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Pisa, Italy
1-10 Employees
2017
We are able to transmit and receive them to produce high performance systems.
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Featured
METAMATERIALS
... METASURFACES represent the 2D version of metamaterials. They have been applied to large number of scenarios. ...
Ikšķile, Latvia
1-10 Employees
2020
Innovative smart antennas for mmWave wireless communications on the earth and in the space. Design and production of liquid crystal-loaded metamaterial structures for antenna applications.
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Featured
Metamaterial article
... Metamaterial ...
Lausanne, Switzerland
1-10 Employees
MinWave designs and manufactures RF front-end (RFFE) solutions based on novel metamaterials. We are a world-class team of experts from EPFL, and our technology has been seeded at LWE at EPFL. Additive manufacturing as an enabling method for providing low-cost monolithic RFFE components with complex geometries.
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Featured
Revolutionary Metamaterial RF Solutions
... Novel Manufacturing Methods Read More Revolutionary Metamaterial RF Solutions Read More OUR TECHNOLOGY MinWave designs and manufactures RF front-end (RFFE) solutions based on novel metamaterials. Our solutions Lower volume and mass Significantly compact and lightweight RFFE components ...
Durham, United States
1-10 Employees
2018
Metacept provides design and engineering services for complete electromagnetic systems, with extensive experience in transitioning metamaterials to real-world applications.
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Featured
Home | Metacept
... Metamaterials are a novel way to engineer material properties using micro-structural design. Metamaterials are able to intricately and precisely control many types of wave dynamics from electromagnetic to acoustic fields. ...
Lake Bluff, United States
251-500 Employees
1936
Buehler is a division of Illinois Tool Works (ITW) and is based in Lake Bluff, Illinois With offices in six countries and sales distribution in over 100 counties, Buehler is a trusted expert delivering simplified solutions and reliable results. Sustainability is important to Buehler and its employees. As Buehler, we’re committed to advancing sustainability through customer-backed innovation. Our products help our customers be greener with longer use life equipment & consumables as well as specialized products designed to provide a more environmentally friendly option. ITW (NYSE:ITW) is a fortune 200 global industrial company built around a differentiated and proprietary business model. The Company’s seven industry-leading segments leverage the unique ITW Business Model to serve markets where highly innovative, customer-focused solutions are required. ITW consistently delivers superior performance and value for its customers. Global industry leader with over 85 years of experienceQuick response time from knowledgeable staffLeaders in industry standards compliance.
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Featured
Applications of Metamaterials
... Applications of Metamaterials ...
Geneva, Switzerland
1-10 Employees
2019
Our goal is to use metamaterial technologies to drastically improve patient throughput and reduce risk of induced cancer by PET scan radiation, especially for children. Metacrystal files new patent on photonic crystals for scintillators. A positron emission tomography (PET) scan is an imaging modality widely used for the diagnosis, patient staging and treatment follow-up of a number of diseases, such as cancer, cardiovascular and brain degenerative diseases. Advances in PET image reconstruction have allowed systems called time-of-flight (TOF) PET to offer higher image quality for more accurate detection of masses and lesions than conventional PET scans. A cyclotron produces radiotracers for delivery to hospitals. Multiwave Technologies AG spins-off activity on metamaterial applications for positron emission tomography. Lecoq is the head of physics of the European Academy of Sciences and a CERN honorary member. Craster is the Dean of the Faculty of Natural Sciences at Imperial College London.
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Featured
Metacrystal
... Metamaterial scintillating crystals for early detection of cancer and reduced radioactive dosage in nuclear medicine. ...
Irvine, United States
1-10 Employees
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply. If you’d like to learn more or are interested in employment opportunities, please contact us . Copyright © 2018 METASEISMIC, INC - All Rights Reserved.
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Featured
metaseismic
... metamaterials, uci, ...
Melbourne, Australia
11-50 Employees
2017
We are offering an engineered solution to the wall of rocks – a lightweight acoustic panel made of metamaterials designed specifically for your unique wave of sound – our MetaBarrier(™) Technology. We can mitigate noise from external environments, or from your product application, let us show you how. An acoustic metamaterial is a material designed to control, direct, and manipulate sound waves as these might occur in gases, liquids, and solids. Related to this is the mechanics of wave propagation in a lattice structure. As the experts in the application of metamaterials for reduction of unwanted noise we promise to provide a solution which reduces the noise in your world.
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Featured
Applied Metamaterials : About
... History of Applied Metamaterials ...
Redmond, United States
101-250 Employees
2012
Kymeta’s industry leading, easily mountable, electronically steered antennas provide satellite and cellular connectivity where and when you need it. Offering reliable and robust always-on connectivity for the Kymeta u8 product family. Manage one, or several devices through Kymeta’s state-of-the-art mobile application.
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Featured
Metamaterials
... Kymeta is the first company to make metamaterial technology commercially viable. This enables Kymeta to build a more efficient antenna that delivers the dynamic electronically-steered performance of a phased array without the need for expensive and power-hungry phase shifters, related ...
Dartmouth, Canada
51-100 Employees
2013
We develop new products and technologies using innovative sustainable science. We are able to develop a library of solutions and functional prototypes much faster and at lower cost than traditional chemical synthesis. Metamaterials enable properties and capabilities that go beyond those found in natural materials and which are generally not possible to create using conventional material discovery or specialty chemical manufacturing technologies. We are developing new solar films that have the potential to increase solar cell efficiency by collecting and absorbing light from all angles. At Airbus, we are always on the lookout for new ideas coming from innovative SMEs, such as MTI. We are very pleased to explore together the potential application of this solution to our aircraft, for the benefit of our customers.”. Advanced materials can improve everyday products that surround us, making them smarter and more sustainable. META delivers previously unachievable performance, across a range of applications, by inventing, designing, developing, and manufacturing scalable, sustainable, highly functional materials and intelligent surfaces.
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Metamaterials and Functional Surfaces
... Metamaterials and Functional Surfaces - ...
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Some interesting numbers and facts about the results you have just received for Metamaterial
| Country with most fitting companies | United Kingdom |
| Amount of fitting manufacturers | 59 |
| Amount of suitable service providers | 34 |
| Average amount of employees | 1-10 |
| Oldest suiting company | 1936 |
| Youngest suiting company | 2020 |
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Metamaterials are artificially engineered structures designed to control and manipulate physical phenomena, including electromagnetic waves, sound waves, and thermal energy. Unlike conventional materials, their unique properties are derived not from their composition but from their precisely tailored structure, allowing for behaviors that do not occur naturally. These materials exhibit extraordinary capabilities, such as bending electromagnetic waves around objects to achieve invisibility cloaks or drastically enhancing the resolution of imaging systems beyond the limitations of traditional optics. The impact of metamaterials extends across various fields, including telecommunications, where they can improve signal strength and bandwidth; medical imaging, by providing clearer and more detailed images; and energy harvesting, where they offer new methods for efficient solar power collection. Their development represents a paradigm shift in materials science, opening avenues for innovation in areas ranging from stealth technology and superlenses to improved acoustic dampening and heat management systems. By harnessing the peculiar characteristics of metamaterials, scientists and engineers are pushing the boundaries of what is physically possible, offering promising solutions to some of the most challenging problems in technology and beyond.
1. Enhanced Wave Manipulation
Metamaterials possess unique structures that allow for extraordinary control over electromagnetic waves. This capability surpasses traditional materials, enabling applications like invisibility cloaks and superlenses that can focus light beyond the natural limits.
2. Improved Communication Systems
Thanks to their ability to manipulate radio and microwave frequencies with precision, metamaterials can significantly enhance the performance of antennas and other communication devices. This improvement leads to faster and more reliable wireless communication networks.
3. Advanced Medical Imaging
Metamaterials offer the potential for revolutionizing medical imaging technologies. Their unique properties can contribute to clearer, more detailed images, assisting in early disease detection and the improvement of diagnostic accuracy.
4. Energy Efficiency
By optimizing the interaction with various energy forms, metamaterials can lead to more efficient solar panels and energy harvesting devices. This efficiency could play a crucial role in developing sustainable energy solutions.
While evaluating the different suppliers make sure to check the following criteria:
1. Technological Expertise
Ensure the supplier has a strong background in metamaterial technology and innovative product development capabilities.
2. Quality Assurance
Verify that they have robust quality control processes in place to ensure the materials meet your specifications and industry standards.
3. Scalability
Assess their ability to scale production up or down based on your needs, without compromising on quality or lead times.
4. Customization Options
Determine if they offer customization options that can be tailored to your specific applications and requirements.
5. Cost-Effectiveness
Consider their pricing structure to ensure it aligns with your budget without sacrificing the quality or performance of the metamaterials.
6. Sustainability Practices
Check their commitment to sustainability and whether their production processes minimize environmental impact.
7. Customer Support and After-Sale Service
Evaluate their customer service efficiency, including after-sale support, technical assistance, and responsiveness to inquiries or issues.
Metamaterials, engineered to possess properties not found in naturally occurring materials, have transformative applications across various industries. In telecommunications, these materials are used to enhance signal strength and clarity. By manipulating electromagnetic waves, metamaterials enable more efficient, compact antennas and filters, leading to improved connectivity and bandwidth in devices, a boon for businesses reliant on robust communication networks. Another significant application is in the medical imaging and treatment sector. Metamaterials offer the potential for improved MRI machines, making them smaller, more powerful, and capable of producing higher resolution images. This innovation can lead to more accurate diagnoses and treatments, benefiting healthcare providers and patients alike. In aerospace and defense, metamaterials contribute to the development of stealth technology. By controlling the reflection and absorption of electromagnetic waves, these materials can reduce the radar signature of vehicles, making them less detectable and enhancing the efficacy of surveillance and reconnaissance missions. The energy sector also benefits from metamaterial applications, particularly in solar power. Metamaterials can increase the efficiency of solar panels by directing and concentrating sunlight onto smaller, more efficient photovoltaic cells. This advancement could lead to more cost-effective and sustainable energy solutions for businesses. Through these diverse applications, metamaterials demonstrate their potential to revolutionize industries by offering innovative solutions to longstanding challenges.
As of the latest assessments, metamaterials are generally positioned at varying stages across the Technology Readiness Level (TRL) spectrum, with most applications hovering between TRL 4 (technology validated in lab) and TRL 6 (technology demonstrated in relevant environment). This broad range is attributable to the diverse nature of metamaterials, which are artificial materials engineered to have properties not found in naturally occurring materials, including negative refractive index, perfect absorption, and superlensing capabilities. The specific TRL of a metamaterial application depends heavily on its domain—ranging from electromagnetic to acoustic metamaterials. The technical reasons for their current TRL positions include challenges in manufacturing processes, scalability, and integration into practical devices. For instance, while the theoretical foundation and lab-scale demonstrations have shown promising results, translating these innovations into commercially viable products has been hindered by high production costs, material instability at larger scales, and difficulties in achieving consistent properties across batches. Additionally, the integration of metamaterials into existing technology platforms requires overcoming significant engineering challenges, such as ensuring compatibility with standard electronic components and systems. These technical barriers must be addressed to advance the TRL of metamaterial applications further, making them more accessible for widespread use in industries such as telecommunications, imaging, and defense.
In the short-term phase, metamaterial technology is expected to see considerable advancements in wireless communication and imaging systems. The development of ultra-thin metamaterial antennas and lenses promises to drastically improve the efficiency and range of wireless communication devices, as well as enhance imaging resolution beyond the diffraction limit of traditional systems. These innovations could lead to more compact and powerful smartphones, as well as more precise medical imaging tools, within the next few years. Mid-term developments are poised to revolutionize energy harvesting and solar power generation. Researchers are working on metamaterials that can significantly increase the efficiency of solar panels and even create devices capable of harvesting energy from ambient sources, such as Wi-Fi signals. This period will likely witness the integration of these materials into consumer products, leading to more sustainable energy solutions and potentially reducing our reliance on traditional power sources. Looking at the long-term, the potential applications of metamaterials extend into cloaking and invisibility technologies, as well as seismic protection. Theoretical studies suggest that metamaterials could be used to direct electromagnetic waves around objects, effectively making them invisible, or to create "seismic invisibility cloaks" that can protect structures from earthquakes. While these applications might seem like science fiction today, ongoing research and development could make them a reality, bringing profound changes to military, construction, and various other industries in the decades to come.
Some interesting questions that has been asked about the results you have just received for Metamaterial
What are related technologies to Metamaterial?
Based on our calculations related technologies to Metamaterial are Glass, Superconductors, High-Performance Materials, Raw Materials, Phase Change Materials
Who are Start-Ups in the field of Metamaterial?
Start-Ups who are working in Metamaterial are Spatialite Antenna Systems
Which industries are mostly working on Metamaterial?
The most represented industries which are working in Metamaterial are Manufacturing, Commerce and Shopping, Hardware, Consumer Electronics, Science and Engineering
How does ensun find these Metamaterial Companies?
ensun uses an advanced search and ranking system capable of sifting through millions of companies and hundreds of millions of products and services to identify suitable matches. This is achieved by leveraging cutting-edge technologies, including Artificial Intelligence.
