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Featured
Phase transformation of 2D transition metal (TM) dichalcogenides during the in-situ high-temperature heating
... Phase transformation of 2D transition metal (TM) dichalcogenides during the in-situ high-temperature ...
11-50 Employees
2009
We specialise in materials and equipment for fabricating and testing high-performance research devices. Backed by decades of experience, our mission is to pave the way to discovery by empowering the international scientific community with the tools you need to accelerate your research. From teaching to rapid prototyping and scale-up processing, we equip laboratories around the world with dependable products at accessible prices. Class AAA over a 15 mm diameter circular area at an affordable price. Long-term and low cost LED characterisation and lifetime measurement system.
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Featured
ReSe2 Rhenium Diselenide | Buy Online, Low Price | Ossila
... Rhenium diselenide (ReSe2) belongs to the family of layered transition metal dichalcogenide (TMDC) semiconductors with layers bound by van der Waals forces. ...
Montpellier, France
11-50 Employees
2004
Annealsys manufactures Rapid Thermal Processing (RTP) and chemical vapor deposition (CVD/ALD) systems. The privately owned company Annealsys was established in 2004 in Montpellier, South of France. Annealsys provides outstanding technical and process customer service through a worldwide sales and service organization. Annealsys proposes specific solutions for development of Rapid Thermal Selenization process. Founded in 2004, Annealsys with more than 300 machines installed worldwide, is a leading manufacturer of Rapid Thermal Processing and Direct Liquid Injection Deposition systems. We are supplying number of companies for the manufacturing of MEMS, sensors, optoelectronics, telecommunication, power and discrete devices. Our customers are Research and Development laboratories and companies for production applications. The systems are proposed from a catalogue range of products and can be customized upon request to meet customer's applications.
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Featured
MC-050 : Laboratory 2-inch DLI system
... The MC-050 offers the widest capabilities for development of new materials including single and multi-metallic oxides as well as transition metal dichalcogenides (TMD) and other 2D materials. ...
Rovereto, Italy
1-10 Employees
2012
We are a small but solid team of scientists, engineers and managers with strong multi-disciplinary competences and many years of experience in respective fields. Noivion was originally founded in mid 2012 in Italy to introduce in the market a new manufacturing technique for the deposition of thin films called Ionized Jet Deposition (IJD) that offers substantial advantages over comparable solutions in terms of quality, cost and yield. Find out how IJD has been used in different applications to realize innovative devices or replace conventional technologies. IJD has unique characteristics delivering distinct advantages for a variety of applications. IJD equipment provides more power and flexibility at a fraction of the cost of a laser ablation system (up to 10 times lower CAPEX, 10-20 times smaller industrial size and 5 times more energy saving). The possibility to coat large objects using small targets (10-30 mm diameter, disc shaped) offers a great cost optimization opportunity in the development of coatings made of rare and precious materials. IJD offers mostly independent process variables allowing to explore a wide set of energies and conditions and fine tune even the more complex deposition processes. A breakthrough towards the large-scale and affordable production of 2D-like materials.
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Featured
Molybdenum disulfide - NOIVION
... D is emerging as cost-efficient and versatile thin-film deposition technique for the fabrication of transition metal dichalcogenides thin films, such as molybdenum disulfide (MoS2). A recent publication by IMEM-CNR Institute of Materials for Electronics and Magnetism (Trento, Italy) ...
Town of Islip, United States
1-10 Employees
2009
We produce over 90 R&D products including graphene oxide , graphene nanoplatelets (GNPs), CVD graphene, and conductive epoxies. The high quality of our products starts with the combined decades of experience by our scientific and technical team in graphene technology and related materials in both academic and commercial settings. As a result, we can provide consistent graphene, graphene related, and epoxy products in packaged units, volume orders, and bulk quantities. In addition, we offer custom development of advanced materials and on-demand R&D based on customers’ needs. Our production and QC facility is located in Ronkonkoma, NY. Graphene Supermarket’s research team operates within a state-of-the-art analytical and materials testing laboratory to perform the certification of raw materials used for production and quality testing for the end-product formulations and composites. Our state-of-the-art chemical reactors are designated for graphene oxide (GO) production. GO is offered in R&D quantities in the form of aqueous dispersions, pastes, dried and reduced powders, and aerogels.
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Featured
Molybdenum Disulfide (MoS2) Crystal
... Molybdenum Disulfide (MoS2) Crystals MoS2 is a naturally-forming layered transition metal dichalcogenide that may be mined. It is a silvery-black crystal which looks and feels similar to crystals of graphite. Properties: [Regular] One or two crystals | [Large] One crystal [Regular] 0.7cm2 ...
Miami Beach, United States
1-10 Employees
2001
Launched on May 25th, 2001, Supercomputing has come to be known as the best vehicle to reach people who build and manage the inspiration, innovation, and discovery powered by supercomputing. What is supercomputing? Supercomputing is the technology that is used to provide solutions to problems that require significant computational power or need to process very large amounts of data quickly. Supercomputing accelerates the production of research results of benefit to our industries, the economy, and society in general. Today, supercomputing is used for innovations such as advances in medicine for cancer research, improvements in homeland defense, financial services for investment risk analysis, energy in oil exploration, manufacturing for complex mechanical design, weather forecasting, and creating artful digital characters. and exploring the cosmos. Unmatched in its depth of analysis and predictive power, Supercomputing links the people and ideas that are shaping the future of supercomputing.
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Featured
SUPERCOMPUTING
... German physicist Tittl develops a metasurface that enables strong coupling effects between light, transition metal dichalcogenides ...
Vilnius, Lithuania
1994
LIGHT CONVERSION, founded in 1994 with roots at the Vilnius University Laser Research Center, is a pioneer in femtosecond optical parametric amplifiers (OPAs) and Yb-based femtosecond laser sources. Currently, it is one of the world’s leading manufacturers of femtosecond lasers. With proven competence in laser design and manufacturing, state-of-the-art R&D facilities, and close ties to research programs, LIGHT CONVERSION offers unique solutions for today’s industrial, scientific, and medical challenges. The reliability of our femtosecond lasers has been proven by hundreds of systems operating 24/7 for more than 10 years in the industrial market. Using our knowledge, experience, and highly motivated professional team, we focus on quality and customer satisfaction.
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Featured
ORPHEUS-N Non-Collinear OPA - LIGHT CONVERSION
... Strained Epitaxy of Monolayer Transition Metal Dichalcogenides for Wrinkle ...
Lancaster, United Kingdom
11-50 Employees
1987
We are in essence a ‘One Stop Shop.’ As well as warehousing your books in our secure facility, our marketing team produce subject targeted sales material and apply social media as a tool to promote our publishers’ titles. Gazelle Book Services is a book distribution company that offers publishers the opportunity to increase their sales in the UK and throughout Europe. In recent times Lancaster is also well-known for its University, founded in 1964 and one of the top Universities in the country with students attending from around the world. The book distribution business is constantly changing and we are well positioned to adapt to these changes. Continued focus on sourcing personnel that will both compliment and add further value to the Gazelle brand, to actively look to extend our network of sales and to invest in additional channels and new ideas that would benefit us, our publishers and our clients. Receive information on our latest titles and offers.
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Featured
Layered Structure Effects as Realisation of Anizotropy in Magnetic, Ga — Gazelle Book Services Ltd
... These materials include transition metal dichalcogenides, intercalated graphite compounds, semiconductors with superlattice, synthetic metals based on organic compounds, etc. This book ...
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Some interesting numbers and facts about the results you have just received for Transition Metal Dichalcogenide
Country with most fitting companies | United States |
Amount of fitting manufacturers | 7 |
Amount of suitable service providers | 6 |
Average amount of employees | 11-50 |
Oldest suiting company | 1987 |
Youngest suiting company | 2012 |
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Transition Metal Dichalcogenides (TMDs) are a unique class of layered materials composed of a transition metal (such as molybdenum or tungsten) and chalcogen atoms (sulfur, selenium, or tellurium) arranged in a sandwich-like structure. These compounds are characterized by their strong in-plane bonds and weak out-of-plane van der Waals forces, allowing them to be exfoliated into thin, two-dimensional layers. TMDs have garnered significant attention in the field of materials science and nanotechnology due to their remarkable electrical, optical, and mechanical properties, which vary widely with the number of layers. For instance, they can transition from indirect to direct bandgap semiconductors as they are thinned down to the monolayer limit, making them highly appealing for applications in electronics, optoelectronics, and photonics. Their high surface area, coupled with chemical stability, also makes them potential candidates for catalysis and energy storage applications. The ability to engineer TMDs by doping, alloying, or heterostructure formation opens up further possibilities for creating materials with tailored properties for specific applications. This versatility and the potential for integration into a variety of devices position TMDs as pivotal materials in the advancement of next-generation technologies.
1. Improved Electrical Properties
Transition Metal Dichalcogenides (TMDs) exhibit superior electrical conductivity and charge mobility compared to their counterparts. This makes them highly efficient for use in next-generation electronic devices, including transistors and semiconductors.
2. Enhanced Mechanical Strength
Despite their thin, almost two-dimensional structure, TMDs possess exceptional mechanical strength and flexibility. This robustness, combined with their lightweight nature, makes them ideal for flexible electronic applications, such as wearable technology.
3. Chemical Stability
TMDs are known for their remarkable chemical stability under a variety of conditions. This stability ensures long-lasting performance and durability in devices, particularly in harsh environments where other materials might degrade.
4. Optical Properties
The unique optical characteristics of TMDs, including their ability to absorb and emit light, open up new possibilities in optoelectronics and photonics. These materials can be used in the development of advanced solar cells, photodetectors, and light-emitting diodes (LEDs).
Transition Metal Dichalcogenides stand out for their multifaceted advantages, offering promising avenues in the fields of electronics, optoelectronics, and beyond. Their unique combination of electrical, mechanical, and optical properties, along with chemical stability, positions them as superior alternatives in many cutting-edge applications.
1. Purity Levels
Ensure the supplier can provide Transition Metal Dichalcogenides (TMDs) with high purity levels, as this affects the material's performance in applications like semiconductors and catalysis.
2. Customization Options
Check if the supplier offers customization options for TMDs, including adjustments to layer thickness, particle size, and composition, to meet specific application needs.
3. Scalability
Determine the supplier's ability to scale production up or down based on demand, ensuring a reliable supply chain for your projects.
4. Technical Support and Service
Assess the supplier's reputation for providing expert technical support and customer service, which is crucial for troubleshooting and optimizing applications.
5. Cost-effectiveness
Compare pricing among suppliers, but consider the overall value, including purity, customization options, and support services, to ensure cost-effectiveness.
Transition Metal Dichalcogenides (TMDs) play a pivotal role in the semiconductor industry, where their unique electrical properties are harnessed for the next generation of electronics. TMDs, with their remarkable ability to scale down to just a few atoms thickness without losing electrical integrity, are ideal for manufacturing ultra-thin, flexible, and high-performance transistors and integrated circuits. This advancement is crucial for developing wearable technology and foldable devices, pushing the boundaries of what's possible in gadget design and functionality. In the field of energy storage and conversion, TMDs stand out for their application in creating highly efficient and durable solar cells and batteries. The materials' distinctive layered structure and chemical properties facilitate enhanced photovoltaic effects and superior electrochemical performance. This makes TMDs an excellent choice for improving the efficiency of solar panels and extending the life and capacity of lithium-ion batteries, directly contributing to the advancement of renewable energy technologies. Furthermore, the catalytic properties of TMDs find significant applications in the chemical industry. They are utilized as catalysts in a variety of chemical reactions, including hydrogen evolution and carbon dioxide reduction. These applications are vital for producing clean fuels and mitigating greenhouse gas emissions, showcasing TMDs' potential in driving sustainable industrial processes.
Transition Metal Dichalcogenides (TMDs) are currently positioned at varying stages of the Technology Readiness Level (TRL) spectrum, primarily between TRL 3 and TRL 6, depending on the specific application and material synthesis advancements. This broad range stems from their unique electronic, optical, and mechanical properties, which have shown significant promise in fields such as electronics, photonics, and energy storage. At TRL 3, basic experimental research has validated the feasibility of TMDs in lab settings, highlighting their potential for ultra-thin, flexible electronic devices and efficient solar cells. Progressing towards TRL 4 and 5, small-scale prototypes have been developed, demonstrating the practical application of TMDs in transistors, photodetectors, and batteries, albeit with challenges in material stability, scalability, and integration with existing technologies. The movement into TRL 6 is marked by the demonstration of TMD-based devices in relevant environments, addressing some of these challenges through innovative synthesis methods and material engineering. However, widespread commercialization (TRL 9) remains elusive due to ongoing issues with reproducibility, large-scale manufacturing processes, and achieving consistent high-quality material properties, indicating a need for further research and development to fully harness the capabilities of TMDs in practical applications.
In the Short-Term, advancements in Transition Metal Dichalcogenides (TMDs) are expected to focus on enhancing their electronic properties for application in next-generation electronics. Researchers are exploring methods to improve the stability and conductivity of TMDs, aiming to integrate them into flexible and wearable devices. This phase will likely see the development of more efficient manufacturing processes, reducing costs and making TMDs more accessible for various technological applications. The Mid-Term outlook for TMDs involves their incorporation into renewable energy solutions. As the efficiency of TMD-based photovoltaic cells improves, these materials are poised to play a crucial role in solar energy conversion and storage technologies. Efforts will concentrate on optimizing TMD layers for better light absorption and conversion efficiency, marking a significant step towards cleaner and more sustainable energy sources. In the Long-Term, TMDs are expected to revolutionize the field of quantum computing. Research into the quantum mechanical properties of TMDs will likely lead to breakthroughs in developing qubits that are more stable at room temperature, significantly advancing quantum computing capabilities. This period will also witness TMDs enabling new forms of ultra-secure communication networks and sensors with unprecedented sensitivity, opening avenues for innovations in various scientific and technological domains.
Some interesting questions that has been asked about the results you have just received for Transition Metal Dichalcogenide
What are related technologies to Transition Metal Dichalcogenide?
Based on our calculations related technologies to Transition Metal Dichalcogenide are Glass, Superconductors, High-Performance Materials, Raw Materials, Phase Change Materials
Which industries are mostly working on Transition Metal Dichalcogenide?
The most represented industries which are working in Transition Metal Dichalcogenide are Science and Engineering, Consumer Electronics, Hardware, Manufacturing, Content and Publishing
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