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Fremont, United States
NTherma invented a breakthrough & scalable production technology to manufacture Graphene Molecular Wires TM and other carbon nanomaterials with precise structural specifications, high quality, and low cost creating game-changing products for Energy Storage, Coatings, Thermal Management, and Lubrication markets. NTherma’s technology is comprised of both equipment and process that produce multi-walled CNTs and Graphene without the need for a purification process, therefore cutting costs significantly. Our process enables greater control of crystallinity and structural dimension of the carbon nanomaterials. Various carbon structures exist at the nanoscale with various properties. Structural variations in these allotropes of carbons are many, ranging from diamond, graphite, carbon blacks (amorphous carbons), carbon nanotubes, graphene, fullerene (ball structure), carbon fibers etc.
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Featured
Graphene Nanoribbons & Graphene Nanoplatelets
... NTherma’s family of graphene nanomaterials compose of graphene nanoribbons and graphene nanoplatelets. Our patent-pending technology produces... greater than 99% purity, high crystallinity and at significantly […] ...
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-PS Narrow-Bandwidth OPA - LIGHT CONVERSION
... Exciton and phonon dynamics in highly aligned 7-atom wide armchair graphene nanoribbons as seen by time-resolved spontaneous Raman ...
Kyoto, Japan
5001-10000 Employees
1945
The HORIBA Group of worldwide companies provides an extensive array of instruments and systems for applications ranging from automotive R&D, process and environmental monitoring, in-vitro medical diagnostics, semiconductor manufacturing and metrology, to a broad range of scientific R&D and QC measurements. HORIBA Automotive provides innovative applications and insights, advanced automotive validation and…. HORIBA Medical designs, develops and distributes worldwide, in vitro diagnostic systems mainly…. HORIBA Process and Environmental provides a wide range of technologies to measure air, water and…. HORIBA Semiconductor have developed a line-up of fluid control, vaporization, analytical equipment…. HORIBA Scientific offers 200 years of experience in developing high-performance scientific…. HORIBA water and liquid analysis technology is based on 75 years’ experience since the foundation of…. Since establishing HORIBA RADIO LABORATORY in Japan in 1945, HORIBA has grown as an R&D company and engaged in international operations, making the most of its experiences and encounters with people along the way.
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Featured
AFM Optical Platform - NanoRaman - HORIBA
... TERS Characterization of Graphene Nanoribbons ...
Washington, United States
A communication resource from the world's particle physics laboratories. An artist’s composition of the Milky Way seen through a neutrino lens (blue). National Science Foundation (Lily Le & Shawn Johnson)/ESO (S. Our Milky Way galaxy is an awe-inspiring feature of the night sky, viewable with the naked eye as a horizon-to-horizon hazy band of stars. Now, for the first time, the IceCube Neutrino Observatory has produced an image of the Milky Way using neutrinos—tiny, ghostlike astronomical messengers.
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Interactions.org - Particle physics, high energy physics, news and resources
... Technique Tunes Into Graphene Nanoribbons’ Electronic ...
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Featured
Home - Advances in Engineering
... Interfacial modulation of TiN nanoribbons/graphene oxide for high performance ...
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Some interesting numbers and facts about the results you have just received for Graphene Nanoribbons
| Country with most fitting companies | United States |
| Amount of fitting manufacturers | 3 |
| Amount of suitable service providers | 2 |
| Oldest suiting company | 1945 |
| Youngest suiting company | 1994 |
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Graphene nanoribbons (GNRs) are narrow, quasi-one-dimensional strips of graphene, a single layer of carbon atoms arranged in a hexagonal lattice. These materials exhibit unique electrical, thermal, and mechanical properties, distinguishing them from both graphene sheets and other nanomaterials. The width of GNRs is typically less than 50 nanometers, and this confinement leads to quantized energy levels, which significantly alter their electronic properties. This quantization endows GNRs with a tunable bandgap, a feature absent in graphene sheets, making them highly promising for nanoelectronics and optoelectronics applications. The controlled synthesis of GNRs allows for the manipulation of their electronic characteristics, enabling the development of highly efficient transistors, sensors, and conductive films. Furthermore, their high surface-to-volume ratio and edge-specific properties are leveraged in catalysis and energy storage, notably in the design of advanced battery electrodes and supercapacitors. The integration of GNRs into composite materials also enhances mechanical properties and thermal conductivity, broadening their applicability in aerospace, automotive, and flexible electronics industries. The versatility and superior properties of graphene nanoribbons underscore their potential to revolutionize multiple technological fields, driving advancements in electronics, energy, and materials science.
1. Enhanced Electrical Conductivity
Graphene nanoribbons showcase superior electrical conductivity compared to other nanomaterials. This property stems from graphene's unique atomic structure, enabling faster and more efficient electrical signal transmission. This makes them ideal for advanced electronic applications, including high-speed computer chips and next-generation display technologies.
2. Exceptional Mechanical Strength
Despite their slender form, graphene nanoribbons possess remarkable mechanical strength. They are significantly stronger and more flexible than conventional materials, making them suitable for reinforcing composites used in aerospace, automotive, and various structural applications. This strength, coupled with lightweight characteristics, offers substantial benefits in terms of performance and durability.
3. Customizable Electronic Properties
A unique advantage of graphene nanoribbons lies in their tunable electronic properties. By adjusting the width and edge structure of the ribbons, it's possible to precisely control their conductive, semiconductive, or insulative behaviors. This versatility opens up new possibilities for designing custom electronic components and devices, paving the way for innovative technological advancements.
1. Purity Levels
Ensure the supplier can provide Graphene Nanoribbons with high levels of purity, critical for superior performance in applications.
2. Production Capacity
Verify the supplier's ability to meet your demand, considering both current needs and potential scalability for future requirements.
3. Consistency of Quality
Look for suppliers with robust quality control processes to guarantee consistent product quality across batches.
4. Customization Options
Check if the supplier offers customization in terms of sizes, lengths, and functionalization of Graphene Nanoribbons to match specific application needs.
5. Technical Support
Assess the level of technical support and consultation the supplier offers, which can be invaluable for integrating the material into your product.
6. Compliance and Certifications
Ensure the supplier adheres to relevant industry standards and holds necessary certifications for safety and environmental compliance.
7. Cost-effectiveness
While quality should not be compromised, evaluate the cost-effectiveness of their offering to ensure it aligns with your budget constraints.
Graphene nanoribbons (GNRs) are increasingly pivotal in the electronics industry due to their exceptional electrical conductivity and thinness, making them ideal for developing advanced, energy-efficient semiconductors. These semiconductors can significantly reduce power consumption in devices, from computers to smartphones, offering manufacturers the opportunity to create more sustainable products. In the realm of composite materials, GNRs contribute to enhancing strength and flexibility without adding significant weight. This characteristic is particularly beneficial in the aerospace and automotive sectors, where reducing weight is crucial for fuel efficiency and performance. Manufacturers incorporate GNRs into materials to produce lighter, stronger, and more durable components, revolutionizing design and functionality standards. Another innovative application of GNRs is in the field of energy storage. They are used to improve the capacity and charging rates of batteries and supercapacitors. This advancement is critical for the renewable energy sector, enabling more efficient storage solutions that can accommodate the irregularities of renewable energy sources. Consequently, companies specializing in energy storage technologies are keenly interested in integrating GNRs to enhance their products' performance. Lastly, GNRs are finding applications in the medical field, particularly in drug delivery systems. Their unique properties allow for the creation of highly targeted delivery mechanisms, potentially increasing the efficacy of treatments while minimizing side effects. This use case represents a significant leap forward in personalized medicine, offering pharmaceutical companies a new tool for developing more effective therapies.
Graphene nanoribbons, with their exceptional electronic and mechanical properties, currently find themselves primarily within the mid-range of the Technology Readiness Level (TRL) spectrum, generally between TRL 3 and TRL 4. This positioning reflects the transition from experimental proof of concept to technology validation in a laboratory environment. The primary technical reason behind this specific TRL categorization is the challenge associated with the scalable and controllable synthesis of graphene nanoribbons. Despite the significant progress in isolating and manipulating graphene, producing nanoribbons with precise widths, edges, and dopant concentrations remains a complex task, crucial for their application in electronics and optoelectronics. Moreover, the integration of graphene nanoribbons into existing semiconductor manufacturing processes and their compatibility with other materials are still under rigorous investigation. These challenges, coupled with the need for further validation of their long-term stability and performance under various conditions, underscore why graphene nanoribbons are yet to advance to higher levels of technological readiness, where their practical application and mass production can be realistically contemplated.
In the short-term, advancements in graphene nanoribbons are poised to revolutionize the electronics industry. Researchers are focused on refining the production process to yield higher quality, more consistent materials. This includes developing techniques for more precise control over the nanoribbons' width and edge structure, which are critical for their electrical conductivity properties. These improvements are expected to lead to more efficient transistors and sensors, enhancing the performance of electronic devices. Looking into the mid-term, the integration of graphene nanoribbons into energy storage technologies is anticipated. As scientists gain a better understanding of their superior electrical and thermal conductivity, efforts will concentrate on leveraging these properties in batteries and supercapacitors. This could dramatically increase energy storage capacity and charging speeds, potentially transforming the electric vehicle market by making longer-range, faster-charging batteries a reality. In the long-term, the focus will shift towards exploiting the unique properties of graphene nanoribbons in medical and environmental applications. Innovations may include highly sensitive biosensors for early disease detection and new filtration technologies for water purification. The material's flexibility combined with its conductivity could enable the development of wearable health monitoring devices or smart textiles, marking a significant leap forward in both healthcare and environmental conservation.
Some interesting questions that has been asked about the results you have just received for Graphene Nanoribbons
What are related technologies to Graphene Nanoribbons?
Based on our calculations related technologies to Graphene Nanoribbons are Glass, Superconductors, High-Performance Materials, Raw Materials, Phase Change Materials
Which industries are mostly working on Graphene Nanoribbons?
The most represented industries which are working in Graphene Nanoribbons are Manufacturing, Consumer Electronics, Hardware, Science and Engineering, Transportation
How does ensun find these Graphene Nanoribbons Companies?
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