ヴィーガンレザー代替需要により、2024-2034年までにバイオベースレザーのCAGR(年平均成長率)が37.4%増加

新たな代替レザー 2024-2034年:技術、トレンド、有力企業

菌糸体レザー、植物性レザー、微生物レザー、ラボグロウンレザーなどの技術分析。持続可能なレザー市場の展望。バイオベースのヴィーガンレザー10年間の市場予測。


製品情報 概要 目次 価格 Related Content
本レポートでは、菌糸体レザー、植物性レザー、微生物レザー、ラボグロウンレザーなど、バイオベースのヴィーガンレザー市場の主要技術とトレンドを包括的に取り上げています。70社以上の企業を特定し、技術的な準備状況、製造プロセス、材料ベンチマーク、用途、課題を分析しています。10年間の市場予測では、バイオベースのヴィーガンレザー需要の伸びをハイライトしています。
「バイオベース_ヴィーガンレザー 2024-2034年」が対象とする主なコンテンツ
(詳細は目次のページでご確認ください)
● 全体概要と結論
● 既存のレザー技術
□ 動物性レザー
□ プラスチックレザー
● 主なバイオベースヴィーガンレザー技術
□ 菌糸体レザー
□ バンブーレザー、パイナップルレザー、グレープレザー、アップルレザーなどの植物ベースレザー
□ セルロースレザー、コラーゲンレザー、スパイダーシルクレザーなどの微生物レザー
□ ラボ栽培レザー
● バイオベースヴィーガンレザーの材料ベンチマーク
● バイオベースヴィーガンレザーの主な用途
● 参入企業
● バイオベースヴィーガンレザーの市場規模、市場予測、市場展望
● 企業概要(インタビュー含む)
 
「バイオベース_ヴィーガンレザー 2024-2034年」は以下の情報を提供します
  • 消費者行動、環境への影響、ブランド活動など、バイオベースヴィーガンレザーの主な市場促進要因の内訳。
  • バイオベースヴィーガンレザー市場の最近の動向。
  • 動物性レザーとプラスチックレザーの製造プロセス、製造方法のトレンド、主要メーカーの詳細な内訳。
  • レザーのリサイクル概要、ボンデッドレザーの解説、再生レザーの製造方法。
  • バイオベースヴィーガンレザー市場の70以上の企業特定。
  • 菌糸体、植物ベースレザー、微生物、ラボグロウン、その他技術を含む4つの主な新しい代替レザー技術特定。
  • 製造プロセスと技術準備の詳細な内訳、SWOT分析。持続可能なコーティングと染料の説明、バイオベースヴィーガンレザーの製造における既存技術の適応。
  • 材料特性のベンチマーク、技術的な準備状況、価格、外観、各企業の拡張性。
  • ブランドパートナーシップの特定、ファッション用途、家具、自動車内装用レザーの考察、商業および用途分析。
  • バイオベースヴィーガンレザーの10年間の市場予測。 新たな代替レザー技術の主要トレンド特定。
 
Vegan bio-based leather: Answering the demand for sustainable materials
 
Leather is a ubiquitous, versatile material, used in many diverse applications including footwear, apparel, upholstery and automotive interiors. Animal leather, which the UN Food and Agriculture Organization estimates exceeds 20 billion square feet in annual production, is prized for its durability, strength, and aesthetic appeal. However, animal cultivation is one of the largest single causes of greenhouse gas emissions as well as being the leading cause of deforestation. Growing concerns about the environmental impact, sustainability, and the ethics of using animal hides have driven demand for alternatives from many consumers and brands.
 
Some brands have shifted to vegan leather - in other words, plastic leather, also called synthetic leather, artificial leather, or faux leather. Plastic leather's low cost has led it to become the dominant alternative for leather applications. However, there are clear sustainability concerns regarding plastic leather's petrochemical feedstocks, problematic disposal, and microplastics. Most plastic leather is disposed into landfills while a concerned amount is mismanaged and released into the environment. As such, plastic leather cannot be the solution to the search for a sustainable alternative to animal leather.
 
With growing numbers of consumers and brands demanding sustainable leather alternatives, this has driven the emergence of numerous startups attempting to capture a new market for vegan bio-based leather alternative materials. Their materials aim to challenge both animal and plastic leathers for the full range of leather applications, and several fashion brands have begun to explore the utilization of vegan bio-based leather in their product lineup, such as Zara, Burberry, H&M, Hermes, Nike, and Ganni. Many have formed partnerships with the key market players producing vegan bio-based alternatives.
 
In this report, "Vegan Bio-based Leather 2024-2034: Technologies, Trends, Players", IDTechEx provides comprehensive independent analysis of the trajectory of the vegan bio-based leather market, covering all major market players and emerging technologies. Within the report, IDTechEx discusses and analyzes key brand partnerships formed between brands and vegan leather companies. For example, the report covers the interest in the emergence of vegan leather alternatives by automotive OEMs such as BMW, Bentley, Cupra, Hyundai, Mercedes-Bens, and Volkswagen.
 
A diverse landscape of vegan bio-based leather technologies and players
 
With investments in alternative leather materials totaling over USD$1 billion, this is a rapidly developing technology landscape to monitor. Companies in the vegan bio-based leather market can be broadly divided into pursuing one of four major technology categories identified by IDTechEx:
  • Mycelium leather
  • Plant-based leather
  • Microbial leather
  • Lab-grown leather
 
 
Within this report, IDTechEx has identified over 70 companies developing vegan bio-based leather alternatives to animal and plastic leather. Most of these have emerged within the last 3-5 years and range from small exploratory startups to companies that have secured hundreds of millions in funding to begin scaling of production. Some strong market players in both mycelium leather and plant-based leather are at the precipice of scaling production and opening large scale factories for their materials.
 
The complex vegan bio-based leather market landscape has been comprehensively broken down with technologies analyzed and compared. IDTechEx has identified market leaders such as Von Holzhausen, MycoWorks, Piñatex, Desserto, and Ecovative among others and outlined prospects for each technology category. This analysis has been informed by IDTechEx's interview-based company profiles with market leaders and new entrants.
 
Through this assessment of the player landscape, IDTechEx expects market leaders to grow significantly while further new companies will continue to enter the sustainable vegan leather market due to its nascent stage and promising outlook.
 
Assessing the current status of vegan bio-based leathers
 
The performance requirements of leather applications vary depending on their application. These applications are wide ranging and include footwear, fashion, apparel, upholstery, and automotive. Some bio-based leathers have met the standards and appearance requirements of incumbent leather, but there is scope across the industry for improved material properties.
 
IDTechEx's material benchmarking studies evaluated bio-based leather materials on factors such as price, material strength, durability, and appearance. The diverse market landscape contains a large array of available products which differ in material properties, and IDTechEx has comprehensively benchmarked these products to allow readers to understand the current status of these materials.
 
Additionally, when assessing these materials, consideration should be made of the technology readiness level and the ability to scale production. These will determine whether a company can become a choice material for consumers and manufacturers while remaining competitive on price. IDTechEx has considered the technology readiness level of many different companies from each bio-based leather type to assess the outlook for the industry.
 
10 year vegan bio-based leather market forecast
 
Using extensive primary and secondary research, IDTechEx has constructed a 10-year market forecast for vegan bio-based leather where production capacity is expected to grow with a CAGR of 37.4% over the forecast period. The forecast is accompanied by commentary on the expected outlook for mycelium leather, plant-based leather, microbial leather and lab-grown leather.
Key aspects:
  • Detailed breakdown of the key market drivers for vegan bio-based leathers including consumer behavior, environmental impact, and brand actions.
  • Recent developments in the vegan bio-based leather market.
  • A detailed breakdown of the manufacturing processes of animal leather and plastic leather, trends in production methods, major manufacturers.
  • An overview of leather recycling, discussion of bonded leather, production methods of recycled leather.
  • 70+ companies identified in the vegan bio-based leather market.
  • Identification of four major emerging alternative leather technologies, including mycelium, plant-based, microbial, and lab-grown as well as other technologies.
  • Detailed breakdown of production processes and technology readiness, SWOT analysis. Discussion of sustainable coatings and dyes, adaptation of incumbent technologies in the manufacture of vegan bio-based leathers.
  • Benchmarking of material properties, technology readiness, price, appearance, and scalability for individual companies.
  • Commercial and application analysis, including identification of brand partnerships and discussion of fashion applications, furnishings, and leather for automotive interiors.
  • 10-year market forecasts for vegan biobased leathers. Identification of major trends for emerging alternative leather technologies.
Report MetricsDetails
CAGRThe production of vegan bio-based leathers is expected to grow by 37.4% CAGR from 2024 to 2034.
Forecast Period2024 - 2034
Forecast UnitsMillions of square meters
Regions CoveredWorldwide
Segments CoveredVegan bio-based leather, plastic leather, animal leather
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詳細
この調査レポートに関してのご質問は、下記担当までご連絡ください。

アイディーテックエックス株式会社 (IDTechEx日本法人)
担当: 村越美和子 m.murakoshi@idtechex.com
Table of Contents
1.EXECUTIVE SUMMARY
1.1.Introduction to emerging alternative leathers
1.2.Incumbent leather technologies
1.3.Leather terminology
1.4.Key drivers for emerging alternative leathers
1.5.Types of sustainable alternative leathers
1.6.Mycelium leather - product description and commercial analysis
1.7.Plant-based leather - product description and commercial analysis
1.8.Microbial leather - Product description and commercial analysis
1.9.Lab grown leather - Product description and commercial analysis
1.10.SWOT analysis of emerging alternative leathers
1.11.Major application areas for emerging alternative leathers
1.12.Go-to-market strategy for emerging alternative leathers
1.13.Leather size requirements by application area
1.14.Restraints for sustainable alternative leathers
1.15.Investment landscape for emerging alternative leathers
1.16.Recent developments in the emerging alternative leather market
1.17.IDTechEx benchmarking of emerging alternative leathers
1.18.Emerging alternative leather market forecast
1.19.Emerging alternative leather market forecast
1.20.Trends for emerging alternative leather
1.21.Key findings on emerging alternative leather
1.22.Company profiles
2.INTRODUCTION - MARKET DRIVERS AND CHALLENGES
2.1.Acronyms
2.2.Introduction to emerging alternative leathers
2.3.Incumbent leather technologies
2.4.Leather terminology
2.5.Key drivers for emerging alternative leathers
2.6.Market driver: The environmental impact of leather production
2.7.Market driver: The environmental impact of rearing livestock
2.8.Market driver: Consumer concerns
2.9.Market driver: Problems with plastic leather
2.10.Market driver: Regulatory drivers for alternative leather
2.11.Market driver: Brand actions driving change
2.12.Restraints for sustainable alternative leathers
3.ANIMAL LEATHER - PRODUCTION AND TRENDS
3.1.Animal leather overview
3.2.Animal leather overview
3.3.Animal leather - manufacturing processes
3.4.Animal leather manufacturing process flowchart
3.5.Leather cuts and coatings overview
3.6.Leather coatings overview
3.7.Leather cuts and applications
3.8.Leather tanning overview
3.9.Leather requirements for fashion accessories
3.10.Evolving tanning requirements
3.11.Disposal of animal leather
3.12.Global leather production by animal source
4.PLASTIC LEATHER - PRODUCTION AND TRENDS
4.1.Plastic leather overview
4.2.Sustainability trends in plastic leather
4.3.Plastic leather overview - continued
4.4.Plastic leather - manufacturing processes
4.5.Plastic leather - wet vs dry production methods
4.6.Global plastic leather production
5.LEATHER RECYCLING
5.1.Leather recycling overview
5.2.Life cycle of leather and recycling
5.3.Leather recycling processes - bonded leather production
5.4.Leather recycling processes - hydroentanglement method
5.5.State of technology development for recycled leathers
5.6.Recycled leather: SWOT analysis
6.SUSTAINABLE LEATHER ALTERNATIVES
6.1.1.Types of sustainable alternative leathers
6.1.2.Comparison of sustainable alternative leathers - production processes
6.2.Mycelium Leather
6.2.1.Mycelium leather overview
6.2.2.Mycelium leather - production process
6.2.3.Inoculation of the mycelium
6.2.4.Growing mycelium - conditions
6.2.5.Processing mycelium into leather
6.2.6.Tanning and dyeing of mycelium leather
6.2.7.Ecovative Design - Forager Hides
6.2.8.State of technology development and market for mycelium leather
6.2.9.Mycelium leather: SWOT analysis
6.2.10.State of technology development for mycelium leather
6.3.Plant-based Leather
6.3.1.Plant-based leather overview
6.3.2.Plant-based leather - production processes
6.3.3.Plant-based leather - textile-based production process
6.3.4.Plant-based leather - bio-composite production process
6.3.5.Plant-based leather: Sourcing feedstock
6.3.6.Processing of plant fibers for leather
6.3.7.Textile backings made from plant-based materials
6.3.8.Plant-based leather: SWOT analysis
6.3.9.Plant-based leather - company landscape
6.3.10.State of technology development for plant-based leather
6.4.Microbial Leather
6.4.1.Microbial leather overview
6.4.2.Microbial leather - production process
6.4.3.Microbial leather - fermentation conditions
6.4.4.Microbial leather - harvest and finishing
6.4.5.Microbial leather: SWOT analysis
6.4.6.State of technology development for microbial leather
6.5.Lab Grown Leather
6.5.1.Lab grown leather overview
6.5.2.Lab grown leather - production process
6.5.3.Lab grown leather: Cell biopsy and culture
6.5.4.Corium Biotech
6.5.5.VitroLabs Inc
6.5.6.Lab grown leather: SWOT analysis
6.5.7.State of technology development for lab grown leather
6.6.Other technologies
6.6.1.Protein-based leather
6.6.2.Mycelium powder-based leather
6.6.3.Sustainable coatings and dyes for leather
6.6.4.Plant-based coatings for leather - Von Holzhausen
7.MATERIAL PROPERTIES OF EMERGING ALTERNATIVE LEATHERS
7.1.Definitions of material properties relevant to leather
7.2.Selected performance standards for leather by application area - ISO, ASTM, AATCC
7.3.Selected performance standards for leather by application area - LHCA
7.4.Comparison of emerging alternative leathers - physical properties and performance
7.5.Compiled data on materials properties of emerging alternative leathers
7.6.Material properties of emerging alternative leathers: tear strength
7.7.Material properties of emerging alternative leathers: Tear strength
7.8.Material properties of emerging alternative leathers: Tensile strength
7.9.Material properties of emerging alternative leathers: Tensile strength
7.10.Material properties of emerging alternative leathers: Bally flexing
7.11.Material properties of emerging alternative leathers: Bally flexing
8.BENCHMARKING OF EMERGING ALTERNATIVE LEATHER
8.1.Considerations in comparing alternative leather materials
8.2.Benchmarking metric: Appearance
8.3.Benchmarking metric: Plastic content
8.4.Benchmarking metric: Price
8.5.Benchmarking metric: Technology readiness level
8.6.Benchmarking metric: Scalability
8.7.IDTechEx benchmarking of emerging alternative leathers
8.8.Benchmarking: Plant-based leathers
8.9.Benchmarking: Mycelium based leathers
8.10.Benchmarking: Microbial leather and other
8.11.Comparison of sustainable alternative leathers - price of commercial products
8.12.Price vs plastic content in plant-based leathers
9.MARKET LANDSCAPE OF EMERGING ALTERNATIVE LEATHER
9.1.Company and Investment Landscape
9.1.1.Sustainable alternative leathers - company landscape
9.1.2.State of technology development for sustainable alternative leathers
9.1.3.Business models for sustainable alternative leather players
9.1.4.Investment landscape for emerging alternative leathers
9.1.5.Investment landscape of emerging alternative leathers by company
9.1.6.Evolving focus: Bolt Threads and Modern Meadow
9.1.7.Scaling production: Bolt Threads
9.1.8.Intellectual property landscape: Mycelium leather
9.2.Applications for Emerging Alternative Leathers
9.2.1.Applications of emerging alternative leathers
9.2.2.Go-to-market strategy for emerging alternative leathers
9.2.3.Requirements for automotive leather
9.2.4.Commercial activity in emerging alternative leathers: Overview
9.2.5.Commercial activity in emerging alternative leathers: Limited launches/collections
9.2.6.Commercial activity in sustainable alternative leathers: Higher volume applications
9.2.7.Recent developments in the emerging alternative leather market
10.FORECASTS FOR EMERGING ALTERNATIVE LEATHER
10.1.Forecast methodology
10.2.Emerging alternative leather market forecast
10.3.Emerging alternative leather market forecast
10.4.Trends for emerging alternative leather
10.5.Trends for emerging alternative leather
11.APPENDIX
11.1.Emerging alternative leather market forecast
11.2.Emerging alternative leather market forecast
11.3.Key players in the leather recycling market
11.4.Key players in the leather recycling market
11.5.Mycelium-based leather company list
11.6.Mycelium-based leather company list
11.7.Plant-based leathers company list
11.8.Plant-based leathers company list
11.9.Plant-based leathers company list
11.10.Plant-based leathers company list
11.11.Microbial leather companies list
11.12.Lab grown leather companies list
 

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レポート概要

スライド 175
フォーキャスト 2034
発行日 Jan 2024
ISBN 9781835700082
 

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