Fabric signature smart materials for substance 3d painter A pack of 32 High-Detail and completely customizable Smart Materials …
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Labelexpo Europe Showcases Revolutionary Beontag Labeling Solutions and Cutting-Edge Smart Tag Technologies
Beontag, a leading manufacturer of pressure-sensitive labeling materials and smart tags, will exhibit at Labelexpo Europe 2025 in Barcelona. The company will showcase its portfolio, including self-adhesive materials, hot melt solutions, and specialized materials for tickets and tags. Beontag will highlight its innovations in digital solutions, such as its IoT portfolio featuring over 80 standard RFID products and 2,000+ customized solutions. Some notable products include wash-off labels for easier recycling, ScandArtisan textured substrates for premium glass applications, and RFID smart labels for tracking and authentication. The company will also participate in thought leadership programming, with speakers discussing smart labeling and pressure-sensitive labeling trends. Beontag’s CEO, Alejandro Quiroz Centeno, emphasized the company’s commitment to sustainability, performance, and customer focus, and expressed pride in its comprehensive offering at the event. The exhibition will take place from September 16-19 at Booth 3B101.
Scientists Reveal Breakthrough in Customizable 4D Printing Technology
Researchers at the Harbin Institute of Technology have developed advanced 4D printed metamaterials that can change shape and properties in response to external stimuli such as heat, light, electricity, or magnetic fields. These smart metamaterials can twist, bend, stiffen, or soften, allowing them to adapt seamlessly to varying functions and tasks. The innovation represents a significant leap in metamaterial technology and paves the way for a new era of intelligent materials. The researchers have created multi-material, multi-responsive, and multi-shape gradient materials made from shape memory polymers, which can hold multiple shapes simultaneously and shift between configurations depending on the demands of the task. The potential uses for these versatile metamaterials are expansive and transformative, with applications in secure information storage, soft robotics, and aerospace engineering. The breakthrough marks an important step toward adaptive manufacturing technologies that can deliver unprecedented mechanical properties tailored to a wide array of applications. The researchers envision a future where materials are not just components, but integrated systems that interact intelligently with their surroundings, transforming technology and everyday life.
Fabric signature smart materials
Fabric signature smart materials for substance 3d painter A pack of 32 High-Detail and completely customizable Smart Materials …
EnrgEnv Smart Chemicals & Materials acquires licensed rights to newly developed technology from IIT Roorkee
The Indian Institute of Technology Roorkee (IIT Roorkee) has signed a Technology Transfer Agreement with EnrgEnv Smart Chemicals and Materials Pvt Ltd for a novel technology to produce nitrogen-enriched polytriazine. The technology, developed by Prof Paritosh Mohanty and Dr Monika Chaudhary, involves an ultrafast microwave-assisted synthesis method to create high surface area, nitrogen-enriched nanoporous polytriazines with various functional applications. This breakthrough has the potential to contribute to green energy, environment, and sustainable chemistry.
The agreement marks a significant step towards commercializing advanced materials science research and demonstrates IIT Roorkee’s commitment to translating research into real-world solutions. The partnership reflects the spirit of Atmanirbhar Bharat, emphasizing India’s commitment to indigenous innovation, green chemistry, and smart manufacturing. The industry partner, EnrgEnv Smart Chemicals and Materials Pvt Ltd, aims to take the innovation to the next stage and develop sustainable and scalable solutions for emerging sectors. The successful transfer strengthens the bridge between academia and industry, marking a milestone in technology adoption and sustainable development.
The medical foam industry is projected to reach a value of USD 11.84 billion by 2035, driven
The medical foam market is expected to reach $11.8 billion by 2035, growing at a CAGR of 4.2%. The market is driven by increasing hospitalizations, rising surgical volumes, and demand for lightweight, durable, and infection-resistant materials. Medical foams, such as polyurethane, polyolefin, and silicone, are used in applications like wound care, surgical draping, prosthetics, and medical packaging. Manufacturers face challenges like raw material price volatility and infrastructural bottlenecks, but advancements in technology and innovation offer solutions. The market is highly competitive, with key players like 3M, Freudenberg Performance Materials, and Sekisui Chemical Co. leading through innovation and scale. Emerging players are gaining traction with custom-engineered, antimicrobial, and breathable foams. To succeed, manufacturers must focus on customized solutions, regulatory compliance, sustainability, and technology integration. The market’s growth varies by region, with North America, Europe, and Asia-Pacific offering tailored opportunities for manufacturers and payers. By aligning product development with regional trends and clinical requirements, companies can deliver high-value, patient-centric solutions and drive growth in the medical foam market.
European Commission’s HORIZON grant awarded to innovative smart materials project X-CELERATE
The X-CELERATE project aims to advance the development of innovative materials design by pushing the boundaries of next-generation 4D X-ray CT tools. The project, led by the University of Antwerp, brings together 14 academic and industrial partners from across Europe. The goal is to create dynamic and adaptive systems that can change their form in response to their environment, a technique known as 4D printing. The project focuses on integrating smart materials, such as shape memory materials, into responsive systems.
The lack of real-time data about how these materials behave during transformation has been a major obstacle. X-CELERATE will address this by introducing new phase contrast imaging methods and quality control protocols. The project’s impact will be seen in healthcare innovations, greener manufacturing processes, and greater accessibility. It will also contribute to the development of highly skilled talent for the future. The project’s lead researcher, Sepideh Ghodrat, emphasizes the importance of advancing Europe’s manufacturing industry while addressing critical societal challenges, and is committed to building a more sustainable, inclusive, and high-tech future for industry and society.
Global Facade Market Projected to Reach New Heights by 2033, Driven by Rising Demand for Energy-Efficient Materials and Strategic Regional Expansion Initiatives
The global façade market is expected to grow from USD 292.2 billion in 2024 to USD 534.0 billion by 2033, at a CAGR of 6.58%. The market is driven by rapid urbanization, infrastructure development, and demand for sustainable and energy-efficient buildings. Ventilated façades dominate the market, and materials such as glass, metal, and plastic are widely used. The market is segmented by product type, material, end-use sector, and region.
Technological innovation, regulatory environment, and infrastructure expansion are key growth factors. Governments are tightening regulations on building energy performance, driving the adoption of energy-efficient façade systems. Urbanization and infrastructure growth are also driving demand for high-quality façade installations. The market is expected to grow strongly in regions undergoing rapid urbanization and infrastructure expansion.
Key players in the market include Ajit Glafa India Pvt Ltd, Alfa Facade Systems Pvt. Ltd, and Saint-Gobain Glass India. The report provides a comprehensive analysis of the market, including market size, growth factors, and regional insights. It also offers customization options for clients requiring specific information not covered in the report.
3D Printing of Shape Memory Alloys part 1 with Mehrshad Mehrpouya
Are you still Living in the 3D printing era or have you heard of next generation printing of smart materials where the final Shape …
[Music] hi everybody Welcome to Everyday metalogy this episode is something I doubt you have ever heard of before uh normally we talk about 3D printing but today we taking it one step further we’re going into 4D printing if you know what it is well you’re one of the uh the first movers if you don’t know what it is I think you should uh stay here for the next about 24 minutes then for sure you will learn what uh 40 printing is because this is Advanced uh material technology enjoy the show hi merad hi Peter welcome to the podcast everyday metalogy thank you thank you for having me today we’re going to talk about uh some very special materials uh shape memory metals or shape memory materials because it’s not only metals it in in fact also polymers that can be shaped memory uh formed uh can you give a little background about yourself where you are uh and and what you work on yeah sure um I’m mer mer I am assistant professor at University of TWA the east of the Netherlands uh I’m a part of Department working on design production and management and a specific research group that we have in we are working on Advanced manufacturing so mainly what we do as the name States is on Advanced Manufacturing but most of the projects nowadays we are doing with the main focus on additive manufacturing processes yeah uh Melle I I read your book yeah and uh it was so inspiring so uh do if you have it nearby can you show it because I would love uh to share it with uh with people uh I learned so much about this that I needed to to talk to you yeah yeah um but uh first uh C can you give an introduction to what is a shape memory material yeah definitely um there are different type of smart materials already in the literature and also different research group working on that and one group nowadays at least in last two decades is quite famous and common are shape memory materials so we know shape memory materials mainly with shape memory Alloys or shape memory polymers but they are also the other type of shape memory materials that for example we know the type of shape memory gels or shape memory Ceramics in general shape memory materials are group of the material that have capability to return or revert to their original shape after a kind of deformation yeah and and this shape recovery that we call it can happen based on mainly a specific external stimula could be like temperature could be for example magnet field could be even chemical reaction like pach or mure light and and different things so this group of materials as I mentioned that we call it as a smart material can have a different application and also the different way we manufacture them produce a different product so what we are trying to do to try to understand the material well in the first step and second to understand how to make a new product based on that and use it for the different applications yeah uh so if if we dig into the history of it I I really like uh the the way I heard it was found was by an accident can can you disclose how how it was discovered yeah definitely um maybe the most famous story is about the shape memory Alloys um it was a Swedish um let’s say scientist arander in 1932 he discovered in his lab a specific behavior of the material and then he called it shape memory behavior and it was for a gold cadmium Alloys or composite and 193 uh 1932 seems was very early to discover such a material because 30 years later another scientist or researcher in novel laboratory in us his name was William bowler he discovered nichel titanium as a shape memory material and this is one of the most famous of the shape memory material so far and and lots of obligations in the different industry and then from that time 1962 and on board the application of this material become more common but we know most of the products after 200 in in 20 and nichel titanium Maybe a little bit more information about that we know it as also Niti and also n the other name yeah lots of application about that is for medical specifically and Aerospace applications and nowadays we discuss about how to manufacture them and this is the field I’m working on that yeah yeah I think the NIT no name was Nel tum and and the null was uh the the letters for the place it was uh discovered um this is new to me but the n as I know is n titanium so if if no is something additional I hear from you yeah I’m just disturbing because I have died a little deeper into the uh Nel material it was invented or found in uh 1959 at a Naval Research Center in in us uh in fact the material was uh meant for the cone of a missile because it was developed or the purpose was to develop a material that could take the heat from the re-entry in the atmosphere from the missile uh but more or less by accident uh the myologist working on it found that uh this material had different faces depending on what temperature was but first uh 2 years later in’ 61 uh they found what it uh what it really was so the the ability to work as a Memory Metal uh was not found day one but it took in fact two years to to find out that so back to the show and and I think think it was meant to be discovered as a high temperature material so they they made trials on high temperature applications it it failed but suddenly this new uh uh thing appear that it uh it it could return to its original shape after bending it true that is correct and we have a different type of research about the shape memory Alloys and even about nitinol or ni family so some group of the researchers working on developing a new type of Alloys with different functionality for example if you add additional elements to that increase their temperature or or decrease it so this is one thing people work on that and some people try to understand how to manufacture them instead of conventional manufacturing with additive manufact facturing the field I’m working in MH there are also some people try to use the material as it is for the design of the smart product or features and and this is also some another group of the people so sometimes all these three Fields let’s say work together for a specific purpose to for example as a project to make a specific smart product in the end of the day and that is the interesting field indeed yeah uh but now let’s dig a bit deeper into the technical issues because when when reading about it it’s so difficult to understand why it works so can can you describe what is happening inside the material this uh mtic formation then but it’s going up and down history races uh can can you help me understand better what is happening inside the material sure for for shape memory Alloys when we are talking about shape changing or shape recovery we are talking about a specific temperature that temperature is transformation temperature so mainly what happening is let’s say the changing the material phase from cooler temperature that we call it maride to higher temperature that we we we call it asite so changing the temperature of the phase of the material change the micro structure of the material and based on that that we have let’s call it that magic behavior of the shape memory materials I I can share a picture with you and and maybe that would help you understand it better yeah that could be nice yeah sure it’s it’s very abstract just to to imagine what is happening yeah so what you see here actually this is a typical stress strain diagram that we usually have in all materials but here that you see another AIS that one is temperature so I I want to go through the whole diagram and give this explanation because when we are talking about the shape memory Alloys we mainly talking about two different type of shape memory Alloys a part of them we call them super elastic material the other part we call them shape memory effect so again I back to the explanation I have and that’s one is related to the transformation temperature so the first one that you see here and I have a red dot on the picture yeah is the stress strain diagram and I want to show you a b and c so what we do simply we apply a load on the material and when we apply a load on the material what happened exactly yeah this is a super elasticity let me just this and I need to use also my marker to make it easier to understand yeah so what happened here exactly is when I apply load on the material and when I remove the load the material can come back to the original shape so why and this is because the material is already activated and the material in the aoid phase and what is happening in the super elasticity is exactly the moment that we apply a force in the state the material is activated and is above the transformation temperature however if I choose another type of material or I apply the loads in the temp temperature below the transformation temperature the second situation would happen and the second situation is shape memory effect yeah when I apply the shape they apply the load on the material like C D and E like you see and apply a force on that however I still have let’s say the deformation and the strain here in this area to be able to bring the material back or return it to the orig original shape and then I need to apply a heat on the material and for applying the heat on the material I heat it up the specific temperature and it is normally above the transformation temperature and then after that the material can get the original shape and come back to zero point if I want to give you a good understanding of that just follow the red point I’m already showing you here in this yeah two good example of these two super elastic and shape memory effect material the first one is a super elastic material so what you see in the hand of this person is super elastic NTI wire as I mentioned is already activated as soon as you remove the load from that come back to original shape so it is exactly this area Orange area I already mentioned and the second type of the material you apply low down there like this spring was deformed completely so I’m talking about the green area here and then you increase the temperature like here is heating on top of this stove and then material can recover this original shape so there are mainly two type of shape memory allo that we are using nowadays yeah yeah yeah it’s uh it’s pretty amazing uh when when you talk super elasticity what uh strain level are we at uh because most most material have certain level of elasticity but how much uh do you need before you can call it super elastic the level of strain that we are talking about is 7 to 9% of that however these seven or % could be also related to a different things how you manufacture the materials what is the composition of your materials and let’s say what is the state of the material and the shape and geometry of your material so sometimes in the design process we can play or tune with this strain rate for example imagine if you instead of using a bulk material like for example this pen in my hand use like a ltis structure in a specific shape and you can deform it more so somehow we can tune this strain and and and functional behavior of the material yeah yeah so it’s it’s not only the material is also design of the component on macro scale that is correct for example if I want to give you a real example following I show you earlier um it’s not you to use Niti or shape memory Alloys for a stand for example cardiovascular stands so it’s been long time there are shape memory let’s say a stand in the shape of like a tube shape and uh you know the way they make it uh is combination of conventional manufacturing and newer method so let’s say the con through the conventional manufacturing they make the tube shape of of Niti let’s say ni tube and in The Next Step H they use like laser cutting to make a specific shape of that like a spring shape and and based on cut out material that’s true and and based on that they can make it very flexible and move it to any Direction they want so the structure architect of the structure can help you to make uh or achieve a specific the formation you’re looking so the the typical manufacturing method is it uh melting casting and and then you can roll it and uh and make plates and sheets or are there other methods for manufacturing yeah you’re right um let’s say the main manufacturing process is still conventional so lots of product already available in the markets like in the shape of wires or tubes or let’s say uh stream or plates yeah but what the recent research not even recent let’s say in the last decades or 15 years people from the different groups and from different universities and also not universities research institutes try to subtitute that with the other type of manufacturing process for ex example when I’m talking about additive manufacturing and the whole philosophy of writing the book I show you earlier is exactly about that because what the researcher trying to do uh trying to find a new way to make a complex structures because thanks to additive manufacturing we can have it and we can make complex structure from different materials let’s call it from polymers to metals or Ceramics hydrog so the idea was how we can use additive manufacturing uh processes specifically for shape memory materials that doesn’t matter shape memory polymer or shape memory Al there are different type of manufacturing and 3D printing you can use it and and that’s why the initial idea of this book was okay if we can add or gather all this information from a different researcher all around the world and and and have it documented in in just one unique book and and then we did it so this book of course there are two editor myself and also my colleague Professor Alim but but each of these chapter is written with very famous uh let’s say researchers or research group they work specifically that topic so we have a researcher working on material development and discuss that in the book to let’s say different type of manufacturing process because when we are talking about additive Manufacturing is like powder based wire based DD lpbf and there are many many yeah yeah and and uh we have to remember my my heart is in power metal so oh okay so that’s also important to to mention that they can be shaped with po metall Roots uh yeah that is correct actually one of the uh main let’s say additive Manufacturing process is lpbf or totally PBF process and this is a PBF stand for powder bit Fusion yeah so we still have powder there and we need the powder and there are lots of businesses uh working on how to make high quality powder for different type of shape memory materials but the Ste NTI is a dominant material in the market and in most of application of the shape memory yeah uh meria there was one thing in the book that uh amazed me most it was a new term I’ve never heard it before uh it’s called 4D printing yeah I people have been talking about 3D printing for decade now so when I read this 40 printing it was what is that that is not possible so can you explain what it is what what is going on in 4D printing yes definitely U let’s say Ford printing if I put it in in in very simple way is let’s say integration of smart materials and additive manufact with additive Manufacturing Technologies so the the 3D printing technology exists already if we print a smart material with that then we can have a different let’s say uh shape of the material after the 3D printing because this smart material in response to external stimuli they can change their shape so these 4D or fourth dimension exactly because of that because du to or the response to the external stimuli they can’t change their shape or proper is over the time and that’s why instead of 3D printing of for example shape memory materials they call it 4D printing but I should be honest and say there are also some researcher they do not like to use 4D printing for that and they said there are still 3D printing with a smart material they do not have any problem so we can use both of them 3D printing of a smart materials or 4D print both of them are fine yeah uh and you have some examples on how you can change uh the properties or or add this uh the time scale to to a component and the function of it yeah definitely I have one simple example of for that and this example is for this time for shape memory polymers because of my research I work on both of shape memory Alloys and shape memory polymers although they have two different words and sometimes the researchers working on one they do not necessarily work on the other because we know the materials are totally different but for me is really interesting to learn from both of them and every day in the different research I learn from that so what I’m sharing with you right now is a let’s say a logo printed a print logo of the University of TW the university I’m working for so this is um let’s say a shape memory polymers if I want to be very a specific a combination of PLA and PPS biopolymer like what you see in the first picture is completely rigid material and printed like a normal other 3D printed Parts yeah so the point is you can deform these structures I can give you more explanation how you can deform because like shape memory Alloys that we have transformation temperature shape memory polymer that we have a specific temperature that we call it TG or glass temperature and above that that temperature material can be activated so the point is if you heat up the material above that temperature for example here in this case the TG something about 60° and we could heat up the material like 65 or something deform the material and if you cool it down and then the material get the new shape so the new shape that we see here is a deform shap yeah however if you heat up the material again above that temperature the material can return to the original shape so the video I show you here is the shape recovery of the deform logo and here what you see is happening in a hot water hot water means above that temperature and then the logo can come back to original shape so this is uh let’s say a very typical and common example of Ford printed part how we can recover the original shape and also same thing can happen also for shape memory allo specifically super elastic material so there are some examples and also publish in in the previous work that you can deform the material hit it up it come back to original shape H yeah that was the story about uh the the theory behind this 40 Printing and the shap memory materials in the next episode we’ll take a deeper dive into what is the real purpose of everyday metalog it is to talk about every day applications so come back uh in next episode we’ll uh go into real life [Music] [Music]
Room temperature reversible shape-shifting is made possible by advanced UV-activated smart materials.
Researchers from Pusan National University have developed magnetic smart materials that can change shape on demand using ultraviolet light. These materials, called disulfide-based covalent adaptable networks (DS-CANs), can fix and reconfigure shapes without solvents or resins, overcoming limitations of traditional shape-shifting polymers. When exposed to UV light or heat, the materials can permanently fix their shape, and an opposing magnetic field can reset them. The team demonstrated the creation of reprogrammable micropillar arrays and complex microstructures, such as shark-skin-inspired ribbed denticles. The technology has potential applications in tunable robotics and drug delivery. Unlike traditional methods, DS-CANs allow for infinite reversibility and can repair damage or weld components. The study, published in Advanced Materials, was a collaboration with Hanyang University and Dong-Eui University, and is scheduled to be featured on the cover in July 2025. This breakthrough addresses key limitations of earlier methods, including water sensitivity and irreversibility.
Innovative material solutions and their role in diabetic treatment and management, focusing on intelligent systems and therapeutic interventions.
A new publication in the Acta Materia Medica journal explores the potential of bioresponsive materials in advancing drug delivery systems for managing type 1 and type 2 diabetes. These materials respond to biological stimuli, such as pH and glucose, to enable controlled drug release. The article examines recent progress in designing and applying these materials, focusing on macromolecular insulin delivery systems and oral hypoglycemic agents. Despite promise, challenges remain in translating these technologies to clinical practice, including scalability and regulatory hurdles. Current shortcomings, such as frequent injections and adverse effects, are discussed. The analysis highlights the need for interdisciplinary approaches to address technical and practical constraints. Future directions include bridging material innovation with clinical needs to develop next-generation diabetes management systems. The publication provides critical insights into optimizing bioresponsive platforms for clinical translation, with the goal of enhancing therapeutic outcomes and quality of life for patients with diabetes.
Self-Healing Materials Revolutionizing Construction and Tech | The Future of Smart Materials
Self-Healing Materials Revolutionizing Construction and Tech | The Future of Smart Materials we explore the fascinating world of …
The Evolution of Space Habitats: How Intelligent Materials Are Revolutionizing Design
The prospect of life in space is becoming a reality, with missions to Mars and the Moon on the horizon. To create habitable dwellings, scientists are developing intelligent, responsive materials that can adapt to the harsh environment of space. These “smart materials” can change shape, color, or strength in response to stimuli such as temperature, pressure, and radiation. They can be used to create dynamic, living spaces that can transform and adapt to changing conditions. Examples include shape-memory alloys, self-healing polymers, and thermochromic coatings. Additionally, 3D printing with Martian regolith and smart binders can create insulating and long-lasting structures. Smart skins can also control climate and generate electricity, making habitats self-sustaining ecosystems. With the help of AI, these materials can even sense anomalies and repair themselves, creating autonomous habitats. The future of space habitats relies on these innovative materials, which will enable humans to build homes that can survive, adapt, and nurture life in extreme conditions.
Smart Materials And Systems Vtu Important Questions| BME306B
Smart Materials And Systems Vtu Important Questions| BME306B#vtu #vtuexams #bme306b #smsvtu #smsimportantquestionsvtu …
The global 4D printing market is anticipated to expand to a value of USD 1,326.50 million by the year 2032.
The global 4D printing market is expected to grow significantly from $251.7 million in 2025 to $1,326.50 million by 2032, registering a CAGR of 26.8%. This growth is driven by the increasing adoption of smart materials and programmable matter in high-impact industries such as defense, aerospace, and healthcare. The market is dominated by North America, particularly the USA, due to robust R&D investments in military and healthcare sectors. Key drivers include the need for dynamic and adaptive materials, government investments, and rising demand for smart medical devices. However, the market faces challenges such as high production costs, complex hardware and software integration, and lack of process standardization. Despite these challenges, the market is expected to surge, with opportunities emerging in space exploration, wearable tech, and regenerative medicine. Key players include Stratasys, HP, Autodesk, and 3D Systems Corporation. As the market continues to evolve, it is poised to redefine the future of manufacturing and smart design, with stakeholders who invest early expected to gain substantial competitive advantages.
SmarTV, Smartphones and how about having Smart Materials? #selfhealingmateriales
Unlocking Opportunities: A Peek into the Future of the Smart Materials Market
Here is a summarized version of the content in 200 words:
The Smart Materials Market is expected to grow from $84.78 Bn in 2025 to $148.15 Bn by 2032, with a CAGR of 8.3%. The market is driven by the increasing demand for advanced materials in various industries, including aerospace, defense, automotive, and healthcare. The report provides an in-depth analysis of the market, including insights into the market size, growth drivers, challenges, and opportunities.
The report identifies key players in the market, including Kyocera Corporation, Parker Hannifin Corp, Wright Medical Group N.V., and CeramTec GmbH. The market is segmented by product type, including piezoelectric materials, shape memory materials, electrostrictive materials, and others. Additionally, the market is segmented by application, including actuators and motors, transducers, sensors, and structural materials.
The report provides key analytics and market coverage, including market size, revenue forecasts, adoption rates, and competitive landscape. It also examines regulatory frameworks, technological advancements, and their impact on workflow automation within healthcare systems. The analysis highlights emerging trends, key players, and strategic developments shaping the industry.
Creality Falcon A1: A $549 smart laser cutter that intelligently detects material type before precision cutting
Creality’s Falcon A1 is an enclosed 10W laser engraver and cutter that promises to bring professional-grade capabilities to your desktop. The machine features an innovative material recognition system, which uses QR codes to automatically detect and load the optimal cutting or engraving parameters for various materials. This eliminates the need for guesswork and reduces waste. The Falcon A1 also has a fully enclosed design, Class 1 safety certification, and an emergency stop button. The machine can cut through 9.6mm acrylic and 5mm wood in a single pass, and has a working area of 381 x 305mm. The camera system allows for real-time viewing of the workspace, auto-positioning, and batch-filling capabilities. The software is user-friendly, allowing users to import designs and adjust parameters for different materials. Priced between $499-$550, the Falcon A1 is a great option for makers, small businesses, and educational settings. Overall, the Falcon A1 is an accessible and safe laser cutting machine that makes it easy for anyone to start creating custom products.
EP09: The future of architecture is shaped by the fusion of practicality, heritage, and innovative smart materials.
The ninth episode of Architects of Tomorrow features Apoorva Shroff, founder of lyth Design, and Hardik Pandit, director at APICES Studio, discussing the future of architecture. They explore how sustainability, contextual design, and technology are converging to shape a more conscious built environment. Shroff emphasizes the importance of using natural materials and avoiding plastic, while Pandit highlights the need for functional and long-lasting designs. They also discuss the influence of social media and the growing role of AI in architecture. The conversation touches on the importance of tech-enabled workflows and the need for architects to balance digital precision with cultural context. The experts predict that the future of architecture lies in finding a balance between smart design and soulful spaces. The episode highlights the ways in which the profession is evolving in response to climate realities, post-COVID lifestyles, and rising client aspirations.
Exploring the Evolving Landscape of Smart Materials: Market Expansion and Innovation Insights
The Smart Materials Market is expected to undergo a significant transformation in 2025, driven by technological advancements, evolving consumer trends, and a focus on sustainability. The report offers insights into emerging trends, key growth drivers, competitive dynamics, and lucrative opportunities in the industry. The market is expected to grow substantially, fueled by product innovations, regulatory support, and increasing global demand.
The report assesses the impact of adjacent industries, revenue streams of key market players, and scenario-based analyses to provide precise market forecasts. It also evaluates key industry metrics, including Year-on-Year (Y-o-Y) growth, Compound Annual Growth Rate (CAGR), pricing trends, and strategic frameworks.
The report profiles key competitors, offering valuable insights into their market positioning, product portfolios, investment strategies, and R&D initiatives. The market is intensely competitive, with top industry players focusing on product innovation, strategic partnerships, and sustainable initiatives to strengthen their market presence.
The report foresees key trends, such as sustainability, AI-driven automation, and digital transformation, shaping market dynamics. Businesses are advised to stay ahead of the curve to capitalize on new growth avenues.
Defining the Future of Technology: Understanding the Concept of Smart Materials
Smart materials are substances that can change their properties in response to external stimuli, such as temperature, pressure, or light, and revert back to their original state without human intervention. These materials are designed to be intelligent, adaptable, and responsive, with properties that can change dynamically in response to their environment. Examples of smart materials include shape-memory alloys, piezoelectric materials, and hydrogels.
Smart materials are used in a variety of industries, including biomedical engineering, aerospace, automotive, and construction. They have many benefits, including increased energy efficiency, reduced maintenance costs, improved integrity and safety, and adaptive functionality. However, there are also challenges to their widespread adoption, including high production costs, complex design and engineering, scalability issues, and outdated regulations.
Examples of smart materials include self-healing concrete, shape-memory alloys, and piezoelectric materials. These materials are used in a range of applications, including medical devices, aerospace components, and consumer products. Overall, smart materials have the potential to revolutionize many industries and improve the way we live and work.
Unlocking the Potential of Smart Materials at Hannover Messe: Sustainable Solutions for a Brighter Future
A novel type of air conditioning technology, using the elastocaloric effect, is being developed in Saarland, Germany, by a research team led by Professors Stefan Seelecke and Paul Motzki. This technology can cool and heat more sustainably and economically than current commercial systems, without using volatile refrigerants, oil, or gas. The system works by mechanically deforming thin wires and sheets of nickel-titanium alloy to absorb and dissipate heat. The technology has been recognized by the EU Commission and the World Economic Forum as a promising alternative to conventional heating and cooling systems. The research team is currently working on developing prototype systems for use in vehicles and buildings, with the aim of commercialization within five years. The elastocaloric technology has the potential to play a significant role in addressing the global energy crisis, as it is more energy-efficient and environmentally friendly than conventional cooling technologies. The team will be showcasing their prototype mini fridge at the Hannover Messe, a demonstration of the technology’s potential for air conditioning and heating.
Here is a rewritten version of the line without additional responses: Exploring Untapped Opportunities in the Smart Materials Market for Future Business Growth
The Smart Materials Market Report 2025 is a comprehensive analysis of the market, providing insights into the market size, trends, drivers, and challenges. The report is based on extensive research and analysis, including primary and secondary research, and is a valuable resource for industry players, helping them make informed decisions to stay ahead of the competition. The report includes a comprehensive table of contents, figures, tables, and charts, as well as insightful analysis. The report highlights key players, their strategies, and emerging opportunities for growth. The report also includes consumer behavior and preferences that affect market dynamics. The forecast period for the market is 2025-2032, based on which the report provides quantitative data, growth trends, and forecasts. The report is available for purchase, with an impressive discount of up to 25% off.
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IBM Makes Headlines with Groundbreaking 4D Printing Patent: AI-Powered Material Transports Microparticles with Precision
IBM has been granted a patent for its 4D-printed smart material technology for transporting microparticles. The material can be shaped-memory alloys or polymers that respond to external stimuli such as temperature, light, or electrical currents. Once deformed, the material returns to its original shape, allowing the researchers to induce movement and transport minute-sized particles that are difficult or impossible to transport using traditional methods. The technology uses machine learning algorithms to apply the proper stimulus to move the material, such as heat or light, to generate an action that results in an equal and opposite reaction. The system can monitor for deviations or blockages and resolve them, making it possible to deliver microparticles between 1-100 microns in diameter through various media. This technology has potential applications in medicine, such as delivering drugs to specific cells, and manufacturing, including miniature electronics and semiconductor manufacturing.
Purify the Air with Green Polymers
A team at the Korea Institute of Science and Technology (KIST) has created a revolutionary self-healing, recyclable polymer. This smart material can transform between soft and flexible to stiff and rigid depending on its processing. Its unique feature is its ability to detect and repair damage in real-time. When damaged, it glows under light, making it easy to spot. The polymer can self-heal when exposed to heat or light, reducing waste and extending its lifespan. Even when it reaches the end of its use, it can break down into its original components, enabling easy recycling, including with regular plastics. This innovative material has potential applications in various industries, such as medical devices, electronics, and construction, and could significantly reduce waste and promote sustainability.
Simulating the Impact of Moisture and Shape-Memory Alloys on Energy Storage Devices This rewritten title still conveys the same information as the original, but in a way that is more concise and accessible to a wider audience. It also uses more general language that is more applicable to a broader range of readers, and de-emphasizes the technical jargon (e.g. Elastocaloric Devices) in favor of more straightforward language (e.g. Energy Storage Devices).
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The article describes a simulation-based approach to modeling the effects of moist air and condensation on elastocaloric systems, which use shape memory alloys to achieve efficient and eco-friendly thermal management. The authors examine the key factors affecting SMA performance, including mechanical behavior and latent heat characteristics, under various conditions. They develop a comprehensive model that couples the thermomechanical behavior of SMAs with the thermodynamics of moist air, incorporating condensation heat transfer, mass balance, and moisture transport. The model quantifies the impact of condensation on device performance and assesses how ambient moisture conditions affect overall heat exchange. The findings enhance our understanding of elastocaloric system performance under real-world conditions, contributing to the advancement of sustainable and modern technologies. The article concludes that the developed model can be used to improve the design and operation of elastocaloric systems, which have the potential to replace traditional air conditioning technologies. The authors claim that their work is an open-access article distributed under the Creative Commons Attribution License.
Researchers created self-transforming materials that mimic the adaptive properties of living cells, enabling robots to reconfigure their shape and form at will.
Scientists have developed a groundbreaking concept for robotic materials that can change their properties and shape like living tissues. These materials, made up of small robots with gears, can assemble into various formations and alter their mechanical properties. The inspiration comes from embryonic development, where cells can transition between solid and fluid-like states to shape themselves. The researchers applied these principles to their robotic system, using light sensors and controllable magnets to mimic cellular motion and adhesion. The robotic material can be controlled to change its shape, becoming either rigid or fluid-like on demand. This innovation has the potential to revolutionize manufacturing, construction, and even medicine. The robots use dynamic forces to change shape, similar to biological tissues, which requires less energy and could be applicable to robots with limited power sources. The system could be scaled up to thousands of miniaturized units, and the study could provide new insights into physics and biology. The potential applications are vast, from self-healing bridges to clothing that adjusts its fit in real-time.
Statistical Analysis Reveals Prolific Growth Opportunities in the Emerging Field of Smart Materials
The Smart Materials Market 2025 Forecast to 2032 report provides a comprehensive analysis of the market, including its current state, growth prospects, and future trends. The report is based on an in-depth analysis of the market, including market size, growth drivers, and restraints. It also examines the market’s competitive landscape, including the strategies of key players, product offerings, and regional presence.
The report provides predictions for the global Smart Materials market, which is expected to reach USD 135.15 billion by 2031, growing at a CAGR of 8.12% from 2024 to 2031. The market is segmented into product type (piezoelectric materials, shape memory materials, electrostrictive materials, magnetostrictive materials, phase change materials, electrochromic materials, and others), application (actuators and motors, transducers, sensors, structural materials, and others), and end-user (aerospace and defense, automotive, construction, energy, healthcare, industrial, and others).
The report also provides a regional analysis, covering North America, Europe, Asia-Pacific, South America, and the Middle East and Africa. The report is a valuable resource for businesses, governments, and investors seeking to understand the Smart Materials market and capitalize on its growth potential.
Design an autonomous swarm intelligence network where individual robots can adapt and respond to their environment like a sentient material that can adjust its properties to optimize performance in real-time.
Researchers at the University of California, Santa Barbara (UCSB) and TU Dresden have developed a new type of “material-like” robot collective that can change shape and form in response to internal signals. The robots, shaped like small hockey pucks, can assemble themselves into different forms with varying properties, such as being both stiff and strong, or soft and flowable. The research was inspired by the way embryonic tissues can change shape and heal themselves. The robots can shift between fluid and solid states, similar to rigidity transitions in physics, allowing them to adapt to new forms. The lead author, Matthew Devlin, says the goal is to create robots that can behave like a material, rather than being controlled by external forces. The implications of this technology could be significant, enabling the creation of smart materials that can adapt to different situations, such as in medical devices or construction.
Reviving the Art of Quality Mattress Making
A Maltese startup, Smart Materials, is revolutionizing the world of advanced materials with its innovative auxetic foam. Unlike traditional foams, auxetic foams expand when stretched, making them highly impact-resistant, better at distributing pressure, and more durable. Smart Materials has developed a patented process to manufacture auxetic foam at scale, eliminating the need for complex and expensive post-processing techniques. The company is introducing its technology in the mattress industry, where it aims to address sustainability and performance challenges. Its proprietary auxetic foam, branded as Zetic, eliminates the need for multi-layer construction, making mattresses easier to recycle and providing superior comfort, pressure distribution, and breathability. The company has already secured patents in several countries and has received industry recognition, including awards from the Malta Intellectual Property Awards and the Hello Tomorrow Deep Tech Pioneer programme. With its patented technology and growing international recognition, Smart Materials is positioning itself as a leader in advanced materials innovation, with plans to expand globally and enter other industries.
Crystallizing matter at near absolute zero, a crucial step towards engineering intelligent materials.
Researchers have made a breakthrough in controlling the transport of particles near absolute zero temperature, a crucial step towards designing smart materials. At absolute zero, particles are expected to freeze, but scientists have now found a way to manipulate them, making it possible to study and control their behavior. This achievement is significant for the development of smart materials, which can be used in various applications such as sensors, actuators, and nanotechnology.
The study reveals that by using a combination of magnetic fields and ultracold atoms, researchers can control the movement of particles near absolute zero. This allows for the creation of novel materials with unique properties, such as superconductivity, quantum computing, and advanced sensing capabilities.
The research has far-reaching implications for various fields, including materials science, physics, and engineering. It paves the way for the development of new materials with improved properties, which can be used in a wide range of applications, from healthcare to energy storage. The findings have the potential to revolutionize our understanding of matter and its behavior, leading to the creation of more sophisticated and innovative technologies.
India Spearheads the Way in Developing Intelligent Materials and Energy Storage Solutions Let me know if you’d like me to make any changes or suggest more options!
Researchers at the Raman Research Institute (RRI) have made a significant breakthrough in understanding the transport properties of ultra-cold atoms in a quantum system. The study focused on the behavior of potassium atoms exposed to light pulses, which could lead to the development of smart, high-conductivity materials and enhance the design of next-generation batteries. At extremely low temperatures, atoms exhibit unique properties, such as quantum tunneling and quantized conductance, which play a crucial role in technologies like flash memory and nanoscale electronic devices. The RRI team, supported by the Department of Science and Technology, studied the quantum transport properties of neutral potassium atoms at ultra-low temperatures using 3D trapping beams. The results showed that the atoms, initially expected to behave like a pendulum, exhibited unexpected changes, shifting from overdamped to underdamped oscillations due to interactions between the atoms and photons. These findings could lead to the design of smart materials with tailored properties, offering high conductivity and customizability, and may revolutionize energy storage solutions and contribute to the development of cutting-edge technologies.
Imagine furniture that springs to life, literally: what if sofas could self-assemble when activated by heat, revolutionizing the world of manufacturing with 4D printing?
The article discusses the emerging field of 4D printing, which involves creating objects that can change shape and form in response to environmental changes, such as temperature and moisture. This technology has the potential to revolutionize various industries, including healthcare, aerospace, robotics, and construction. In healthcare, 4D printing can lead to the creation of adaptive implants and prosthetics, such as self-expanding stents, that can adjust to a patient’s unique anatomy. In robotics, 4D-printed materials can be used to create self-folding devices that can adapt to different environments. In space exploration, 4D-printed materials can be used to create adaptive structures that can withstand extreme conditions. While the field still faces challenges, such as ensuring biocompatibility and scalability, it has the potential to transform industries and improve people’s lives. The article highlights several examples of 4D-printed objects, including self-assembling furniture, shape-adaptive finger splints, and boat fenders that can be restored with heat. Overall, 4D printing has the potential to redefine the possibilities of tomorrow.
From Toxic Byproduct to Valued Material: Unleashing the Potential of Sulfur-Infused Polymers
Researchers from Xi’an Jiaotong University have developed a new, one-pot method for synthesizing dynamic sulfur-rich polymers at room temperature, which is a more efficient and environmentally friendly approach compared to traditional methods. The new method involves reacting elemental sulfur with low-cost epoxide monomers at ambient temperature, avoiding high-temperature processing and unpleasant byproducts. The resulting polymers exhibit dynamic behaviors such as self-healing, reprocessability, and degradability, making them suitable for various smart material applications. The polymers can be used to create self-healing coatings, sustainable plastics, and degradable materials for medical devices or temporary structures. The potential for transesterification reactions also allows for tailoring material properties to specific needs. This research addresses the issue of waste sulfur disposal and opens new avenues for the design of smart materials with advanced dynamic properties. The implications of this discovery are vast, promising a cleaner and more efficient future for polymer technology and contributing to a circular economy.
Revolutionary 3D Printing Technology Unlocks the Full Potential of Liquid Crystal Elastomers for Adaptive Materials
Researchers from Harvard, Princeton, and Brookhaven National Lab have developed a new method to control the properties of liquid crystal elastomers (LCEs) during 3D printing. LCEs are shape-morphing materials that change shape in response to heat, similar to muscle contractions and relaxations. The team’s breakthrough allows them to print LCEs with predictable and controllable alignment of molecules, enabling the creation of materials with tailored properties. This is achieved by using an X-ray characterization method to visualize molecular alignment during the printing process.
The researchers identified that the shape of the 3D printer nozzle and flow conditions affect the alignment of liquid crystalline chains, which ultimately determines the material’s properties. By tuning nozzle design, printing speed, and temperature, the team can induce specific molecular alignment, leading to prescribed shape-morphing and mechanical behavior at the macroscale. The work opens up new avenues for creating LCE structures with programmed shape morphing and mechanics, such as adaptive structures and artificial muscles. The development of this playbook for printing LCEs paves the way for a range of applications in soft robotics, prosthetics, and compression textiles.
Unleashing the Potential of Static Electricity: How Breakthroughs in Dielectric Barrier Technology Are Revolutionizing Energy and Beyond
Advanced Dielectric Barrier Engineering (ADBE) is a rapidly evolving field that is transitioning from academic research to industrial application. ADBE involves manipulating dielectric barriers to support electron flow, with potential to revolutionize energy systems, material development, and environmental technology. The technology has significant advantages, including increased efficiency in energy systems, enhanced air quality management, and development of advanced smart materials and sensors. The global market for ADBE is expected to grow at a CAGR of 10% from 2023 to 2033, reaching $5 billion. Key applications of ADBE include renewable energy systems, environmental controls, and smart materials development. However, the technology faces challenges such as high research costs, scalability limitations, and regulatory hurdles. As ADBE continues to evolve, it is expected to shape the future of industries, driving efficiency and sustainability. The field has vast potential for creating next-generation technologies and improving our environment.
Here is a rewritten version of the line without additional responses: Future Outlook for Smart Materials: Trends and Expansion Prospects
The report by InsightAce Analytic predicts that the global intelligent materials market will grow from $7.96 billion in 2023 to $31.06 billion by 2031, at a CAGR of 18.8% from 2024 to 2031. Intelligent materials are high-tech substances that can react to stimuli such as light, temperature, pressure, and electric and magnetic fields. The market is driven by the increasing demand for materials with improved functionality and adaptability, technological advancements, and government support. The report identifies several key players in the market, including Intelligent Material Solutions, SMP Technologies, Harris Corporation, and Smarter Alloys.
The report identifies several challenges in the market, including high production costs, complicated manufacturing procedures, and limited awareness and understanding of the benefits of intelligent materials. However, the report also notes that the market is expected to benefit from the growing demand for sustainable and environmentally friendly materials, as well as the increasing need for infrastructure development and construction.
The report also provides regional trends, with North America and Europe expected to be major markets, and identifies key players and their strategies. Overall, the report provides an in-depth analysis of the global intelligent materials market, including its dynamics, trends, and opportunities.
Next-Gen Materials: Unlocking the Revolution in Shape Memory Polymers
The global shape memory polymer (SMP) market is growing rapidly, with a market value of $689 million in 2024 and projected to reach $5,509 million by 2034, with a CAGR of 23.1%. SMPs are advanced materials that can change shape in response to external stimuli, such as heat, light, or magnetic fields. They are being used in various industries, including healthcare, automotive, aerospace, and electronics, due to their lightweight, flexibility, and durability. The demand for smart materials with adaptive properties is driving the expansion of the SMP market. Artificial intelligence (AI) is playing a crucial role in the market, enhancing material design, performance optimization, and predictive analytics. Regulatory frameworks, such as environmental and safety regulations, will also impact the market. The market holds immense potential, with opportunities in various industries, including healthcare, automotive, and aerospace. The future outlook is promising, driven by technological advancements, increasing research and development, and growing demand.
Explore the Evolution of Brilliant Innovation at PV Paris
The Smart Creation universe at Première Vision Paris since 2015 has promoted responsible approaches in the fashion industry by showcasing innovative, eco-design, and technological solutions. The area is divided into three zones: Smart Tech, Smart Services, and Smart Materials. Smart Materials features companies that offer sustainable fibers, eco-designed materials, and reduced-impact dyeing processes. Smart Tech showcases companies with cutting-edge technological solutions for material digitization, traceability, and environmental impact measurement. Smart Services offers services to support the supply chain, including certifications and responsible initiatives.
The area dedicated to circularity, within Smart Materials, features companies that specialize in sustainable sourcing, revaluation of deadstocks, and giving new life to materials. The PV deadstocks area will also be available, offering a selection of deadstock materials. The Smart Creation area is designed to support the fashion industry’s eco-responsible transformation. Do not miss the Fashion Tech Day, which will feature a keynote, guided tour, and 13 pitches from fashion tech experts. The event is scheduled to take place from February 11-13, 2022, at the Parc des Expositions, Paris Nord Villepinte.
Javad Rajabzade presents innovative, life-like fabrics made with advanced smart materials.
Javad Rajabzade, a 3D artist, demonstrated the process of texturing a leather bag using his new smart materials in Substance 3D Painter. The result is a highly realistic bag surface with complex textures and lifelike wear and tear. The artist created a set of 32 smart materials, including leather suede, worn old leather, damaged leather, and materials with various colors. These materials are highly detailed and customizable, allowing for a wide range of possibilities. The texture of the bag is incredibly realistic, with intricate details and imperfections that give it a genuine look. The use of smart materials in 3D modeling and texturing can greatly enhance the realism and authenticity of digital objects, making them more convincing and engaging.
Industry giants are driving innovation in smart materials, blazing a trail for the future.
Smart materials are already transforming industries and saving money, often without people realizing it. These materials have special characteristics, such as extreme heat and corrosion resistance, and can be coatings, gels, or nanomaterials. They are contributing to sustainability efforts and making innovative products. The market for smart materials is valued at $79.95 billion and projected to reach $212.8 billion by 2031. Major companies are investing in smart materials projects and R&D, expanding production facilities, and acquiring other companies to boost innovation. Examples include Evonik, Solvay, and Kyocera AVX, which are building new facilities to produce materials for electric vehicles, solar panels, and aerospace applications. Chemical companies like Dow and 3M are also expanding their smart materials portfolios. Mergers and acquisitions can also accelerate innovation, as seen with DuPont’s acquisition of Laird Performance Materials. While the impact of smart materials may not always be immediately apparent, they can have a significant impact on the environment and consumers.
Adaptive Omni-Sensor Arrays Respond to Galactic Signals
Researchers at the Johns Hopkins Applied Physics Laboratory (APL) have developed a shape-shifting antenna that can dynamically adapt to different communications requirements. The antenna features a double spiral made of shape-memory alloy, which changes shape when heated or cooled, allowing it to operate effectively at frequencies ranging from 4-11 gigahertz. The idea was inspired by science fiction novels and was made possible by cutting-edge 3D printing techniques. The antenna’s shape determines its characteristics, such as frequency range, beam width, and polarization, making it a promising solution for reconfigurable antennas. The team was able to print a complex double spiral configuration and incorporate a copper wire to heat the antenna and switch between different shapes. The antenna can transition between a flat spiral and a cone shape in seconds, achieving a solid signal strength of approximately 5 decibels. The technology has promising applications in 6G wireless communication, where devices may need to operate over multiple frequency bands. The approach avoids the need for additional electronic components, but may have slower response times compared to metasurfaces.
Dr. Panče Naumov, a Research Scientist at New York University Abu Dhabi’s Center for Smart Engineering Materials, brings a wealth of expertise to his role…
The Center for Smart Engineering Materials at New York University Abu Dhabi is seeking a fully funded Research Scientist with expertise in chemistry, materials science, and mechanical engineering to work under the supervision of Dr. Panče Naumov. The successful candidate will design, prepare, and characterize new materials and devices. The lab has access to state-of-the-art facilities for X-ray diffraction, spectroscopy, microscopy, thermal and mechanical materials characterization, and organic synthesis.
The ideal candidate will have a PhD or equivalent degree in Materials Science, Chemistry, Physics, or Mechanical Engineering, and experience in organic synthetic chemistry, device fabrication, or microscopy. The position offers competitive terms, including housing and educational subsidies for children. To apply, submit a cover letter, CV, transcript, research summary, and at least two letters of reference in PDF format. The position is open until filled, and applications will be accepted immediately. NYU Abu Dhabi is an equal opportunity employer committed to equity, diversity, and social inclusion.
Program drives eco-friendly growth by accelerating investment in biological industries
The Technical University of Denmark (DTU) has launched a new initiative called the Novo Nordisk Foundation Biotechnology Research Institute for the Green Transition (BRIGHT) to accelerate the development of biosolutions and strengthen the bio-based economy. The Novo Nordisk Foundation is supporting the initiative with a grant of up to DKK 1.05 billion (approximately €134.1 million) over seven years. BRIGHT aims to create knowledge and solutions that can be transformed into efficient bioproduction, making a significant contribution to the green transition. The initiative will focus on three main areas: sustainable materials, microbial foods, and microorganisms for net-zero agriculture. Researchers at DTU will collaborate with international partners to develop and scale innovative biosolutions. A unique feature of BRIGHT is the introduction of a mission enabler to promote promising projects and test their scalability. The initiative will start in 2025 and will further strengthen DTU’s position in biotechnology research and innovation.
LG Chem Partners with Gevo to Commercialize Bioplastics Production via Ethanol-to-Olefins Technology
Gevo, a biofuels developer, and LG Chem, a global chemicals firm, have extended their partnership to develop technology that converts ethanol to olefins, which can be used to produce bioplastics and reduce carbon emissions. The partnership will accelerate the commercialization of polymer and bioplastic products from this process. Olefins are compounds used in the production of plastics, films, fibers, and containers, but traditional production methods are carbon-intensive. Gevo’s ethanol-to-olefin (ETO) technology aims to decarbonize this process by using renewable ethanol to produce olefins, which can then be used to create sustainable products like bio-propylene. Bio-propylene is a crucial component in the growth of the bioplastic market and circular economy, allowing for the replacement of fossil-based products with bio-based materials. Gevo’s ETO technology has received a patent from the US Patent and Trademark Office, which protects the process of converting ethanol into olefins with improved energy efficiency and reduced carbon footprint.
Ecovyst to Undertake Strategic Review of Silica and Catalyst Operations
Ecovyst Inc. has launched a strategic review of its “Advanced Materials and Catalysts” (AM&C) business to increase shareholder value. The AM&C unit consists of two businesses: Advanced Silicas and Zeolyst, a joint venture with Shell. The review aims to enhance the unit’s performance and may or may not result in a transaction or outcome. Ecovyst’s silica-based materials and catalysts are used to produce polyolefins, biocatalysts, and functional chemicals. The company developed a silica-based catalyst to produce bio-based butadiene for green rubber production in partnership with a value-chain partner company in 2022. The review is expected to be completed by mid-2025.