 기업 프로파일(기업 230사의 프로파일)

제5장 조사 방법

제6장 참고문헌

영문목차

The market for biodegradable and compostable packaging is experiencing rapid growth, driven by increasing environmental awareness, stringent regulations, and shifting consumer preferences towards sustainable products. This sector has emerged as a crucial component of the global packaging industry, offering eco-friendly alternatives to traditional plastic packaging. Currently, the market is characterized by a diverse range of materials and technologies, including polylactic acid (PLA), polyhydroxyalkanoates (PHA), starch-based blends, and cellulose-derived packaging solutions. These materials are finding applications across various industries, with food packaging representing the largest segment due to growing concerns about plastic waste in the food supply chain. Major players in the packaging industry are investing heavily in research and development to improve the performance and cost-effectiveness of biodegradable materials. Simultaneously, numerous start-ups and innovative companies are entering the market with novel solutions, such as seaweed-based packaging and mycelium-derived materials. The market is witnessing a trend towards the development of compostable packaging that can break down in home composting conditions, addressing the limitations of industrial composting infrastructure. Additionally, there is a growing focus on creating multi-functional packaging that not only biodegrades but also offers enhanced shelf life for products or incorporates smart technologies.

Despite its growth, the biodegradable packaging market faces challenges, including higher production costs compared to conventional plastics, performance limitations in certain applications, and the need for proper waste management infrastructure. However, ongoing technological advancements and economies of scale are gradually addressing these issues. As the global push for sustainability intensifies, the biodegradable and compostable packaging market is expected to continue its upward trajectory. The industry is likely to see further innovations, increased adoption across various sectors, and potential consolidation as larger companies acquire promising technologies. This growth is not only reshaping the packaging industry but also contributing significantly to global efforts in reducing plastic waste and environmental pollution.

"The Global Market for Biodegradable and Compostable Packaging 2025-2035" provides a thorough examination of the market landscape from 2025 to 2035, offering valuable insights for manufacturers, investors, and stakeholders in the sustainable packaging ecosystem.

Report contents include:

• Market Size and Growth Projections: Detailed forecasts of the biodegradable and compostable packaging market size and growth rate from 2025 to 2035, segmented by product type, material, end-use industry, and region.
• Material Innovation Deep Dive: Comprehensive analysis of both synthetic and natural biobased packaging materials, including PLA, Bio-PET, PHA, starch-based blends, and emerging solutions like mycelium and seaweed-based packaging.
• Application Landscape: Exploration of key application areas such as food packaging, consumer goods, pharmaceuticals, and e-commerce, with insights into specific requirements and growth opportunities.
• Competitive Landscape: Profiles of leading companies and emerging players in the biodegradable packaging space, including their technologies, strategies, and market positioning. Companies profiled include 9Fiber, Inc., ADBioplastics, Advanced Biochemical (Thailand) Co., Ltd., Aeropowder Limited, AGRANA Staerke GmbH, Ahlstrom-Munksjo Oyj, Alberta Innovates/Innotech Materials, LLC, Alter Eco Pulp, Alterpacks, AmicaTerra, An Phat Bioplastics, Anellotech, Inc., Ankor Bioplastics Co., Ltd., ANPOLY, Inc., Apeel Sciences, Applied Bioplastics, Aquapak Polymers Ltd, Archer Daniel Midland Company (ADM), Arekapak GmbH, Arkema S.A, Arrow Greentech, Asahi Kasei Chemicals Corporation, Attis Innovations, llc, Avani Eco, Avantium B.V., Avient Corporation, Balrampur Chini Mills, BASF SE, Bio Fab NZ, Bio Plast Pom, Bio2Coat, Bioelements Group, Biofibre GmbH, Bioform Technologies, Biokemik, BIOLO, BioLogiQ, Inc., Biome Bioplastics, Biomass Resin Holdings Co., Ltd., BIO-FED, BIO-LUTIONS International AG, Bioplastech Ltd, BioSmart Nano, BIOTEC GmbH & Co. KG, Biovox GmbH, BlockTexx Pty Ltd., Blue Ocean Closures, Bluepha Beijing Lanjing Microbiology Technology Co., Ltd., BOBST, Borealis AG, Brightplus Oy, Business Innovation Partners Co., Ltd., Carbiolice, Carbios, Cardia Bioplastics Ltd., CARAPAC Company, Cass Materials Pty Ltd, Celanese Corporation, Cellugy, Cellutech AB (Stora Enso), Chemkey Advanced Materials Technology (Shanghai) Co., Ltd., Chemol Company (Seydel), CJ Biomaterials, Inc., Coastgrass ApS, Corumat, Inc., Cruz Foam, CuanTec Ltd., Daicel Polymer Ltd., Daio Paper Corporation, Danimer Scientific LLC, DIC Corporation, DIC Products, Inc., DKS Co. Ltd., Dow, Inc., DuFor Resins B.V., DuPont, Earthodic Pty Ltd., EarthForm, Ecomann Biotechnology Co., Ltd., Ecoshell, EcoSynthetix, Inc., Ecovia Renewables, Enkev, Epoch Biodesign, Eranova, Esbottle Oy, Fiberlean Technologies, Fiberwood Oy, FKuR Kunststoff GmbH, Floreon, Footprint, Fraunhofer Institute for Silicate Research ISC, Full Cycle Bioplastics LLC, Futamura Chemical Co., Ltd., Futuramat Sarl, Futurity Bio-Ventures Ltd., Genecis Bioindustries, Inc., Grabio Greentech Corporation, Granbio Technologies, GreenNano Technologies Inc., GS Alliance Co. Ltd, Guangzhou Bio-plus Materials Technology Co., Ltd., Hokuetsu Toyo Fibre Co., Ltd., Holmen Iggesund, IUV Srl, Jiangsu Jinhe Hi-Tech Co., Ltd., Jiangsu Torise Biomaterials Co., Ltd, JinHui ZhaoLang High Technology Co., Ltd., Kagzi Bottles Private Limited, Kami Shoji Company, Kaneka Corporation, Kelpi Industries Ltd., Kingfa Sci. & Tech. Co. Ltd., Klabin S.A., Lactips S.A., LAM'ON, LanzaTech, Licella, Lignin Industries, Loick Biowertstoff GmbH, LOTTE Chemical Corporation, MadeRight, MakeGrowLab, Marea, Marine Innovation Co., Ltd, Melodea Ltd., Mi Terro, Inc., Mitr Phol, Mitsubishi Chemical Corporation, Mitsubishi Polyester Film GmbH, Mitsui Chemicals, Inc., Mobius, Mondi, Multibax Public Co., Ltd., Nabaco, Inc., NatPol, Nature Coatings, Inc., NatureWorks LLC, New Zealand Natural Fibers (NZNF), Newlight Technologies, NEXE Innovations Inc., Nippon Paper Industries, Notpla, Novamont S.p.A., Novomer, Oimo, Oji Paper Company, Omya, one - five GmbH, Origin Materials, Pack2Earth, Paptic Ltd., Pivot Materials LLC, Plafco Fibertech Oy, Plantic Technologies Ltd., Plantics B.V., Poliloop, Polyferm Canada, Pond Biomaterials, Provenance Biofabrics, Inc., PT Intera Lestari Polimer, PTT MCC Biochem Co., Ltd., Qnature UG, Rengo Co., Ltd., Rise Innventia AB, Rodenburg Productie B.V., Roquette S.A., RWDC Industries, S.lab, Sappi Limited, Saudi Basic Industries Corp. (SABIC), Searo, Shellworks, Shenzhen Ecomann Biotechnology Co., Ltd., Sirmax Group, SK Chemicals Co., Ltd., Solvay SA, Spectrus Sustainable Solutions Pvt Ltd, Spero Renewables, StePAc, Stora Enso Oyj, Sufresca, Sulapac Oy, Sulzer Chemtech AG, SUPLA Bioplastics, Sway Innovation Co., Sweetwater Energy, Taghleef Industries Llc, Teal Bioworks, Inc., TemperPack-R Technologies, Termotecnica, TerraVerdae BioWorks Inc, Tianjin GreenBio Materials Co., Ltd, Ticinoplast, TIPA, Toppan Printing Co., Ltd., Toraphene, TotalEnergies Corbion, Universal Bio Pack Co., Ltd., UPM Biochemicals, UPM-Kymmene Oyj, Valentis Nanotech, Vegea srl, Verso Corporation, Weidmann Fiber Technology, Woamy Oy, Woodly Ltd., Worn Again Technologies, Xampla, Yangi, Yokohama Bio Frontier, Inc., Zelfo Technology, ZeroCircle, Zhejiang Jinjiahao Green Nanomaterial Co., Ltd.
• Sustainability Impact: Assessment of the environmental benefits and challenges associated with biodegradable and compostable packaging, including life cycle analyses and circular economy initiatives.
• Recent developments in biodegradable packaging technology.
• Market Drivers and Opportunities.
• Challenges and Market Dynamics
• Regional Analysis and Market Opportunities
• In-depth analysis of biodegradable packaging applications across various industries:
  • Food and Beverage: Largest market segment with diverse applications from fresh produce to dairy packaging
  • Consumer Goods: Growing demand in personal care and household products
  • Pharmaceutical: Increasing use of bioplastics in medical packaging and drug delivery systems
  • E-commerce: Rising adoption of sustainable packaging solutions for online retail
• Materials Benchmarking and Performance Analysis
• Manufacturing and Processing Innovations
  • Improvements in extrusion and thermoforming processes
  • Novel approaches to enhance material properties
  • Scalability considerations for mass production
  • Quality control and testing methodologies
• Investment Landscape and Market Opportunities
• Regulatory Framework and Standards

As the world moves towards more sustainable packaging solutions, understanding the biodegradable and compostable packaging market is crucial for:

• Packaging manufacturers looking to expand their product portfolio
• Brand owners seeking to meet sustainability goals and consumer demands
• Investors interested in high-growth areas of the packaging industry
• Policy makers developing regulations for sustainable packaging
• Researchers and material scientists working on next-generation packaging solutions

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

• 1.1. Global Packaging Market
• 1.2. The Market for Biodegradable and Compostable Packaging
  • 1.2.1. By biobased plastics type
  • 1.2.2. By packaging product type
  • 1.2.3. By end-use market
  • 1.2.4. By region
• 1.3. Main types
  • 1.3.1. Cellulose acetate
  • 1.3.2. PLA
  • 1.3.3. Aliphatic-aromatic co-polyesters
  • 1.3.4. PHA
  • 1.3.5. Starch/starch blends
• 1.4. Prices
• 1.5. Market Trends
• 1.6. Market Drivers for recent growth in Biodegradable and Compostable Packaging
• 1.7. Challenges for Biodegradable and Compostable Packaging

2. BIOBASED MATERIALS IN BIODEGRADABLE AND COMPOSTABLE PACKAGING

• 2.1. Materials innovation
• 2.2. Active packaging
• 2.3. Monomaterial packaging
• 2.4. Conventional polymer materials used in packaging
  • 2.4.1. Polyolefins: Polypropylene and polyethylene
    • 2.4.1.1. Overview
    • 2.4.1.2. Grades
    • 2.4.1.3. Producers
  • 2.4.2. PET and other polyester polymers
    • 2.4.2.1. Overview
  • 2.4.3. Renewable and bio-based polymers for packaging
  • 2.4.4. Comparison of synthetic fossil-based and bio-based polymers
  • 2.4.5. Processes for bioplastics in packaging
  • 2.4.6. End-of-life treatment of bio-based and sustainable packaging
• 2.5. Synthetic bio-based packaging materials
  • 2.5.1. Polylactic acid (Bio-PLA)
    • 2.5.1.1. Overview
    • 2.5.1.2. Properties
    • 2.5.1.3. Applications
    • 2.5.1.4. Advantages
    • 2.5.1.5. Challenges
    • 2.5.1.6. Commercial examples
  • 2.5.2. Polyethylene terephthalate (Bio-PET)
    • 2.5.2.1. Overview
    • 2.5.2.2. Properties
    • 2.5.2.3. Applications
    • 2.5.2.4. Advantages of Bio-PET in Packaging
    • 2.5.2.5. Challenges and Limitations
    • 2.5.2.6. Commercial examples
  • 2.5.3. Polytrimethylene terephthalate (Bio-PTT)
    • 2.5.3.1. Overview
    • 2.5.3.2. Production Process
    • 2.5.3.3. Properties
    • 2.5.3.4. Applications
    • 2.5.3.5. Advantages of Bio-PTT in Packaging
    • 2.5.3.6. Challenges and Limitations
    • 2.5.3.7. Commercial examples
  • 2.5.4. Polyethylene furanoate (Bio-PEF)
    • 2.5.4.1. Overview
    • 2.5.4.2. Properties
    • 2.5.4.3. Applications
    • 2.5.4.4. Advantages of Bio-PEF in Packaging
    • 2.5.4.5. Challenges and Limitations
    • 2.5.4.6. Commercial examples
  • 2.5.5. Bio-PA
    • 2.5.5.1. Overview
    • 2.5.5.2. Properties
    • 2.5.5.3. Applications in Packaging
    • 2.5.5.4. Advantages of Bio-PA in Packaging
    • 2.5.5.5. Challenges and Limitations
    • 2.5.5.6. Commercial examples
  • 2.5.6. Poly(butylene adipate-co-terephthalate) (Bio-PBAT)- Aliphatic aromatic copolyesters
    • 2.5.6.1. Overview
    • 2.5.6.2. Properties
    • 2.5.6.3. Applications in Packaging
    • 2.5.6.4. Advantages of Bio-PBAT in Packaging
    • 2.5.6.5. Challenges and Limitations
    • 2.5.6.6. Commercial examples
  • 2.5.7. Polybutylene succinate (PBS) and copolymers
    • 2.5.7.1. Overview
    • 2.5.7.2. Properties
    • 2.5.7.3. Applications in Packaging
    • 2.5.7.4. Advantages of Bio-PBS and Co-polymers in Packaging
    • 2.5.7.5. Challenges and Limitations
    • 2.5.7.6. Commercial examples
  • 2.5.8. Polypropylene (Bio-PP)
    • 2.5.8.1. Overview
    • 2.5.8.2. Properties
    • 2.5.8.3. Applications in Packaging
    • 2.5.8.4. Advantages of Bio-PP in Packaging
    • 2.5.8.5. Challenges and Limitations
    • 2.5.8.6. Commercial examples
• 2.6. Natural bio-based packaging materials
  • 2.6.1. Polyhydroxyalkanoates (PHA)
    • 2.6.1.1. Properties
    • 2.6.1.2. Applications in Packaging
    • 2.6.1.3. Advantages of PHA in Packaging
    • 2.6.1.4. Challenges and Limitations
    • 2.6.1.5. Commercial examples
  • 2.6.2. Starch-based blends
    • 2.6.2.1. Overview
    • 2.6.2.2. Properties
    • 2.6.2.3. Applications in Packaging
    • 2.6.2.4. Advantages of Starch-Based Blends in Packaging
    • 2.6.2.5. Challenges and Limitations
    • 2.6.2.6. Commercial examples
  • 2.6.3. Cellulose
    • 2.6.3.1. Feedstocks
      • 2.6.3.1.1. Wood
      • 2.6.3.1.2. Plant
      • 2.6.3.1.3. Tunicate
      • 2.6.3.1.4. Algae
      • 2.6.3.1.5. Bacteria
    • 2.6.3.2. Microfibrillated cellulose (MFC)
      • 2.6.3.2.1. Properties
    • 2.6.3.3. Nanocellulose
      • 2.6.3.3.1. Cellulose nanocrystals
        • 2.6.3.3.1.1. Applications in packaging
      • 2.6.3.3.2. Cellulose nanofibers
        • 2.6.3.3.2.1. Applications in packaging
      • 2.6.3.3.3. Bacterial Nanocellulose (BNC)
        • 2.6.3.3.3.1. Applications in packaging
    • 2.6.3.4. Commercial examples
  • 2.6.4. Protein-based bioplastics in packaging
    • 2.6.4.1. Feedstocks
    • 2.6.4.2. Commercial examples
  • 2.6.5. Lipids and waxes for packaging
    • 2.6.5.1. Overview
    • 2.6.5.2. Commercial examples
  • 2.6.6. Seaweed-based packaging
    • 2.6.6.1. Overview
    • 2.6.6.2. Production
    • 2.6.6.3. Applications in packaging
    • 2.6.6.4. Producers
  • 2.6.7. Mycelium
    • 2.6.7.1. Overview
    • 2.6.7.2. Applications in packaging
    • 2.6.7.3. Commercial examples
  • 2.6.8. Chitosan
    • 2.6.8.1. Overview
    • 2.6.8.2. Applications in packaging
    • 2.6.8.3. Commercial examples
  • 2.6.9. Bio-naphtha
    • 2.6.9.1. Overview
    • 2.6.9.2. Markets and applications
    • 2.6.9.3. Commercial examples

3. MARKETS AND APPLICATIONS

• 3.1. Paper and board packaging
• 3.2. Food packaging
  • 3.2.1. Bio-Based films and trays
  • 3.2.2. Bio-Based pouches and bags
  • 3.2.3. Bio-Based textiles and nets
  • 3.2.4. Bioadhesives
    • 3.2.4.1. Starch
    • 3.2.4.2. Cellulose
    • 3.2.4.3. Protein-Based
  • 3.2.5. Barrier coatings and films
    • 3.2.5.1. Polysaccharides
      • 3.2.5.1.1. Chitin
      • 3.2.5.1.2. Chitosan
      • 3.2.5.1.3. Starch
    • 3.2.5.2. Poly(lactic acid) (PLA)
    • 3.2.5.3. Poly(butylene Succinate)
    • 3.2.5.4. Functional Lipid and Proteins Based Coatings
  • 3.2.6. Active and Smart Food Packaging
    • 3.2.6.1. Active Materials and Packaging Systems
    • 3.2.6.2. Intelligent and Smart Food Packaging
  • 3.2.7. Antimicrobial films and agents
    • 3.2.7.1. Natural
    • 3.2.7.2. Inorganic nanoparticles
    • 3.2.7.3. Biopolymers
  • 3.2.8. Bio-based Inks and Dyes
  • 3.2.9. Edible films and coatings
    • 3.2.9.1. Overview
    • 3.2.9.2. Commercial examples
• 3.3. Biobased films and coatings in packaging
  • 3.3.1. Overview
  • 3.3.2. Challenges using bio-based paints and coatings
  • 3.3.3. Types of bio-based coatings and films in packaging
    • 3.3.3.1. Polyurethane coatings
      • 3.3.3.1.1. Properties
      • 3.3.3.1.2. Bio-based polyurethane coatings
      • 3.3.3.1.3. Products
    • 3.3.3.2. Acrylate resins
      • 3.3.3.2.1. Properties
      • 3.3.3.2.2. Bio-based acrylates
      • 3.3.3.2.3. Products
    • 3.3.3.3. Polylactic acid (Bio-PLA)
      • 3.3.3.3.1. Properties
      • 3.3.3.3.2. Bio-PLA coatings and films
    • 3.3.3.4. Polyhydroxyalkanoates (PHA) coatings
    • 3.3.3.5. Cellulose coatings and films
      • 3.3.3.5.1. Microfibrillated cellulose (MFC)
      • 3.3.3.5.2. Cellulose nanofibers
        • 3.3.3.5.2.1. Properties
        • 3.3.3.5.2.2. Product developers
    • 3.3.3.6. Lignin coatings
    • 3.3.3.7. Protein-based biomaterials for coatings
      • 3.3.3.7.1. Plant derived proteins
      • 3.3.3.7.2. Animal origin proteins
• 3.4. Carbon capture derived materials for packaging
  • 3.4.1. Benefits of carbon utilization for plastics feedstocks
  • 3.4.2. CO2-derived polymers and plastics
  • 3.4.3. CO2 utilization products
• 3.5. Flexible packaging
• 3.6. Rigid packaging
• 3.7. Coatings and films

4. COMPANY PROFILES (230 company profiles)

5. RESEARCH METHODOLOGY

6. REFERENCES