Sustainable Economy and Ecotechnology (SEE) Conference的动态

The recent news about the bioeconomy model reaffirms the urgent need to shift away from extractive practices towards a renewable and sustainable approach. The bioeconomy offers a transformative solution, where businesses can thrive by harnessing the power of renewable resources and sustainable processes. Imagine an economy where production is regenerative, waste is minimized, and conservation is prioritized. This isn't just a vision; innovative companies are already leading the way in bio-based materials, bioenergy, and sustainable agriculture. The bioeconomy isn't just about mitigating environmental damage; it's about unlocking new opportunities for growth and innovation. By embracing the bioeconomy, businesses can position themselves at the forefront of a global shift towards a more sustainable future, where prosperity and sustainability go hand in hand. #bioeconomy #sustainability #innovation #circulareconomy #futureofbusiness https://lnkd.in/gKMezusy

??Unlocking Economic Benefits with Algae-Based Wastewater Treatment?? ? In today's world, innovative solutions to environmental challenges are crucial. One such?approach is algae-based wastewater treatment, which not only cleans our water but also brings substantial economic benefits. This nature-based technology champions sustainability while driving substantial cost savings and revenue growth. ? ?? Why Algae? Algae are nature's little powerhouses, capable of absorbing nutrients and contaminants from wastewater. This process results in cleaner water and a host of valuable by-products. ? ?? Economic Advantages: 1. Cost-Effective Treatment: Algae can significantly reduce the operational costs of wastewater treatment plants by lowering the need for expensive chemical treatments. 2. Energy Savings:?Traditional methods are energy-intensive, but algae-based systems harness natural processes, slashing energy consumption by an impressive 60% and reducing associated costs by atleast 30%. 3. Valuable By-Products: Algae produce biomass that can be converted into biofuels, bioplastics, premium animal feed additives, biofertilizers, and high-value chemicals, opening new revenue streams. 4. Carbon Capture: Algae naturally sequester CO2, which can be monetized through carbon credits, adding another layer of financial incentive. AgroMorph's innovative CCUS integration captures 100 tons of CO2 and treats 1.6 million liters of water daily, exemplifying this benefit. 5. Job Creation: The growth of this green technology can spur job opportunities in research, operations, and maintenance. ? ?? Sustainability at its Core: Beyond the economic benefits, algae-based wastewater treatment aligns with global sustainability goals. It reduces pollution, lowers greenhouse gas emissions, and promotes circular economy principles by turning waste into resources. ? ?? The Future is Green: Embracing algae-based technologies can propel us towards a cleaner, greener, and more profitable future. As industries and municipalities look for sustainable and cost-effective solutions, algae-based wastewater treatment stands out as a win-win. ? Join us in redefining the landscape of wastewater treatment, where every drop and every ton of CO2 captured translates into a sustainable bottom line and a greener future. ? #EconomicAdvantages #SustainableSolutions #Innovation #AgroMorph ?????? #Sustainability #WastewaterTreatment #GreenTech #CircularEconomy #Bioeconomy #AlgaeInnovation #CleanWater #EcoFriendly

?? Key #Characteristics of the #Bioeconomy ?? The bioeconomy is revolutionizing our approach to sustainability and innovation. Here are its key characteristics: 1. #Renewable Resources: Utilizes biomass, plants, algae, and waste materials, ensuring resources can be replenished. 2. #Sustainability: Focuses on reducing environmental impact through sustainable agricultural practices and renewable energy. 3. #Innovation: Leverages advancements in biotechnology, synthetic biology, and green chemistry to develop new products and processes. 4. #Circular Economy: Promotes the reuse, recycling, and regeneration of resources, minimizing waste and environmental impact. By embracing the bioeconomy, we can create a sustainable and resilient #future. Let's innovate for a greener tomorrow!?

Happy to share that our review titled "Toward Green and Sustainable Zinc-Ion Batteries: The Potential of Natural Solvent-Based Electrolytes" has been published in Small with open access. This perspective review aims to explore the potential of biomass-derived materials to be utilized as natural solvents for zinc-ion battery electrolytes, focusing on their sustainability, effectiveness, and ability to enhance battery performance. #naturalsolvent #electrolyte #solvationregulation #zincionbatteries

???? Together we can change the course! ???? As concern for the environment grows every day, it is essential to address one of the greatest challenges of our time: the problem of waste. ????? ?? At BioReCer, we believe that every challenge is an opportunity for innovation and positive change. And we want to listen to you, because your opinion counts in the search for sustainable solutions. ???? ? What ideas do you have for improving certification systems for products from bio-based waste? What is missing from current certification frameworks? Share your perspective in the comments and join our mission for a cleaner and more sustainable future. ???? You can register here: https://biorecer.eu/brsp/ Here for the Webinar: https://lnkd.in/eYTjuUjV #BioReCer #Certification #EcoLabelling #BioBased #CircularBiomass #BioFeedstock

??????????: ?????? ???????? ?????? ?????????? Algae, once seen as pond scum, is being investigated as a powerful renewable energy source. It produces biofuel more efficiently than crops like corn, absorbs CO2 rapidly, and can thrive in non-farmable environments like wastewater and deserts, offering a carbon-negative solution without competing with food production. Why algae? ???????? ????????????: Algae can double its mass in a day, making it a highly efficient energy source. ???????????? ??????????????: Algae farms can act as natural carbon sinks, capturing CO2 and reducing emissions. ??????????-??????: Beyond fuel, algae is also being researched for its potential in biodegradable plastics and sustainable packaging. Research is still in its early stages, but some companies are pulling out due to the high investment of time and money yielding only modest results. Never say never... ??????????????: ????????????????????????????????????????????.??????

The biological cycle in the circular economy showcases how bioeconomy strategies can transform organic waste into valuable resources. By converting bio-waste and biomass into biobased products, biofuel, and biogas, we enrich organic resources, improve soil health, and recover renewable energy. This closed-loop system promotes sustainability by recycling and reusing materials, ultimately supporting the production of food, plants, and other green goods. However, the bio circular economy faces unique challenges compared to the traditional circular economy. These include the complexity of processing organic materials, ensuring the stability and efficiency of bioprocesses, and integrating biobased solutions into existing industrial systems. Addressing these challenges requires advanced biotechnologies, robust regulatory frameworks, and significant investment in research and development. Together, we can drive a more sustainable future through innovative bioprocessing, tackling these challenges head-on to fully realize the potential of the bio circular economy. #Bioeconomy #CircularEconomy #Sustainability #RenewableEnergy #BiobasedProducts #Organic #GreenTech #WasteManagement #EnvironmentalScience #Innovation #CleanTech #Biotechnology #R&D #RegulatoryChallenges #SustainableFuture #EcoInnovation #GreenSolutions #ResourceEfficiency #BioTech #Renewables #CircularSolutions #SustainableGrowth #ClimateAction

?? ?????????????????????????????? ?????????????????? ????????????: ???????????????????? ???? ?? ?????????????????????? ???????????????? ?????? ?????????????????? ???????????????????? As the global demand for energy surges alongside rising concerns about climate change and fossil fuel depletion, the quest for sustainable alternatives has never been more critical. Microalgae emerge as a groundbreaking feedstock for biodiesel, offering a viable solution that addresses both energy needs and environmental concerns. ?? Why Microalgae? Microalgae, unlike traditional biofuel sources, do not compete with food crops for land or resources. They can be cultivated in wastewater, brackish water, or even saline environments, significantly reducing the freshwater burden. With higher oil yields than terrestrial crops, microalgae can produce substantial amounts of oil which can be converted into biodiesel, presenting a sustainable alternative to fossil fuels. ?? Environmental Benefits: - Carbon Capture: Microalgae have the remarkable ability to capture carbon dioxide, helping mitigate greenhouse gas emissions. - Biodiversity Protection: Utilizing non-arable land for cultivation safeguards food production and biodiversity. - Biodegradability: Biodiesel derived from microalgae is highly biodegradable and non-toxic, reducing environmental pollution. ?? Current Advances and Challenges: Research and development in microalgal technology have made significant strides. Innovations in cultivation systems and genetic engineering have enhanced yield and efficiency, making microalgae a more feasible option for large-scale production. However, challenges remain in reducing production costs and achieving economic viability, necessitating continued innovation and investment in this sector. ?? Future Perspectives: With the potential to meet and surpass global energy demands sustainably, microalgae-based biodiesel could revolutionize energy consumption patterns worldwide. The integration of microalgae cultivation with industrial processes for carbon capture and wastewater treatment could create a circular, zero-waste economy, propelling us towards a more sustainable future. As we advance, the role of industries, governments, and researchers becomes pivotal in supporting this sustainable energy transition. Investing in microalgal research and biorefinery technologies not only aids in combating climate change but also in fostering economic growth through green jobs and energy security. #Sustainability #RenewableEnergy #Biofuel #Microalgae #Biodiesel #GreenTech #CleanEnergy #ClimateAction

While October underscores the importance of energy awareness, we should continue to prioritize energy efficiency and sustainability throughout the year. In the article below??Mirá Biotech highlights its innovative biofuel pellets as a sustainable alternative to traditional energy sources, emphasizing the critical role of moisture content in pellet performance.?? #PoweringOurPlanet #BiofuelRevolution #SustainableEnergy #MiraBiotech #EcoFriendly #GreenFuture #CleanEnergy #RenewableResources #BiotechInnovation #ClimateAction #UNEnvironment #350org #TheNatureConservancy #NationalGeographic #CleanTech #EnvironmentalDefenseFund #InternationalRenewableEnergyAgency #RenewableEnergy #Biotechnology #SustainableAgriculture #DOE #CircularEconomy #EnergyEfficiencyMonth #CrunchTime

"I am so excited to give an opening plenary speech at the T2R2 conference based on my 20 years of research on biochar linked with ESG and sustainability." ScholarGPS has just released the impact ranking of biochar researchers among over 40,000 scientists, and I found that I am ranked #1 for this particular year. Below are the details of my presentation along with the conference proceedings. I will share my final presentation file to provide more information to our communities and young scholars. Biochar from Biomass and Waste for Circular Economy and ESG Biochar has gained worldwide interest over the past decade because it encompasses high-priority research areas, including bioenergy production, global warming mitigation, and sustainable agriculture. This lecture on Biochar from Biomass and Waste series will provide the fundamentals of biochar, covering its basic concepts, production technology, and characterization methods, along with comprehensive examples for participants. The presentation includes information on state-of-the-art biochar application technologies in the fields of agriculture, energy, and environmental sciences, featuring step-by-step case studies linked to the circular economy and ESG. Here, I will primarily discuss: 1) a comprehensive coverage of biochar production, characterization, and modification methods; 2) global case studies covering a wide range of application fields, including environmental, agricultural, syngas, and bio-oil; and 3) the sustainability and future of biochar.An important example of corporate sustainability using biochar is Microsoft's initiative to become carbon negative by 2030. Many global companies are investing in carbon capture and storage technologies, including the production and utilization of biochar, to offset its emissions. By integrating biochar into its sustainability strategy, Microsoft not only aims to sequester carbon from biomass but also improve soil health, enhancing agricultural productivity and resilience. This demonstrates how organizations can effectively utilize biochar as part of their commitment to sustainability and environmental stewardship. Key words:?ESG, Sustainability, Carbon negative, CCUS, Plastic pollution ??