Shreya Raghorte’s Post

What are regenerative materials? Or should we say restorative materials? How to create a sustainable bioeconomy? These are complex topics! Materiom and Metabolic have written some very helpful guidance addressing these questions: https://lnkd.in/egVECGRv https://lnkd.in/dQ9VUM8P #biobased #regenerative #impact #restore #restorative #bioeconomy #circular

🌍 Driving Sustainability: The Rise of Degradable Bioplastics 🌍 With the global focus on reducing #plasticpollution and creating a circular economy, the #degradablebioplastics market is gaining momentum. Bioplastics offer a sustainable alternative to traditional plastics, delivering reduced environmental impact without compromising functionality. 📈 Key Market Insights According to Knowledge Sourcing Intelligence, the degradable bioplastics market is projected to see significant growth as industries such as #packaging, #agriculture, and #healthcare embrace sustainable solutions. Innovations in compostable and #biodegradable materials are driving this trend, making eco-friendly materials more accessible and effective. 🌱 Why Bioplastics Matter Reduced Carbon Footprint: Made from renewable resources, bioplastics help lower greenhouse gas emissions. Degradability: These materials break down naturally, reducing landfill waste. Versatile Applications: Suitable for use in various sectors without compromising quality. Learn more about how degradable bioplastics are shaping a greener future: https://lnkd.in/ge3rR3WY #Sustainability #Bioplastics #GreenEconomy #EcoFriendly #CircularEconomy #MarketTrends #SustainableFuture #BusinessGrowth

In recent years, the global focus on environmental sustainability has spurred significant innovations in various industries, including packaging. Biodegradable packaging has emerged as a promising solution to mitigate the environmental impact associated with traditional packaging materials, particularly plastics. Actually what is Biodegradable Packaging ?? Biodegradable packaging refers to materials that are capable of being broken down naturally by microorganisms such as bacteria, fungi, and algae. Unlike conventional plastics derived from fossil fuels, which can persist in the environment for centuries, biodegradable materials undergo a decomposition process where biological agents metabolize their molecular structure. This breakdown ultimately transforms them into simpler, stable compounds that integrate harmlessly back into the ecosystem. The timeframe for biodegradation varies depending on environmental conditions but generally ranges from a few months to several years. Biodegradation is a natural process facilitated by microorganisms present in the environment. When biodegradable materials are exposed to moisture, heat, and microbial activity in soil, composting facilities, or marine environments, microorganisms secrete enzymes that catalyze the breakdown of complex molecules into simpler compounds. This process continues until the material is fully converted into water, carbon dioxide, methane, biomass, and other natural substances that reintegrate harmlessly into the ecosystem. biodegradable packaging stands at the forefront of sustainable innovation, offering a pathway to reduce environmental impact, conserve natural resources, and foster responsible consumption patterns. By embracing biodegradable materials in packaging, stakeholders can collectively contribute to preserving biodiversity, mitigating climate change, and creating a healthier planet for all. #innovateforclimate #SSCCA #ClimateAwareness #ActOnClimate #EcoAction #ClimateMitigation #EnvironmentalEducation #StudentSocietyForClimateChange

A circular bioeconomy provides a framework for transforming industries by reducing waste and improving sustainability. The succesful transition to circular bioeconomy will require investments and incentives, consistent policies and long term policy commitment. #bioeconomy #circularbioeconomy #sustainability #biorefinery #biotechnology

Exciting Developments in Sustainable Materials! Did you know that the future of packaging and materials lies in bioplastics, biodegradable, and compostable materials? At 21 Century Polymers, we're passionate about sustainability, and these innovations are at the forefront of our efforts. Bioplastics offer a renewable alternative to traditional plastics, derived from sources like corn starch or sugarcane. They reduce our reliance on fossil fuels and decrease carbon emissions. As per defination, Biodegradable materials break down naturally over time, reducing environmental pollution and waste accumulation. They're a crucial step towards a cleaner planet. Compostable materials take it a step further, breaking down into organic matter that enriches soil when properly composted. However, there's room for improvement. Biodegradable/compostable materials in current form require controlled conditions for decomposition, limiting their widespread effectiveness. Imagine if they could compost in any environment! What are your thoughts on the future of sustainable materials? Share your opinion in this survey: https://lnkd.in/dUUuqEm8 Let's shape a greener future together! 🌿 #Sustainability #Bioplastics #Biodegradable #Compostable #GreenFuture

Preserve Online Survey: The EU PRESERVE project aims to replace current packaging with biobased alternatives that provide high product protection and can be upcycled, recycled, or composted after use. New packaging solutions made from renewable raw materials and subsequent upcycling applications for the aim to contribute to the circular economy of packaging by not only optimally protecting [...]

“Our approach improves the economic viability of industrial biomanufacturing, offering manufacturers a more sustainable method of waste management; creating safe, low-footprint alternatives to synthetic plastics; offering additional energy-cost and water-use savings; and helping plastic converters and brands better appeal to their customers while meeting circularity/sustainability goals.” Learn more about how member Ourobio is accelerating and supporting the circular bioeconomy:

🌟Turning Waste into Gold!🌟 At Sparklo, we thrive on cutting-edge innovations hence we are excited to share ETH Zürich's recent breakthrough in turning e-waste into gold! Leveraging a protein sponge derived from food industry byproducts, they’ve discovered a way to recover precious metals from electronic waste, showcasing a brilliant intersection of sustainability and innovation. The results are detailed in the article "Gold Recovery from E-Waste by Food-Waste Amyloid Aerogels," by Fabio Bergamin, published in Advanced Materials♻️✨ 🔑 Key Results: - From 20 old computer motherboards, the team retrieved a 22-carat gold nugget weighing 450 milligrams - This method utilizes whey protein, a byproduct of cheese production, making it both sustainable and cost-effective. The gold's value is 50 times higher than the aerogel's production cost - Whey protein is used to craft a highly adsorbent aerogel, which is three times more efficient than typical activated carbon adsorbents - While currently focused on gold, this technology could be adapted to recover other valuable metals from e-waste in the future At Sparklo, we may not turn waste into gold, but we do turn waste into rewards! Our commitment to sustainability and innovation drives us to continuously seek out and support groundbreaking research and technologies like this one from ETH Zurich. Together, we can transform waste into valuable resources, fostering a more sustainable future for all. Get Sparklo App <sparklo.com/app> and start your recycling journey now! 🌍🔄

A recent paper from SSRN explores the integration of bio-based, biodegradable, and compostable (BBCMs) materials into a circular economy framework, emphasizing their potential to enhance sustainability in various industries. The research examines the life cycle of such materials and products, from production to disposal, highlighting their environmental benefits over traditional plastics. It also discusses regulatory challenges and market opportunities, underscoring the importance of innovation and collaboration among stakeholders to drive the adoption of BBCMs. 🔑 Key insights: ⚫ The life cycle analysis of biopolymers in sustainable applications. ⚫ Regulatory frameworks that support the adoption of BBCMs. This study serves as a vital resource for understanding how biopolymers such as PHAs can contribute to a more sustainable and circular economic model, reducing dependency on fossil fuels. 🔍 Read more: https://lnkd.in/emaVhHjp #Sustainability #Biopolymers #CircularEconomy #EnvironmentalImpact #Innovation #Research

Biodegradable, Recyclable, and Renewable Polymers as Alternatives to Traditional Petroleum-based Plastics These polymers are produced using renewable Natural sources such as plants and microbes to reduce reliance on fossil fuels and minimising plastic pollution Biodegradable polymers offer end-of-life solutions through composting or natural breakdown, reducing plastic pollution. Interesting Review Article https://lnkd.in/d22f_Dnr