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Amsterdam, Netherlands
51-100 Employees
2011
We are a growing team of 60+ passionate people, headquartered in Amsterdam, the Netherlands. We are a team of 60+ passionate people, headquartered in Amsterdam, the Netherlands. Due to the unique application of innovative technology, Chiaro can perform mechanical mapping from sub-cellular scale to whole tissue samples spanning several centimeters, without compromising data quality. Chiaro is a microscope-compatible system for mechanically characterizing soft materials, from single cells to complex 3D cellular systems, including organoids and spheroids. Our system is equipped with closed-loop XY stages, offering sub-micrometer positioning accuracy across 12 mm in each direction. Discover more about how our products can help you accelerate and achieve your research goals. Mechanobiology can be described as the intricate movement of forces within cells and tissues. We believe that having a better understanding of these forces allows for significant advancements in healthcare and therapy development.
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NANOINDENTATION PRODUCTS
... The Optics11Life Nanoindentation Products can Test the Mechanical Properties of Applications like Single Cells, Tissues, Hydrogels, and other ...
Jette, Belgium
11-50 Employees
2015
We are a team of chemical engineers, physicists, materials and data scientists with a mission to deliver world-class innovative solutions. Our vision is to employ advanced LCA modelling and integrate life cycle thinking in product development. IRES, founded in 2015, is devoted to provide decision making tools and methodologies for environmental, safety and risk assessment, materials characterization/digitization and process optimization. For this, the whole lifecycle of products is considered, through a holistic evaluation of social, environmental and economic aspects based on EU standards and regulations. We focus on the development of innovative solutions that can help Field Experts manage and process their scientific Data and add extra value to them beyond their initial purpose. Adapted to this crushing pressure, we address the challenge of transforming linear to circular production and support sustainable development by greening supply chains. IRES also provides services to organizations to be compliant to environmental management systems such as ISO14001 or EMAS. Contemporary research has applied novel materials, as well as unique manufacturing and processing routes to achieve end products of spectacular qualities and properties.
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IRES - Innovation-res.eu
... Nanoindentation in the today’s News: Materials novel characterization by harmonized ...
Leverkusen, Germany
1001-5000 Employees
2008
Bei der chemischen Produktion anfallende Reststoffe entsorgen wir nachhaltig. Gerne stellen wir Ihnen unser Leistungsangebot im Detail vor. Über unsere eigenen Netze und Rohrleitungen liefern wir es direkt zum Abnehmer vor Ort, kümmern uns um den sicheren Betrieb und die zuverlässige Lieferung. Langjährige Erfahrung in der Standortlogistik und im Umgang mit gefährlichen Gütern zeichnen uns hier aus. Wir bieten einen umfassenden analytischen Service für Forschung, Entwicklung und Produktion in der Industrie. Unsere qualifizierten Analytik-Expert*innen stehen Ihnen mit langjähriger Erfahrung, fundierten Fachkenntnissen und umfangreicher Produkterfahrung als engagierte und verlässliche Partner*innen zur Seite. Und ist der Partner für große und kleine Aufträge direkt vor Ort. Unsere qualifizierten Analytikexperten stehen Ihnen mit langjähriger Erfahrung, fundierten Fachkenntnissen und umfangreicher Produkterfahrung als engagierte und verlässliche Partner zur Seite.
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Nanoindentation – Härte auf mikroskopischer Skala
... Die Kombination von nanomechanischen Messungen in Form von Nanoindentation mit der Rasterkraftmikroskopie (AFM) eröffnet neue Wege in der Materialentwicklung und -prüfung sowie der Fehlstellenanalyse. CURRENTA Analytik unterstützt Sie bei Ihren Fragestellungen. ...
Germany
11-50 Employees
Fischer offers a wide range of solutions for the specific requirements of various industries and sectors. Find the right gauge for your measuring task here:. Enter the desired product or series name and get directly to the product through the suggested results. Depending on the activated level, you accept the previous levels by clicking the respective button. By clicking "Confirm selection" or "Select & confirm all", you also provide your consent in accordance with Art. 49 Para. 1 P. 1 lit. a GDPR for your data to be processed by the corresponding services in the USA.
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FISCHERSCOPE HM2000 – Automatisierte Nanoindentation
... FISCHERSCOPE HM2000 – Automatisierte Nanoindentation ...
Thun, Switzerland
1-10 Employees
2008
Alemnis AG is a pioneer in the field of in-situ material testing and is known for its innovations leading to breakthrough findings in materials science. Alemnis enables breakthrough academic research in material science by providing leading-edge micro- and nanomechanical property measurement instruments that can be applied in a wide variety of testing environments. Alemnis nanoindentation products are based on years of experience in the design of scientific instruments and piezoelectric transducers conducted in joint projects between EPFL (Swiss Federal Institute of Technology, Lausanne) and Empa (Swiss Federal Laboratories of Material Science and Technology, Thun). Alemnis offers a range of long-serving consumable products: calibrated indenters, heaters, sample stubs, and a variety of sample materials. Numerous Alemnis customers have shared their experiences of the ASA, its additional modules, and other Alemnis products. The in-situ Alemnis Standard Assembly (ASA) has opened the doors to unique crack growth characterization as well as specialized friction and wear techniques. Without the Alemnis nanoindenter we simply could not undertake research of such high quality as we currently do.”. Unique in its intrinsic displacement mode, the ASA offers unmatched accuracy and flexibility for both in-situ and ex-situ nanomechanical testing.
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Nanoindentation | In-Situ Mechanical Testing
... Nanoindentation ExpertsThe world’s most versatile, high performance and cost-effective nanoindentation platform for in-situ in-SEM and in-air use. ...
Vienna, Austria
11-50 Employees
We are a multidisciplinary team consisting of specialists in the fields of physics, electrical and mechanical engineering, biological sciences, semiconductor and MEMS processing, business and finance. We are more than happy to announce that Jürgen Schlütter joins GETec Microscopy as our new CEO. GETec was founded in 2011 as GETec KG and has been transferred to GETec Microscopy GmbH as its full legal successor in Oct. GETec Microscopy offers innovative Atomic Force Microscopy solutions for seamless integration into existing host systems like Scanning Electron Microscopes. In partnership with our customers, we develop dedicated nano analysis tools based on pre-engineered modules. It’s open access design allows to simultaneously operate SEM and AFM inside the SEM vacuum chamber. GETec’s leading Atomic Force Microscopy in SEM technology nicely complements Quantum Design’s strong position in materials property characterization instrumentation and optics,” stated Jerry Daviess, Chief Executive Officer for Quantum Design International. Especially the possibility to immediately control the result of your nanofabrication experiment is a real benefit!”.
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Home - GETec Microscopy
... Nanoindentation analysis with AFSEM® ...
Göttingen, Germany
1-10 Employees
We also use different external services like Google Webfonts, Google Maps, and external Video providers. Since these providers may collect personal data like your IP address we allow you to block them here.
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Charakterisierung von Bariumtitanat mittels Nanoindentation und Rasterkraftmikroskopie - sierke VERLAG
... Charakterisierung von Bariumtitanat mittels Nanoindentation und Rasterkraftmikroskopie - sierke ...
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NanoTechnology Solutions® - Helping you Discover...
... Electron Microscopy, SPM/AFM, Tensile Testing, Nanoindentation, Microscopy workstations, Optical Tables, Sample Prep, Plasma Cleaning, Wafers, in-situ ...
Czechia
11-50 Employees
2015
NenoVision is connecting a long tradition of development of scientific instruments with leading innovations within the industry. We are pioneers of in-situ correlative microscopy, developing and producing unique AFM-in-SEM LiteScope. Our mission is to create unique tools on the top technological level which drive new discoveries with significant impact.. Our vision is to build a successful technological company that provides researchers with innovative and unparalleled advanced scientific instrumentation. We develop, manufacture, and sell a revolutionary type of atomic force microscope (AFM) LiteScope™ designed for fast and easy integration into scanning electron microscopes (SEMs). NenoVision is a technology company based in Brno, Czech Republic. Our goal is to move microscopy to the next level. NenoVision continues with the established tradition and expertise within the field and brings innovative Correlative Probe and Electron Microscopy technology to the market.
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Modules for LiteScope AFM-in-SEM
... Nanoindentation ...
Kennesaw, United States
1001-5000 Employees
Our customers trust ZwickRoell for our global leadership in static testing and our significant growth in the field of fatigue testing systems. ZwickRoell in numbers: sales for the fiscal year 2022 totaled EUR 288 million. About ZwickRoell Quality & certificates ZwickRoell environmental and social involvement Careers at ZwickRoell ZwickRoell history Image brochure. At ZwickRoell, quality means realizing the high demand of our customers—something we prove with our flexible and sophisticated machine designs, and consistent reliable test results. ZwickRoell machine and software solutions are known for accuracy, repeatability, reproducibility and seamless traceability of test results. ZwickRoell is a family-owned company, and for years we have been committed to thinking and acting in a way that sustains our future and helps people in need. Become part of the ZwickRoell family with more than 190 product and industry experts, 75 trainees and interns and a total of 1800 employees around the world. We are a global leader in materials testing and your trusted partner for reliable test results.
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Nanoindenter for instrumented indentation tests | ZwickRoell
... The instrumented indentation test in the nano range (nanoindentation) is used for determination of the mechanical load capacity of very small components. ...
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Some interesting numbers and facts about the results you have just received for Nanoindentation
| Country with most fitting companies | United States |
| Amount of fitting manufacturers | 11 |
| Amount of suitable service providers | 10 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 2008 |
| Youngest suiting company | 2015 |
Nanoindentation is a high-resolution technique used for measuring the mechanical properties of materials at the nanometer scale, employing a hard, sharp indenter, typically made of diamond, to apply a controlled force to the surface of the material being tested. This process allows for the precise determination of material properties such as hardness, elastic modulus, and viscoelastic properties by monitoring the depth of penetration and the force applied. The method's sensitivity and small scale make it particularly valuable in fields such as materials science, engineering, and nanotechnology, where understanding the mechanical behavior of materials at the micro- to nanoscale is crucial for the development of advanced materials and devices. By enabling detailed analysis of thin films, coatings, and small volumes of material, nanoindentation has become an indispensable tool for researchers and developers, facilitating the design of materials with tailored properties for specific applications. Its ability to characterize the mechanical properties of materials at such small scales has profound implications, impacting the development of more durable and efficient materials for use in a wide range of applications, from electronics and biomedical devices to aerospace and automotive components. The technique’s precision, versatility, and non-destructive nature underscore its critical role in advancing material science and technology innovation.
1. Precision at the Nanoscale
: Nanoindentation offers an unparalleled level of precision by allowing measurements of mechanical properties such as hardness and elastic modulus at the nanometer scale. This makes it ideal for studying thin films, nanostructures, and other materials where understanding small-scale behaviors is crucial.
2. Minimal Sample Damage
: Compared to traditional indentation techniques, nanoindentation is less invasive and causes minimal damage to the sample. This is especially important for delicate materials or those where preserving the integrity of the sample is critical for subsequent analyses or applications.
3. High Throughput and Automation
: Modern nanoindentation tools are highly automated, allowing for rapid testing over a large number of points on a sample. This high throughput capability is beneficial for applications requiring statistical significance or the mapping of mechanical properties across a sample's surface.
4. Versatility
: Nanoindentation can be applied to a wide range of materials, from soft polymers to hard metals and ceramics. This versatility makes it a valuable tool across various fields, including materials science, engineering, and biology, for characterizing material properties under different environmental conditions.
While evaluating the different suppliers make sure to check the following criteria:
1. Technological Capabilities
Assess the precision, accuracy, and range of force/displacement of the nanoindentation equipment. The supplier should offer advanced technology that meets current research and industry standards.
2. Equipment Versatility
Consider the variety of materials the equipment can test, including soft polymers, metals, and ceramics, and its ability to perform in different environments (temperature, vacuum, etc.).
3. Software and Data Analysis
Evaluate the ease of use of the software for controlling the equipment and analyzing data. It should offer comprehensive analysis options, including hardness, modulus, and creep measurements.
4. Technical Support and Training
The supplier should provide thorough training on how to operate the equipment and analyze data, along with ongoing technical support.
5. Warranty and Service Agreements
Check the length of the warranty period and what it covers. Also, inquire about service agreements for maintenance and repairs.
6. Customer Reviews and References
Seek feedback from current users about their experience with the equipment and the supplier's service quality.
7. Price and Financing Options
Compare pricing among suppliers, but also consider financing options or payment plans that can alleviate upfront costs.
Nanoindentation, a precise method for measuring mechanical properties at the nanoscale, finds significant application across various industries, serving as a cornerstone for material innovation and quality assurance. In the semiconductor industry, nanoindentation is crucial for evaluating the mechanical properties of thin films and coatings. This data is essential for ensuring the reliability and durability of electronic components, where even the smallest imperfection can lead to failure. By understanding the hardness and elasticity of these materials, manufacturers can improve product longevity and performance. The biomedical sector leverages nanoindentation for studying the mechanical properties of biological tissues and biomaterials. This application is vital for developing medical implants and devices that are both durable and compatible with human tissue. By assessing how these materials behave under stress at the microscopic level, researchers can enhance the safety and effectiveness of medical products. Nanoindentation also plays a pivotal role in the automotive industry, particularly in the development of lightweight and strong materials. By characterizing the mechanical properties of metals, alloys, and composites, manufacturers can create vehicles that are not only fuel-efficient but also meet rigorous safety standards. This information helps in designing automotive components that can withstand extreme conditions while reducing overall vehicle weight. In the aerospace sector, understanding the mechanical integrity of materials under extreme conditions is paramount. Nanoindentation aids in evaluating the performance of materials used in aircraft and spacecraft, ensuring they can endure the harsh environments of space and high-altitude flight. This research is fundamental for advancing aerospace technology, where material failure is not an option. Overall, nanoindentation's ability to provide detailed insights into material behavior at the nanoscale makes it an indispensable tool across industries focused on pushing the boundaries of material science and engineering.
Nanoindentation, a technique used to measure the mechanical properties of materials at the nanoscale, such as hardness and elastic modulus, currently spans a range of Technology Readiness Levels (TRLs) depending on its application and development stage, with most established uses sitting at TRL 6 to TRL 8. This broad positioning is primarily because nanoindentation has moved beyond the proof-of-concept stage (TRLs 1-3) and undergone validation in laboratory environments (TRL 4-5) for various materials, including polymers, metals, and biomaterials. At TRL 6, it demonstrates the capability in relevant environments, indicative of its integration into higher-level systems like microelectromechanical systems (MEMS) and advanced material research, where its precision and reliability are crucial. The progression to TRLs 7 and 8 is marked by the demonstration in operational environments and the actual system completion, respectively, highlighting its transition from controlled settings to real-world applications. This transition is technically underpinned by advancements in nanoindentation tools, including the development of more sophisticated indenters, improved force application and measurement techniques, and enhanced data analysis software, which collectively increase the accuracy, reliability, and applicability of the technique. However, it has not fully reached TRL 9, as widespread commercial deployment and proven operational success across all potential applications are ongoing, reflecting both the evolving nature of nanoindentation technology and the expanding range of its applications.
In the short term, advancements in nanoindentation are expected to focus on enhancing accuracy and sensitivity through improved sensor technology and data analysis algorithms. This phase will likely see the integration of AI and machine learning for more precise material characterization, enabling researchers to analyze complex materials with greater speed and less human error. Developments in high-speed nanoindentation techniques will also allow for real-time property measurements, expanding the technique's applicability in dynamic material testing. Mid-term developments are anticipated to revolutionize nanoindentation by expanding its capabilities to a wider range of materials, including biological tissues and soft polymers, which have been challenging to analyze due to their delicate nature. This will be achieved through the advent of specialized indenter tips and adaptive loading techniques that can adjust in real-time to the material being tested. Additionally, the integration of nanoindentation with other nanoscale characterization techniques, such as Atomic Force Microscopy (AFM), will offer comprehensive multi-property analysis within a single experiment, enhancing the understanding of material behaviors at the nanoscale. In the long term, the focus will likely shift towards the development of in-situ nanoindentation techniques capable of operating under extreme conditions, such as high temperatures and radiation environments. This will open new frontiers in materials science, particularly in the study of materials for aerospace and nuclear applications. Furthermore, the miniaturization of nanoindentation equipment will enable portable, field-deployable systems, broadening the technique's application in onsite material evaluation and real-world condition monitoring, thus transforming the approach to material science research and quality control in manufacturing processes.
