Zenfold Sustainable Technologies’ Post

The Eco-Friendly Revolution: Discover the Power of Green HPLC ❓ What if your lab work could not only advance science but also protect the planet? Green HPLC is reshaping chemical analysis with eco-friendly alternatives—want to know what makes it so revolutionary? ⁉ Traditional HPLC relies on large volumes of organic solvents like acetonitrile and methanol, which can be harmful to the environment and costly to dispose of safely. Green HPLC steps in as a game-changer, replacing these solvents with greener options such as ethanol, isopropanol, and even water-based solutions. These alternatives are less toxic, biodegradable, and often cheaper, making them a win for both your lab and the environment. #gogreen #ecofriendly #safetoenvironment Not only does Green HPLC reduce solvent use, but it also minimizes energy consumption by optimizing processes to be faster and more efficient. So, while you’re lowering your carbon footprint, you’re also improving productivity and cutting costs—two things every lab can get behind! Green HPLC is the perfect blend of innovation and sustainability, helping labs worldwide operate cleaner and smarter. Ready to swap hazardous chemicals for greener solutions? Lets Jump into the future with Green HPLC and lead the eco-friendly transformation! #saferanalysis #cleanerwaste #lessenergery #efficient #chemistry #hazard #pharma #industry #innvoation #sustainable

“Chemistry in Water” is a green technology that enables the sustainable synthesis of APIs and intermediates. 💧 Why water? While water is an unconventional choice in chemical synthesis, it can be used to minimize waste, enhance reactions, boost product yields, and reduce energy use. However, many chemical components and even endogenous substances do not dissolve in water. Discover how Chemistry in Water uses nature-inspired tricks to facilitate organic reactions in our video: 🎦 https://lnkd.in/e3cbSyYi   🌍 Sustainability drives us! Learn more: https://lnkd.in/e4vP5aVU   #Evonik #ChemistryInWater #SustainableChemistry #Pharmaceuticals #sustainability Evonik Health Care

🌿 Driving Green Chemistry in Specialty Chemicals: A Free Resource for Chemical Manufacturers! Sustainability is no longer just a buzzword—it’s a must-have in the chemical industry. As a chemical manufacturer, integrating green chemistry practices into your operations can drive innovation and improve your environmental impact. At X3 Consulting, we’re excited to offer a FREE download of our latest guide: How to Drive Green Chemistry in Specialty Chemicals. This guide provides actionable insights on implementing sustainable practices while optimising production processes. 🌍 ➡️ Download the free guide today and start making a positive impact: https://buff.ly/4hpe5ST #GreenChemistry #Sustainability #ChemicalManufacturing #SpecialtyChemicals #SageX3 #FreeResource #SagePartner

Creating chemicals has a huge footprint. This 2023 Ray of Hope finalist based on cellular processes to produce industrial chemicals sustainably https://buff.ly/4dCfNOt more > https://buff.ly/3YnQVG5 #biomimicry #innovation inspired by #nature asknature Learn Biomimicry Biomimicry 3.8

Are you pondering the switch from traditional chemical synthesis to #biocatalysis for your industrial processes? It's a big decision, and we understand that you need all the facts to make the right choice. That's why we've put together a detailed blog post to help you out by answering questions like: What does it mean for your business in terms of cost, speed, and sustainability? And how tools like ZYMSCAN can make this transition smoother than ever? Discover the efficiencies, sustainability benefits, and perhaps some surprising advantages of using #enzymes that could transform your business 👇 https://lnkd.in/d2qQm56c #GreenChemistry #SustainableInnovation #ChemicalSynthesis

Discover innovation with our key chemical products. Leading the way in industry excellence. #ChemicalInnovation #IndustryLeaders #Sustainability #ChemicalSolutions #ChemicalIndustry #ProductInnovation

🔬 From Harsh to Harmonious: The Future of Chemical Processing  Traditional chemical manufacturing can be energy-intensive and environmentally harmful. But what if there was a way to reduce the impact without sacrificing efficiency or driving up costs? Our latest blog explores how bio-based innovations are paving the way for a cleaner, safer, and more efficient future in chemical processing. Curious about the shift from harsh to harmonious? 🔗read more here: https://lnkd.in/eARi72kJ Intrigued by our technology and want to learn more? Start a conversation: products@hydregenoxford.com #ChemicalProcessing #Sustainability #downstreamprocessing #BioManufacturing #HydRegen #CleanEnergy #GreenChemistry

James Kennedy, IDTechEx, explores #dissolution and the entire advanced #plasticrecycling market in the report: Chemical Recycling and Dissolution of Plastics 2024-2034: Technologies, Players, Markets, Forecasts. Read more >>https://lnkd.in/eYmd_SQq #PlasticWaste #ChemicalRecycling

The Urgency of Choice -Traditional vs. Green Chemistry! The dichotomy between traditional chemical manufacturing and green chemistry presents us with a clear choice. On one hand, we see the lasting damage of outdated practices — pollution and environmental degradation. On the other hand, the promise of green chemistry offers a pathway to innovation, sustainability, and restoration. At Zenfold Sustainable Technologies, we're committed to leading this transformation. We innovate and implement sustainable solutions that not only respect our environment but enhance it. So, let us know in the comments, isn't it time to make the switch? #sustainability #pharmaceuticals #innovation #innovativesolutions #zenfold

N. Lahfaidh, N. Guigo, L. Vincent, N. Sbirrazzuoli. Exploring and Understanding the Recycling of a Bio-Based Epoxy Thermoset via Saponification July 2024ACS Sustainable Resource Management DOI: 10.1021/acssusresmgt.4c00207 The chemical recycling of a fully biobased thermoset has been investigated by developing an innovative in-situ monitoring methodology. Within this study, two distinct recycling pathways utilizing KOH/EtOH or NaOH/water were successfully developed for the solvolysis process of SuccELO, an epoxy/acid cross-linked polymer, by targeting its fragile ester bonds. The solvolysis was monitored by calorimetry, FT-IR, mass loss measurements and optical microscopy. The kinetic parameters evaluated by calorimetry have been interpreted in terms of solvolysis mechanisms and used to discriminate four stages of the recycling process, beginning with a diffusion-controlled stage. The second step combines both diffusion and solvolysis, the later process corresponding to formation of carboxylate ions. A third stage was identified and is associated to an autocatalytic step driven by formation of sodium salts, acting as a solubilizer for triglycerides. Finally, the diffusion of small chains is identified as the rate-limiting step at the end of the process. Validation of these findings is reinforced by comprehensive surface analysis, using microscopy and FT-IR techniques. Besides the novelty of monitoring solvolysis by calorimetry, a simulation tool was developed based upon this method. These simulations were compared with mass loss measurements, highlighting drawbacks in the procedure used for these mass loss tests. Lastly, it is shown how prediction of the solvolysis at various temperatures not experimentally accessible, can be achieved using kinetic modeling, facilitating process design and optimization strategies.