The B2B platform for the best purchasing descision. Identify and compare relevant B2B manufacturers, suppliers and retailers
Filter
Locations
Result types
Type of company
Select company type
Industries
Select industry
Company status
Select company status preset
Number of employees
Min.
Max.
Founding year
Lock keywords
Exclude keywords
Optional keywords
London, United Kingdom
11-50 Employees
AQSE is a stock market providing primary and secondary markets for equity and debt products. It is authorised as a Recognised Investment Exchange, which allows it to operate a regulated listings venue. The ICFO is a Research Centre of Excellence based in Barcelona. It is an international leading research centre, founded in 2002 by the Government of Catalonia and Universitat Politècnica de Catalunya – Barcelona Tech and is dedicated to advancing the very limits of knowledge in several fields of science and technology where photonic-tools and related concepts provide an edge. The institute is made up of 80 state-of-the-art laboratories whose research is devoted to science and technology of Photonics. The IOP is the professional body and learned society for physics in the UK and Ireland, with an active role in promoting cooperation in physics around the world. IOP’s 21,000 members demonstrate their professional expertise in physics in settings ranging from schools, universities and national research facilities to businesses of all sizes, and in roles as varied as a teacher, researcher, apprentice, technician, engineer and product developer. UKQuantum is the voice of the UK quantum industry UKQuantum’s mission is to; Unite the UK quantum industry with one voice, champion within Government and internationally, advising on interventions and policies that will advance the UK quantum industry and promote the adoption and benefits of quantum technologies across the UK economy.
+
Featured
Strategy - Quantum
... Quantum Metrology ...
London, United Kingdom
11-50 Employees
AQSE is a stock market providing primary and secondary markets for equity and debt products. It is authorised as a Recognised Investment Exchange, which allows it to operate a regulated listings venue. The ICFO is a Research Centre of Excellence based in Barcelona. It is an international leading research centre, founded in 2002 by the Government of Catalonia and Universitat Politècnica de Catalunya – Barcelona Tech and is dedicated to advancing the very limits of knowledge in several fields of science and technology where photonic-tools and related concepts provide an edge. The institute is made up of 80 state-of-the-art laboratories whose research is devoted to science and technology of Photonics. The IOP is the professional body and learned society for physics in the UK and Ireland, with an active role in promoting cooperation in physics around the world. IOP’s 21,000 members demonstrate their professional expertise in physics in settings ranging from schools, universities and national research facilities to businesses of all sizes, and in roles as varied as a teacher, researcher, apprentice, technician, engineer and product developer. UKQuantum is the voice of the UK quantum industry UKQuantum’s mission is to; Unite the UK quantum industry with one voice, champion within Government and internationally, advising on interventions and policies that will advance the UK quantum industry and promote the adoption and benefits of quantum technologies across the UK economy.
+
Featured
Strategy - Quantum
... Quantum Metrology ...
Copenhagen, Denmark
1-10 Employees
2015
We are Sparrow Quantum, a Danish quantum technology company committed to pushing the boundaries of light-matter interfaces for quantum technologies. Our company was founded in 2016 in Copenhagen by Prof. Peter Lodahl, and we are widely recognized as a leader in single-photon sources, achieving the world’s highest light-matter coupling efficiency. We are passionate about providing researchers and developers of quantum technology systems with unparalleled technology and essential building blocks for scaling up photonic quantum technology applications in information processing and communication. Our technology finds applications in areas such as secure quantum communication, photonic quantum computing, and quantum repeaters for the quantum internet.
+
Featured
About us - Sparrow Quantum
... Quantum sensors for metrology based on single-atom-like device ...
Eindhoven, Netherlands
1-10 Employees
2021
ICeNd, a deep tech startup is committed to fostering a work environment that is diverse, equitable, and inclusive. We are committed to dedicating the necessary human resources and gender expertise to implement this plan effectively. We are committed to continuous improvement in our efforts to achieve gender equality. ICeNd is spun off to create pioneering artificial lives for the sustainability of humanity on earth and outside earth. We believe that gender equality is not just the right thing to do, but also essential for our continued success and innovation. Partnering with external experts on gender equality issues as needed. We will provide mandatory awareness-raising training on gender equality and unconscious gender bias for all staff and decision-makers. We will offer flexible work arrangements, such as remote work options and compressed workweeks, to support work-life balance for all employees.
+
Featured
ICeNd HQ at Eindhoven - About
... > ICeNd is a semiconductor quantum nanofluid company creating paradigm shifting universal nanodevices for smart detection of ultrasmall motions in real-time to impact the field of biology, quantum engineering, energy, metrology, ...
City of Edinburgh, United Kingdom
11-50 Employees
2013
An agile photonics company committed to providing quality, service and value. Using our proprietary BRaMMS Technology®, we develop light you can trust - as ultra-reliable, high performance, single-frequency lasers. - CW Operation- Single Longitudinal Mode- Linewidth ≤ 0.5 MHz. © Skylark Lasers Limited I Company registration SC 445 554.
+
Featured
Single Frequency C-DPSS Lasers | UV - NIR
... Suitable for Raman, Holography, Interferometry, Microscopy, Metrology, Quantum Technologies, and more. ...
Tewkesbury, United Kingdom
501-1000 Employees
1900
NPL provides the measurement capability that underpins the UK's prosperity and quality of life. The National Physical Laboratory (NPL) is the UK's National Metrology Institute (NMI), developing and maintaining the national primary measurement standards, as well as collaborating with other NMIs to maintain the international system of measurement. We develop the metrology required to ensure the timely and successful deployment of new technologies and work with organisations as they develop and test new products and processes. NPL is a Public Corporation owned by the Department for Science, Innovation and Technology. NPL is part of the National Measurement System (NMS) which provides the UK with a national measurement infrastructure and delivers the UK Measurement Strategy on behalf of the Department for Science, Innovation and Technology. We are the UK’s National Metrology Institute (NMI), a world-leading centre of excellence that provides cutting-edge measurement science, engineering and technology that underpins prosperity and quality of life in the UK. We provide confidence in measurement results and data traceable to SI units. NPL was established in 1900 with the aim to "bring scientific knowledge to bear practically upon our everyday industrial and commercial life." We have been making world-leading discoveries ever since.
+
Featured
Metrology for quantum photonic and quantum-secured technologies
... Metrology for quantum photonic and quantum-secured technologies - ...
Los Angeles, United States
11-50 Employees
1960
We are the only organization in the world that manufactures tachometer calibrators on a regular production basis, and also thus the only organization that provides continuous and ongoing support for the systems that monitor the speed of virtually all critical rotating assemblies. QUANTUM DYNAMICS was founded in 1959 to address specific US military metrology requirements, many of which were/are classified. Standardized in all military/civilian, fixed/mobile, developmental /production JETS, these high precision flow systems remain a major contributor to the development of ever higher efficiency gas turbine engines, and are the only flow systems capable of performing a one second military SNAP/RAPIDACCEL test using a single sensor. QUANTUM DYNAMICS measures the flow, verifies the engine tachometers, and provides the indication thereof: we are a critical element of modern jet engine development and test. Unlike many other manufacturers, QUANTUM DYNAMICS designs and delivered products rigorously fulfill contract specifications. Over the course of years, the civilian public has become aware of the excellent performance of QUANTUM DYNAMICS’ systems. These systems frequently save millions of dollars per year in fuel costs, while reducing emissions. Unlike many/most other manufacturers of “flowmeters” who are focused solely on large volume production and sales, we continue to maintain our technological leadership through the combination of scientific expertise, engineering excellence, and manufacturing prowess.
+
Featured
Homepage - Quantum-Dynamics Co., Inc.
... CAGE/FSCM 16951 Technologically Advanced Flow Metrology Solutions Quantum Dynamics Co.,Inc. systems landed the Apollo missions on the moon U.S. Defense Logistics Agency "Certified Quality Vendor" U.S. Navy "Quality / Best Value Contractor" ...
Paris, France
1-10 Employees
2018
The obvious answer is SNAIA – leading topical conference, which welcomes new ideas, promotes new collaborations, gives opportunities to young scientists, and… just lovely to attend. The STEMM Smart Nanomaterials (SNAIA) Conference Series is a unique, established science-to-technology networking platform covering the most exciting emerging fields in smart technologies. Notification of acceptance — 1 week from the submission day. Each year is a pleasure to attend Snaia in this very beautiful venue in the middle of Paris and to discuss with high level scientists.”. It gives the opportunity to present to, share knowledge with, and establish links between leading experts from academia and industry. This year, the 4th International SNAIA Conference is moving to a hybrid online-onsite format. Despite the current pandemic crisis, we are keeping our plans for the in-person part of SNAIA2021 in an unchanged format for now. We will do everything in our power to ensure participants safety and provide extensive information as it arrives.
+
Featured
Smart Nanomaterials
... Quantum Optics and Quantum Metrology ...
Milan, Italy
1-10 Employees
1975
Our company works and supplies high-tech products in the fields of:. Reflection and transmission spectroscopy applications thanks to the wide emission spectrum from 400nm to 750nm.
+
Featured
Complete solutions in Optical Frequency Combs, Terahertz Systems, and Ultrafast Fiber Lasers for Metrology, Quantum Optics, Astronomy, Femtosecond, Spectroscopy and Life Sciences
... Complete solutions in Optical Frequency Combs, Terahertz Systems, and Ultrafast Fiber Lasers for Metrology, Quantum Optics, Astronomy, Femtosecond, Spectroscopy and Life ...
Stockholm, Sweden
11-50 Employees
2011
Together the researchers of Graphensic have over 500 publications, four patent families and more 50 years of experience related to epitaxial graphene specifically. Graphensic is a member of the Swedish initiative for graphene development (SIO Grafen). The company was founded in November 2011 and became the first European supplier of epitaxial graphene on silicon carbide. An undesirable consequence of this phenomenon is the enhanced Si sublimation at the step edges which facilitates local bilayer graphene formation. The co-founders, Professor Rositsa Yakimova and collegues, have the mission to progress the company to become a leading supplier of wafer scale graphene not only in Europe but worldwide. The strong interaction between the company and the research group is a motor of the new product development. Graphene is a crystal plane built up of carbon (C) atoms with sp2 bonding in a honeycomb lattice in which carbon participates with three in-plane bonds while the forth one is unsaturated bond in the perpendicular direction.
+
Featured
Home – Graphensic
... Quantum metrology breakthrough using ...
Technologies which have been searched by others and may be interesting for you:
Some interesting numbers and facts about the results you have just received for Quantum Metrology
| Country with most fitting companies | United Kingdom |
| Amount of fitting manufacturers | 7 |
| Amount of suitable service providers | 3 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 1900 |
| Youngest suiting company | 2021 |
Quantum metrology is a subfield of measurement science that utilizes the principles of quantum mechanics to achieve measurements with precision beyond the capabilities of classical metrology techniques. It relies on the exploitation of quantum phenomena such as superposition, entanglement, and quantum interference to enhance the sensitivity and resolution of measurement instruments. By manipulating quantum states and utilizing quantum systems as measurement devices, quantum metrology offers significant improvements in the accuracy of timekeeping, the definition of standards of electrical currents, lengths, and other fundamental physical quantities. This enhancement in measurement precision is pivotal in various applications, including more accurate and sensitive gravitational wave detection, improved navigation and timing systems, and enhanced resolution in microscopy and imaging technologies. The impact of quantum metrology extends beyond improved measurement capabilities; it drives innovation in quantum computing and quantum information science by providing the foundational tools necessary for the control and characterization of quantum systems. Furthermore, the advancement in quantum metrology opens new frontiers in fundamental physics, allowing for tests of the limits of quantum mechanics and exploration of the boundaries between quantum and classical worlds. As such, quantum metrology stands at the intersection of theoretical physics, experimental science, and technological development, heralding a new era of precision in scientific research and applied technologies.
1. Enhanced Precision:
Quantum metrology leverages the principles of quantum mechanics, such as entanglement and superposition, to measure physical quantities with unprecedented precision. This is crucial in fields like timekeeping, where atomic clocks achieve accuracy by measuring the vibrations of atoms in quantum states.
2. Improved Sensitivity:
By utilizing quantum states that are highly sensitive to environmental changes, quantum metrology offers improved sensitivity over classical methods. This makes it indispensable for applications requiring the detection of minute changes, such as gravitational wave detection in astrophysics or monitoring volcanic activity.
3. Reduced Measurement Time:
Quantum metrology can significantly reduce the time needed for measurements. This efficiency is due to the ability to process information and perform measurements on quantum systems more quickly than with traditional methods, benefiting fast-paced industries and research fields.
4. Lower Resource Consumption:
Quantum metrology often requires fewer resources, such as energy or physical material, for the same or even better levels of accuracy compared to classical metrology. This efficiency contributes to more sustainable practices in scientific research and industrial processes.
While evaluating the different suppliers make sure to check the following criteria:
1. Technical Expertise and Experience
Ensure the supplier has a strong background in quantum metrology, including relevant projects and a track record of innovation and problem-solving.
2. Quality of Quantum Sensors
Evaluate the performance, sensitivity, and accuracy of the quantum sensors offered. High-quality sensors are crucial for precise measurements.
3. Customization Capabilities
Check if the supplier can tailor their solutions to fit your specific needs, as quantum metrology applications can vary widely across different fields.
4. Support and Maintenance Services
Assess the level of post-purchase support, including maintenance, calibration services, and technical assistance, to ensure long-term reliability.
5. Scalability
The supplier should offer solutions that can scale with your project or operational needs, allowing for future growth and development.
6. Compliance with Standards
Make sure the supplier adheres to relevant industry standards and certifications, ensuring their products and services meet regulatory requirements.
7. Cost-Effectiveness
While not compromising on quality and performance, consider the overall cost-effectiveness of the supplier's offerings, including initial investment, operating costs, and potential savings.
Quantum metrology, leveraging the principles of quantum mechanics to achieve high-precision measurements, finds its applications across a spectrum of industries, enhancing accuracy and efficiency in business-to-business (B2B) operations. In the field of telecommunications, quantum metrology is pivotal for improving the synchronization of global networks. The technology enables the development of ultra-precise atomic clocks that surpass traditional timekeeping methods, ensuring more reliable and faster data transmission between businesses worldwide. This advancement not only optimizes network efficiency but also enhances security protocols through improved encryption techniques. The pharmaceutical industry benefits from quantum metrology in the realm of drug development. By enabling precise measurements at the molecular level, it allows for more accurate modeling of drug interactions and reactions. This precision accelerates the drug discovery process, reducing costs and time-to-market for new medications. Pharmaceutical companies can thus offer more effective treatments faster, gaining a competitive edge. In aerospace and defense, quantum metrology enhances navigation and sensing technologies. Quantum sensors, for instance, provide unprecedented accuracy in measuring gravitational fields, enabling more precise navigation systems for both manned and unmanned vehicles. This capability is crucial for operations in environments where traditional GPS systems are unreliable or unavailable, improving safety and operational efficiency. Quantum metrology is also revolutionizing the energy sector by enabling more accurate measurements of electric and magnetic fields. This leads to improved monitoring and management of power grids, optimizing energy distribution and reducing waste. Energy companies can thus ensure a more stable and efficient supply of electricity, catering to the growing demand with enhanced sustainability. These use cases across telecommunications, pharmaceuticals, aerospace and defense, and energy sectors underscore the transformative potential of quantum metrology in fostering innovation, enhancing precision, and driving efficiency in B2B operations.
As of the most recent assessments, Quantum Metrology is predominantly situated between TRL 3 and TRL 5. This placement is due to the technology's evolution from proof-of-concept experiments (TRL 3), demonstrating the feasibility of quantum-enhanced measurement techniques, to the integration of these concepts into more complex system prototypes tested in relevant environments (TRL 5). The technical reasons underpinning this TRL positioning stem from several factors. Firstly, quantum metrology leverages the principles of quantum mechanics, such as superposition and entanglement, to achieve measurement precisions beyond the limits of classical physics. However, the practical realization of these principles into operational technologies is challenging, requiring sophisticated control over quantum systems and mitigation of decoherence effects. Secondly, while there have been significant advances in demonstrating enhanced measurement sensitivities in laboratory settings, transitioning these capabilities to real-world applications faces hurdles in robustness, scalability, and integration with existing technological infrastructures. The development of quantum sensors and clocks exemplifies this progress, showcasing improved precision but also highlighting the need for further advancements in technology readiness before widespread deployment. Thus, the current TRL reflects both the demonstrated potential of quantum metrology and the ongoing efforts to address the technological challenges inherent in bringing quantum-enhanced measurements from the lab to the field.
In the Short-Term, quantum metrology is set to enhance precision measurements significantly, leveraging quantum entanglement and superposition. This phase will witness the development and miniaturization of quantum sensors, which are expected to revolutionize fields such as magnetic resonance imaging (MRI) and timekeeping. The focus will be on refining existing quantum technologies to improve their sensitivity and reliability for commercial and scientific applications. Immediate advancements will likely include more precise atomic clocks and enhanced geophysical survey techniques, benefiting navigation, telecommunications, and environmental monitoring. Mid-Term developments in quantum metrology will likely see the integration of quantum technologies into broader industrial applications, driven by breakthroughs in quantum computing and materials science. This period will mark the advent of quantum-enhanced measurements that are not only more precise but also capable of measuring new physical quantities that were previously inaccessible. The implementation of quantum networks for distributed quantum sensing will enable unprecedented synchronization across vast distances, improving global positioning systems (GPS) and facilitating deep-space communication. This phase will also witness quantum metrology pushing the limits of accuracy in temperature measurements and electromagnetic field detection, influencing sectors from healthcare diagnostics to cybersecurity. In the Long-Term, quantum metrology is expected to redefine the standards of measurement, establishing new benchmarks for accuracy and sensitivity. Quantum technologies could enable the direct measurement of gravitational waves, dark matter, and other elusive cosmic phenomena, opening new frontiers in astrophysics and cosmology. Innovations in this phase will likely include self-calibrating quantum devices and the widespread adoption of quantum standards for measuring fundamental constants. This era will also explore the quantum limits of measurements, potentially leading to breakthroughs in understanding the fundamental principles of physics. The long-term advancements in quantum metrology promise not only to enhance our technological capabilities but also to deepen our comprehension of the universe.
