For Nanoscientific Research Shop Park Fx40 Park FX40 infuses artificial intelligence with robotics, enabling automated processes and machine learning for your nanoscale microscopy needs. Additional axis cameras automatically align in synch with laser beams and photodetectors. For more information visit our website https://www.parksystems.com/products/small-sample-afm/park-fx40 or contact us on 408-986-1110.

Accurate Measurement Of Nanomechanical Properties Using AFM Force-Indentation Curve

The 2020 NanoScientific Symposium Korea, which was held jointly with the Korean Microscopy Association Fall Conference, has been successfully concluded. In the 9th event, a heated discussion was held to introduce and share various applied technologies with the participation and interest of many AFM researchers even in the situation of Corona 19. We edit and share some lectures from several presentations.

We hope this will be a good resource for researchers interested in SPM, AFM and applied technology.

For more information on the Nano Scientific Symposium, please visit the website below https://www.youtube.com/watch?v=segTqK1Td8E.

Atomic Force Microscopy – Everything You Want to Know

Atomic force microscopes (AFM) are high resolution scanning probe microscopes with high resolution imaging that can measure fractions of a nanometer. They have become one of the most essential tools used for imaging on nanometer scales. AFM's rely on a cantilever which has a sharp probe, which is used to scan the surface of a sample. The tip travels close to the surface measuring the forces between the sample and tip.

Atomic force microscopes can measure numerous forces, based on the situation and sample being measured. The force between the tip and sample deflects the cantilever, changing the reflection of the laser beam. The beam shines directly onto the surface onto a host of photodiodes, which measure the variation in the forces.

The most common modes of operation for AFM's is contact and non contact mode. This is based on whether the cantilever vibrates when operating the device. Contact mode means the cantilever drags across the sample and relies on the deflection of the cantilever to measure the surface contours. In order to eliminate any noise and draft that could impact th image, low stiffness cantilevers are used allowing strong forces to pull the tip to the surface.

Non contact mode means a slight vibration in the tip, just above resonance frequency. This method means the tip does not contact the sample surface. Long range forces decrease the cantilevers resonant frequency. A feedback loop is used to maintain osculation amplitude of the changing distance from sample to tip. It records the distances at each point with software creating a topographical image.

The problem is that most samples will have some moisture layer, especially wen stored at ambient temperatures, which can make it harder to get accurate sample measurements. When the probe is close enough to eh surface to detect any short range forces, it can get stuck to the moisture. Tapping or dynamic contact mode is recommended in these situations.

The next scanning technique used in atomic force microscopy, especially when faced with a moist sample surface is tapping mode, which is when the cantilever relies on piezoelectric element mounted at the top to oscillate close to resonance frequency. The forces result in the amplitude decreasing as it gets closer to the sample surface, adjusting the cantilever height. Tapping causes less damage to samples than contact mode, it is more accurate on samples which have a moisture layer.

Atomic force microscopy is a very powerful tool and essential to measure any small samples with excellent accuracy. It doesn't need a vacuum or any metal coating treatment in order to get the images you need, which means less damage to the sample. Further, it has proven itself in ambient air and liquid environments.

You also need to ensure that you understand any downsides to using an atomic force microscope such as the single scan size, when you compare it to the millimeters offered by other microscopes, such as the scanning electron microscope.

What is also a downside to the AFM is that it scans very slowly, which can cause a thermal drift on the image. Manufacturers are constantly working on improving signal to noise ratios and reducing the risk of thermal drift. While the risk of thermal drift is high on the AFM image due to the slow scan time, it produces very high quality images when compared to ht scanning electron microscope, which scans considerably faster with lower quality images..

About Us: Park Systems is a leading supplier of AFM systems. This well-established company provides their clients with years of knowledge and experience in the industry. They comprise of a dedicated team of experienced professionals who focus on providing the highest level of service and support to their clients on a daily basis. Park Systems design their system with care and attention to detail. They are focus driven and have built up a solid reputation on a global scale. The company has a global sales network providing thirty years of experience with over 1,000 AFM’s available. They are the fastest growing AFM company with more than one hundred and twenty full time employees. To find out more, visit https://parksystems.com.

Atomic Force Microscopy Pros and Cons

Atomic Force Microscopy is growing in demand around the world, but just like any other device, it has it's limitations. When deciding whether to analyze a sample using an AFM, you need to know the pros and cons of the device to ensure you use the right equipment for the project.

Atomic force microscopy offers many great advantages when compared to scanning electron microscopes. AFM's provide the convenience of three dimensional profiles, rather than the two dimension provided by the scanning elecron microscope.

In addition to this, when using an atomic force microscope, you don't have to do any special treatment to the sample, so no need to provide a metal coating, which can damage the sample. Unlike the scanning electron microscope that requires a vacuum environment to operate effectively, the atomic force microscope can work in ambient air and in liquid, making it ideal for studying living organisms.

AFM's are also able to provide the highest resolution images. The images produced are significantly better quality than the scanning electron microscope, showing rue atomic resolution.

When choosing the best imaging technique for your particular sample, you also need to know the disadvantages of the atomic force microscope. The biggest downside of these devices is their single scan image size. Scanning electron microscopes, for example are able to image an area in square millimeters with depth of field based on the order of millimeters. The AFM, on the other hand, only images a maximum height in ten to twenty micrometers with maximum scanning area being 150 x 150 micrometers.

When it comes to scanning speed, the AFM falls short when compared to the scanning electron microscope. Scanning electron microscopes scan close to real time, but their quality isn't as high. The AFM takes a good few minutes to carry out a scan, but offers a higher quality image. The slow imaging speed has been known to result in a thermal drift, which makes it difficult on topographical projects, this has been eliminated using new methods, which have been introduced.

It's not uncommon to have to use software filtering and enhancements on AFM images, due to the hystersis effect of piezoelectric materials and the cross in the x, y, z axles. This can result in topographical features being flattened. These problems have mostly been eliminated in the newer AFM products.

The final disadvantage you need to be aware of is that atomic force microscopes are not good at measuring overhangs and steep walls. For this you need a specifically designed cantilever which can move up and down and side to side.

When choosing between the different imaging methods, it's also important to focus on the suppliers and the quality of the product, ensuring you achieve accurate results. There are numerous AFM products on the market, supplied by a host of specialists. This is why you need to follow some important steps to ensure you make the right selection, spending your budget wisely.

First make use of recommendations from other researchers on the suppliers they use and the brands they trust. Visit the internet and find suppliers that will deliver to your location that have a good name in the industry.. Research and review the suppliers, get to know about them, their experience and their host of products, review them to ensure they have glowing online reviews. Finally compare them to find a brand you feel confident in using.

About Us: Park Systems is a leading supplier of AFM systems. This well-established company provides their clients with years of knowledge and experience in the industry. They comprise of a dedicated team of experienced professionals who focus on providing the highest level of service and support to their clients on a daily basis. Park Systems design their system with care and attention to detail. They are focus driven and have built up a solid reputation on a global scale. The company has a global sales network providing thirty years of experience with over 1,000 AFM’s available. They are the fastest growing AFM company with more than one hundred and twenty full time employees. To find out more, visit https://parksystems.com.

AFM Applications – What You Need to Know

Atomic Force Microscopy (AFM) is a technique which scans the surface of a sample with nanometer resolution. This device enables researchers to study at nanoscale without causing damage to the sample. Atomic Force Microscopy is used to collect data on mechanical, electrical and functional properties at nanoscale level. It is also used extensively in surface studies.

AFM's scan the surface using a small probe which is controlled by elements with a feedback loop, which is connected to a computer. It moves back and forth over a small area, gathering interaction and profile data. The probe traces the surface. The probe is usually made of silicon nitrate with a free moving cantilever that is attached to a carrying chip. The cantilever is a thin arm of silicon, while the tip is very sharp and is placed at the end of the cantilever. The cantilever detection is determined by the forces between the tip and sample.

Data is collected based on the surface and probe tip interaction as it scans the surface. A laser beam is focused at the back of the cantilever reflecting to a photodiode, recording the surface. The tip interacting with the surface is best described as the needle on a vinyl record player and how it interacts with the record being played. This enables the surface to be captured at a high resolution.

These devices operate on a number of different modes, including contact, static, tapping and dynamic. When the tip moves across the sample surface making contact, this is contact mode. The feedback remains constant, offering constant force topography, which is recorded. Note that the force can cause damage to the sample and wear the probe tip down.

In tapping mode, the cantilever is oscillated at resonant frequency, the amplitude is then measured and used to create an imaging loop. The amplitude becomes the image, the tip forces on the sample is reduce and the risk of damaging the tip and sample is reduced. Tapping mode provides more detail with higher resonance models.

Fast Force Mapp9ng Mode is another of the imaging techniques used with AFMs. It measures the force distance curves at a very high speed, capturing all the curves. Analysis models can be applied offline and in real time to calculate modulus, adhesion and other properties, along with basic topography.

Atomic Force Microscopy is considered one of the most effective imaging techniques used on subnanoscale and nanoscale levels. It has been applied in a number of problems in the field of natural sciences, recording a sot of material surfaces in the air and in liquid. AFM applications include semiconductor sciences and technology thin films and coatings and tribology, which is the interaction between surface and friction.

In addition to this, AFM applications include cell biology, molecular biology and polymer chemistry and physicals, along with energy generation and energy storage and more. It is a very powerful measurement and imaging technique and that become valuable and vital to nanoscale research

AFM”s are used at universities and commercial companies around the world in the development of circuits and more. It is important when purchasing a device of this nature that you do your research to find the best brand to purchase with confidence, that will not only provide you with the highest resolution, but with the best after sales service and support. Do your research, learn about the company, before reviewing and comparing them to find the one you feel confidence in buying from.

About Us: Park Systems is a leading supplier of AFM systems. This well-established company provides their clients with years of knowledge and experience in the industry. They comprise of a dedicated team of experienced professionals who focus on providing the highest level of service and support to their clients on a daily basis. Park Systems design their system with care and attention to detail. They are focus driven and have built up a solid reputation on a global scale. The company has a global sales network providing thirty years of experience with over 1,000 AFM’s available. They are the fastest growing AFM company with more than one hundred and twenty full time employees. To find out more, visit https://parksystems.com.

Difference Between Scanning Tunneling Microscope and Scanning Electron Microscope

Scanning electron microscopes have the ability to render high quality images and is considered one of the most powerful optical microscopes on the market. The Scanning Electron Microscope (SEM) creates a beam of electrons using an electron gun, the beam follows a path via the microscope using a vacuum, electromagnetic fields and lenses to focus down to a sample. Once the beam makes contact with the same, the electrons and Xrays are ejected from the sample and collected, converting them into a signal that displays the image on a screen.

The scanning electron microscope images samples through scanning using a high focused electron beam. It strikes individual atoms within the sample you are investigating, detecting the electrons and extracting information on the surface and inner structures. Objects can be observed at elevated temperatures, in a vacuum, wet or dry.

Scanning electron microscopes were developed way back in the 1960's, but didn't become commercially available until the 1960's. They are very complex instruments, which don't come with a cheap price tag, but offer detailed imaging on numerous samples. Scanning with a concentrated beam can created electrostatic charges and prevent imaging, which is why the sample needed to be electrically grounded. Non metal objects are the problem and must go through a plating application before imaging.

This type of imaging is used for integrated circuit analysis. There is a difference between the scanning electron microscope and the scanning tunneling microscope (STM). Scanning tunneling microscopes are able to imagine objects at more than ten times the lateral resolution to 0.1 nanometers. Quantum mechanics is what tunneling is based on theoretically. A conventional object has an impenetrable barrier. In the quantum realm, an object with minimal mass will posses attributes of a wave, crossing the impenetrable barrier. This is known as tunneling, arising from electrons near Fermi level.

Scanning tunneling microscopes use a conducting tip that comes close to the sample. A bias voltage between the two points and electrons cross the vacuum between the points. The tunneling current is based on the position, voltage and density of the sample, providing the basis for the high quality image. Everything is mapped with respect to any changes in position. Images are high resolution without any vibrations.

Where scanning tunneling microscopes shine is that they are able to manipulate objects at atomic levels. This is cutting edge technology used extensively in nanotechnology.

When it comes to buying microscopes for your laboratory, it's essential you purchase the finest quality, buying from a company with a proven reputation for reliability and high quality when it comes to their scanning electron microscopes and their scanning tunneling microscopes.

Attend nanotechnology events if interested in scanning tunneling microscopes where you can meet the industry leaders, see product demonstrations in person and discuss your requirements. Make use of recommendations by other researchers and use the internet to your advantage to identify the best suppliers with the best reputation in the industry.

Search for AFM suppliers online and make use of their websites to learn about the company, their experience and their host of products. Look for those that can assist with all your microscopy needs from providing you with the microscopes to the applications. Make use of review sites to get feedback from past and present clients before reviewing the suppliers to fin the one you feel most comfortable in purchasing from.

About Us:Park Systems is a leading supplier of AFM systems. This well-established company provides their clients with years of knowledge and experience in the industry. They comprise of a dedicated team of experienced professionals who focus on providing the highest level of service and support to their clients on a daily basis. Park Systems design their system with care and attention to detail. They are focus driven and have built up a solid reputation on a global scale. The company has a global sales network providing thirty years of experience with over 1,000 AFM’s available. They are the fastest growing AFM company with more than one hundred and twenty full time employees. To find out more, visit https://parksystems.com.

PinPointing Polymers: Nanomechanical Characterization of Functional Polymer Blends | Park Webinar

Polymer based blends and composites are a key area of materials research activity.For example, blends of polymers are used in optoelectronic devices for charge extraction, and biopolymers which change their mechanical character upon environmental influences.

To know more contact us on : https://www.parksystems.com

Introducing NanoScience Center Europe

NanoScience Center Europe of Park Systems, located in Mannheim, Germany, is equipped with full range of academic and industrial research AFMs, including Park NX10, small sample AFM for material and life science.

To know more contact us on : https://www.parksystems.com

Atomic Force Microscopy Market Showing Promising Signs of Exponential Growth

The need for advancements in a wide range of fields is an insatiable hunger which can never be completely fed. Over recent years these advancements in technology, medical research and a range of other fields, created a society which is dependent on improvements and progress in research.

 More so it is also a society living in expectation of continues progress, newer research, medical breakthroughs and more complex yet vastly smaller devices to provide for the luxuries which became synonymous with the age we live in. It is this need which pushes for better research possibilities, equipment and accessories and driving the market of atomic force microscopy forward. The AFM market is one with a value of USD 441 million in 2019 and according to projections, it will reach a value of USD 586 million by 2024. This indicates an exponential growth of 5.8%.

Park Systems is a leading role-player in this growing industry. It is a brand which is familiar for their world-class service and premium quality products and as the company has a global presence with offices in several countries, they cater for the needs of clients from a wide range of backgrounds. The team at the leading provider states that the most vital factor to their success is staying at the edge of developments in their field. The second most important is to be familiar with which industries are the biggest driving forces behind this growth and to maintain excellent relationships with the major role-players in these industries.

So which industries are the continuous and forceful drivers pushing the AFM market into the steep upward growth curve? To find the answer to this question you simply must look at who will benefit from the development of nanotechnology. It is often the case that governments are highly invested in nano research. 

Thus, a lot of money comes from government funds to improve the development and promotion of nanotechnology on a global scale. Another industry which is much reliant on the AFM market is the electronics industry. While the public relies on the electronics industry to continuously deliver on demands for more advanced solutions in everyday electronic devices, the specific market of consumers only maintains a small market share in the industry as the specific industry also caters for far more complex solutions which are not available in the marketplace.

The growth in the AFM market over recent years is a direct result of its capability to explore object beyond nanoscales. Coupled with this capability is the versatility it can cater for when it comes to the needs of various kinds of industries and the dominance it enjoys in the field of nano research. Currently, AFM is still the most successful way of obtaining three-dimensional topography. Thus, making it the preferred solution to researchers and scientist alike.

Another important feature of the projected growth curve up to 2024 is the large market share which forecasters project for industrial-grade AFM accounts. Industrial accounts are showing exponentially higher demands as the need to explore the surfaces of microscopic structures and to find defects in nanomaterials became in much higher demand.

Yet, of all these markets invested in the development of AFM, the largest contributor remains material development. AFM plays a vital role in the development of new kinds of materials by providing researchers with the ability to examine the nanostructures of materials such as polymers, films and fibres to be able to create new metals and alloys, biomaterials and ceramics. According to the team at Park Systems, the country with the highest interest in the AFM market is North America followed by European partners. The industry which is the largest role player is materials sciences, only followed then by life sciences with electronics and semiconductors third on the list.

About Us: Our commitment to you is to find the solutions to challenges holding back the development and research in a range of fields. It is why we spend endless hours to ensure quality and service and above all, make sure we can guarantee precision and accuracy in all our prestige options. As a global role-player in the industry with offices worldwide, you can be sure to rely on our support and outstanding customer service. Park Systems is a leader in the field of microscopic exploration, we are at the edge of advances and ensures you can reap the benefits of the most revolutionary developments. Visit our site at https://parksystems.com/ and explore our wide range of technology.

Park Systems Can Help You Find Bespoke Solutions to Answer to Your Unique Needs

As a leader in its field making a global impact through its wide network of international offices, Park Systems offers solutions beyond the expectations of their clients. The team of experts brings a range of easy customisable AFMs which can deliver according to your unique needs and bring the solutions you desire. One part of the device where they can make several modifications to find a design which best answer to your needs is when it comes to the head holding the AFM probe. Park Systems offers a range of variations on probe heads and while these bring the much-needed flexibility to create bespoke solutions, they all feature the following beneficial attributes.

The head of your AFM is responsible to hold the highly specialised probe in place to deliver absolute accuracy and precision during the scanning process. These heads should be able to react quickly to changes in its Z scanner movements and clients should be able to upgrade these heads with minimal effort to adapt to various options and modes.

One of the benefits on their list of solutions is the independent scanner. With the specific scanner, the head holding the probe is on the Z scanner functioning independently from the XY scanner. As the Z scanner moves completely independently from the XY scanner it enables the Park AFM to react much quicker to changes the height at which the device is scanning. The specific solution also eliminates the possibility of XY-Z crosstalk which often occurs when clients rely on XYZ tube scanners.

Park Systems can also assist to adjust the resonant frequency. The solution the team offers with their dedicated flexure-guided scanner is a much faster scanning rate than what tube-based scanners can ever deliver. This increased scanning speed plays a vital role in the resonant frequency of the Z scanner which then delivers better feedback performance of the AFM topography measurement.

The AFM head which Park System supplies to their clients has a build-in revolutionary cantilever deflection detection system. The highly advanced cantilever system provides for much more accurate topographic spectroscopic measurements. The head monitors the accuracy of the interaction between the probe and the surface with a light beam sourced by either a laser of a light-emitting diode. Lasers are however prone to the influence from the interference of artefacts and therefore the much more preferred option for a light source is a super-luminescent diode. These provide for far greater accuracy in F-d spectroscopic and topographic measurements.

Clients of the leading provider in the industry have a choice of more than eight different kinds of heads when they need to find the perfect solution to hold the atomic force microscope probe needed for accuracy in their work and precision in the results they want to obtain.

Some of these heads include the Standard NX AFM Head. The specific head has a Z scan range of 15 µm. It has multiply-stacked piezoelectric stacks which drive the flexure-guided structure. Other features of the specific probe head include a low coherent SLD which is available at 830 nm for the cantilever deflection detection. One of the concerns of most clients, in general, is the amount of effort it would take to mount or remove these probes. It can in some cases be a highly time-consuming task. Yet, this is not the case when you opt for the specific head from Park Systems. The head comes with a slide-to-connect head mount which ensures that you can enjoy easy and quick removal and mounting of your device.

This is merely one of the many outstanding solutions the reputable brand offers, a way how they make it possible for their clients to have solutions which perfectly suit their needs.

About Us: Our commitment to you is to find the solutions to challenges holding back the development and research in a range of fields. It is why we spend endless hours to ensure quality and service and above all, make sure we can guarantee precision and accuracy in all our prestige options. As a global role-player in the industry with offices worldwide, you can be sure to rely on our support and outstanding customer service. Park Systems is a leader in the field of microscopic exploration, we are at the edge of advances and ensures you can reap the benefits of the most revolutionary developments. Visit our site at https://parksystems.com/ and explore our wide range of technology.

AFM Processing – An Overview of the Advantages and Disadvantages It Holds

To many researchers and scientists, the availability of an atomic force microscope and the nearly miraculous way it processed images were the best thing that ever happened in their careers. It provided them with the chance to break through barriers which used to be impossible and find solutions, make advances and take their research forward. Yet, according to the team at Park Systems, a global leader in the field of atomic force microscopy, even this highly advanced device has its limitations. They shared an overview of what the many advantages of the device are and the slight shadow of limitations following it like a trail.

One of the features of AFM which set it apart from its predecessor the SEM was the fact that now life sciences could also reap the benefits of nanotechnology as the materials which you can observe did not have to be conductive or semi-conductive anymore and researchers could explore biological tissue.

The AFM provides a three-dimensional view of the surface of the profile you want to explore and the process does not require any kind of advanced treatments. With the SEM a surface would need special treatments with carbon or metal coating causing irreversible damage to your object. Now it was no longer the case.

The AFM could break free from the very expensive vacuum environment which was a necessary feature when you work with SEM. As scanning electron microscopes only function accurately within a vacuum environment, it had several limitations often set by limited budgets. The AFM broke through all these barriers as it works perfectly well and provided high accuracy and precision even in ambient air and liquid settings. The result was that now researchers could study living objects. Lastly, AFM image processing is possible at far higher resolutions than with SEM, bringing greater visibility and accurate insights into the field of study.

While there are many breakthroughs in several fields of study that took place thanks to the wonderful contributions of AFM image processing, even this highly advanced device still has some limitations. One of the limitations is that the AFM has a relatively slow scanning speed. Every scan can take up to several minutes, this is much slower than the rate at which SEM image processing takes place. It is all fine to wait slightly longer for the scanning process but the growing concern during the longer processing time is the increasing risk of thermal drift in the image. The result of this is that AFM becomes a less accurate tool to measure the distances present between various topographical features.

Another concern is the restrictions AFM has towards the size of the object it can scan at any single moment. With an SEM it is possible to scan areas of several square millimetres while it also has a depth of field of several millimetres. This is not the case with the AFM. During AFM image processing, the area which it can scan is small and no bigger than 10-20 micrometres while the maximum area it can scan is no larger than 150x150 micrometres. One technique which scientists use to overcome this concern is to rely on parallel probes in a way which resembles the same techniques as used in millipede data storage.

Factors such as an unsuitable tip, the quality of the sample material you are scanning and even environmental factors can influence the accuracy of your ATM image processing.

Yet, it is important to remember that researchers can overcome many of these restrictions through various techniques. While the team of experts at Park Systems is always available to provide the support, you need to achieve optimal functionality from your highly advanced equipment.

About Us: Our commitment to you is to find the solutions to challenges holding back the development and research in a range of fields. It is why we spend endless hours to ensure quality and service and above all, make sure we can guarantee precision and accuracy in all our prestige options. As a global role-player in the industry with offices worldwide, you can be sure to rely on our support and outstanding customer service. Park Systems is a leader in the field of microscopic exploration, we are at the edge of advances and ensures you can reap the benefits of the most revolutionary developments. Visit our site at https://parksystems.com/ and explore our wide range of technology.

One Advanced Piece of Technology – A Multitude of Uses

Since the first electron tunnelling microscope saw the light of day back in 1981 in the laboratory of Gerd Binning and Heinrich Rohrer at the premises of IBM in Zürich, the number of industries which started reaping benefits of the advantages the innovative device held expanded quite a bit. As the advanced microscope scans the surface of a range of conductive or semi-conductive materials with its sharp conducting tip, it measures the distance between the surface and the tip at various levels. 

Through the use of revolutionary technology, the data captured from the scanning probe is converted to create a 3D image giving scientists the benefits of exploring the surfaces they work with on a far smaller scale. It allows researchers to get an in-depth insight into what is happening on a nanoscale during certain applications and how materials react when they are in contact with each other. 

The technology behind the concept allows it to distinguish between particles which are a mere 0.1mm big and it has a depth resolution of 0.01mm. When this was possible for the first time, it has been one of the most impressive breakthroughs in the world of science for several years.

Today, labs across the globe have even more advanced technology available but the electron tunnelling microscope has been able to make an impressive impact on a range of fields as a vital partner in the research and development needed to step forward with advances making our lives much easier. The microscope provides a three-dimensional image of the surface it scans and can therefore identify various surface defects, the roughness of the surface and the character as well as the arrangement of the molecules. This is a helpful aid in many industries and the team at Park Systems, a leading provider in its field, is keen on sharing some of the fields in which their equipment makes a difference.

The age we are living in relies strongly on the areas of electricals and electronics. It is also two fields where advances and developments over recent years have made a huge impact on the way the world is operating. Many of these advances became possible by the valuable contribution of electronic tunnelling microscopes. The advanced technology allowed the industry to go much smaller without losing any speed or effectivity and is one of the reasons why portable electronic devices such as smartphones and tablets are getting smaller, faster and far more intelligent.

As these microscopes can provide such a microscopic view of material surfaces, it contributed to the development of new materials featuring several innovative characteristics. These materials play a vital role in the fields of transportation and energy creation. With the aid of the Binning and Rohrer’s device, the scientists and researchers can identify various characterizing features of materials. These are attributes such as the magnetic, mechanical and electrical properties and how it can be functional in areas of manufacturing such as aviation, the automobile industry and even the generation of electricity.

As you can study surfaces and the defects in material, the device also allows researchers and scientist to explore friction in far greater depth. It allows them to see on a nano-level what is happening with the material when it meets each other. These observations play a vital role in the development of conductors and microelectronics.

It is often the case that we go about in our everyday lives, enjoying everyday comforts and living life with all its advances and outstanding developments. While we are so blasé regarding all the research and development that goes into our life luxuries, it is a good reminder that there has been some outstanding work done by heroes such as Benning and Rohrer. Work which made it possible for industries to create the comforts we are used to.

About Us: Our commitment to you is to find the solutions to challenges holding back the development and research in a range of fields. It is why we spend endless hours to ensure quality and service and above all, make sure we can guarantee precision and accuracy in all our prestige options. As a global role-player in the industry with offices worldwide, you can be sure to rely on our support and outstanding customer service. Park Systems is a leader in the field of microscopic exploration, we are at the edge of advances and ensures you can reap the benefits of the most revolutionary developments. Visit our site at https://parksystems.com/ and explore our wide range of technology.

Introduction of Recent SPM Hybrid Technology Development

The 2nd NSSC 2020 will focus on electrical studies of advanced electronic devices (e.g. memristors, field effect transistors, sensors) by Scanning Probe Microscopy (SPM),including Conductive Atomic Force Microscopy (CAFM)

To know more visit: https://parksystems.com

Aspects To Consider When You Are Ready To Invest In An Atomic Force Microscope

The advanced technology behind the development of an atomic force microscope opens a world of opportunity to the wider world of science, research and development globally. It delivers a range of benefits exceeding the widely applauded predecessor, namely the scanning probe microscope. Even though the latter was a huge breakthrough when the invention of Dr Binning and Dr Rohrer, scientists at the IBM Research Centre in Zurich, Switzerland, initially saw the light of day, it had had one major limitation. The device was only capable to explore the surface of specimens on a nano-level when it was of conductive or semi-conductive material. Thus, no biomaterial could aid from the development. Finally, researchers could overcome this limitation when the atomic force microscope entered the market, enabling scientist to explore a full range of surfaces from polymers and ceramics to completing vital research in the medical field.

Today, the advanced technology plays a vital role in cancer research and many labs globally desire to have such high-end equipment but there are certain considerations you need to keep in mind before making such a major investment, warns the leading team at the global leader in microscopy equipment, Park Systems.

These factors will have a huge influence on the price you would have to budget for and thus it is vital to make sure you find the solution perfectly suited for your research needs.

Price influencing factors include aspects such as the capabilities you desire, the level of performance needed to fulfil your research requirements and the modes you expect the instrument to deliver on. The more complex and advanced the device would be which would suffice your needs, the more costly the purchase would be.

Other important aspects you need to keep in consideration would be which type of scanner you would require to deliver optimal imagery. You have the choice between a tip scanner or a sample scanner, both have pros and cons and it is vital to make the correct choice for your needs.

Other factors include the accessories you would need to create the perfect environment for the microscope to deliver optimal functionality. You might have to make various elaborate additions to your purchase such as environment or temperature control technology, FluidFM or even to create an environment for a variable magnetic field.

Would you need automation of the measurements of your research or even automated sample handling? These could increase the price you would have to budget for and although it can increase the price you need to pay, you also need to remember that having such an advanced device and not being able to use it optimally due to the lack of certain vital accessories is a rather pointless, albeit expensive exercise.

Do you need lateral resolution, vertical resolution and what about your sub-Angstrom roughness? Would it have to be planned?

They furthermore state that it is important to consider your field of research, the capabilities your specific work requires to deliver optimal results and what applications you would need. As this advanced equipment is mostly not limited to the use of one specific scientist, it is important to consider the needs of all parties involved at the specific location to ensure that all needs are met.

Once you have completed the inventory of what you would need to add to your purchase, what your requirements are and what you want to obtain from the investment, their team of experts can advise you on the best solution for your needs.

The trusted team also emphasises that they have offices across the globe and are always ready to assist to help you make the purchase which is a perfect fit for your needs and requirements.

About Us

Our team at Park Systems is always working to create change through advances in the field of research and technology by supplying premium quality equipment scientists need for microscopic exploration on a nano level. One of our most advanced features is our commitment to absolute accuracy and precision in all we do and the products we deliver. We aim to deliver the resources you need to have the breakthroughs you work for and to provide the support you need from any of our offices based globally. Visit our website at https://parksystems.com/ and explore the numerous possibilities we offer to help you achieve excellence.

The Atomic Force Microscope – An Overview of a Versatile Solution

In 1986, Drs Binning and Rohrer won a Nobel Prize for Physics for their highly advanced scanning tunnel microscope. It delivered a breakthrough in a wide range of scientific fields as research and development were often halted due to a lack of visibility. Once particles became smaller than the wavelengths of light, the image became blurry when you used an optical microscope. Thus, scientists could not explore the surfaces, the attributes and the behaviour of specimens on an atomic level. This limitation inhibited scientific progress and it was a great frustration in the various scientific fields. Their invention changed it all and did not only allow scientists to explore particles on a nano-level, they could also manipulate it.

Yet, the invention had a major drawback as well. It was only effective when used to explore the surfaces of conducting and semi-conducting surfaces and there was still a range of surfaces which had to be observed at a much more micro-scale for advancements to proceed. Especially the field of medical development had to find a solution which would allow the same kind of nano-level visibility of biomaterial to be able to explore viruses, bacteria, infected tissue and much more. Thus, not long after the advanced development was initially celebrated, there was once again a demand for an even more advanced and versatile solution. The answer to this demand was the invention of the atomic force microscope. The latest and newest development in scientific development allowed for a far wider range of surfaces to finally be explored and observed on a nano-level. Now researchers could observe surfaces such as ceramics, polymers, glass, composites and biological samples on an atomic level.

So, how does the advanced solution work and what made it different from its predecessor? The trusted team of experts at the leading provider of this kind of technology with a global footprint of success and efficiency, Park Systems, helps to understand the different kinds of technology. To explain the difference, we need to have clarity on how a scanning tunnelling microscope operates. Thus, in short, the latter relies on a microscopic probe which is raster-scanned over the surface of an atomic size specimen. The specimen needs to be conductive or semi-conductive for the probe to collect the data through a feedback loop to create an image of the surface it is scanning. They track the movement of the probe with laser technology and capture it through advanced systems. Such a system also relies on advanced computer software to add colour to the captured image on your screen to add additional clarity and to provide the researcher with a clear image of the subject.

The atomic force microscope works on much the same principles but in this case, there is no need for the surface to be either conductive or semi-conductive for the system relies on a quantum mechanical effect caused by tunnelling. Through the process, the atomic forces interact with the tip of the probe and enable it to map out the surface and deliver a clear image.

The advanced technology enables a much wider range of scientific research fields to be able to move forward in their development. One field which greatly benefits from the invention is research and development in the medical field. Especially cancer research is currently taking great steps forward in learning more about the differences in the morphology of white blood cells in patients with leukaemia when they compare it to the cells of healthy subjects.

Another medical benefit of this kind of technology is that it enables medical researchers to be able to scan tumour tissue and the tissue surrounding the cancerous body to explore the impact the disease has on the cell structure and how it responds to the medication.

Within a short time frame, the advanced solution became a vital piece of equipment of most professional labs globally.

About Us: Our team at Park Systems is always working to create change through advances in the field of research and technology by supplying premium quality equipment scientists need for microscopic exploration on a nano level. One of our most advanced features is our commitment to absolute accuracy and precision in all we do and the products we deliver. Our aim is to deliver the resources you need to have the breakthroughs you work for and to provide the support you need from any of our offices based globally. Visit our website at https://parksystems.com/ and explore the numerous possibilities we offer to help you achieve excellence.

Practical Applications Of Electron Microscope Technology

In 1981, the world of science and research were able to break through barriers previously impossible to surpass when Dr Gerd Binnig and Dr Heinrich Rohrer, two scientific experts at the IBM Research Centre in Zurich invented the electron microscope. Not only did their invention made them winners of the Nobel Prize in Physics in 1986 but it also enabled scientist to explore surfaces on a nano level, to observe atoms and make various scientific revelations. The electron tunnelling microscope enabled scientist to move forward in their fields, progress previously inhibited by limited visibility.

Today, three decades later, the range of end-users who rely upon this advanced technology is far more inclusive than what Drs Binnig and Rohrer could ever have imagined.

It plays an important role during machine-building processes. Even though any kind of mechanical build might appear to be rather robust on the first impression, there are various kinds of applications, observing the surface of materials as well as many others where these engineers rely upon the ability to observe on a nano level to be able to be successful in their industry, to be able to deliver advancements and to continuously strive to make outstanding advances.

Developers of computers and a wide range of other different kinds of technology depend heavily on this kind of nano-level observation. It enables technological development and gives a clear image of various elements required to drive the industry forward. Examples of such elements would include the surface of conductors and the atomic resolution of these metallic surfaces.

Aerospace development is another field which took giant strides in moving forward and can now deliver on expectations which were unthinkable only a few years ago. The advanced equipment is necessary to explore the features of various kinds of conductive and semi-conductive material used in these kinds of industries.

The advanced instrument can perform well under various kinds of conditions. Its versatility allows it to be optimally functional in air, vacuum, water as well as several kinds of gasses and liquids. It is however not the only versatility scientists could enjoy from the advanced solution as it also showed the tremendous capability to perform to perfection with outstanding precision in a wide temperature range. The range is covering temperatures low as zero Kelvin to several hundreds of degrees Celsius.

While advanced technology delivers a range of outstanding features, it also has a few disadvantages. Some of these are not limiting the functionality nor the versatility of the microscope at all, the team at Park Systems, a leading provider of this kind of advanced solutions with a global presence of excellence, pinpoints. Yet they do also state that the device has one major limitation as it can only function and deliver imagery of conductive or semi-conductive material. A feature which excludes biomaterial and medical research from reaping the benefits of the advanced technology which the world was applauding far and wide.  

While the medical sciences were left out of reaping the benefits, many other fields could enjoy the contributions of the instrument and simply had to overcome certain challenges. One of the challenges of working with an electron tunnelling microscope is the fact that it is a highly advanced device and requires a very specific technique which is only developed over time.

Accuracy also depends on having a clean and stable surface to work on to allow for vibration control of the sharp tip of the device. And lastly, the equipment is fragile and should always be handled with the utmost care. Especially because the price of such advanced technology can be somewhat steep for any budget to simply replace or repair.

About Us

Our team at Park Systems is always working to create change through advances in the field of research and technology by supplying premium quality equipment scientists need for microscopic exploration on a nano level. One of our most advanced features is our commitment to absolute accuracy and precision in all we do and the products we deliver. We aim to deliver the resources you need to have the breakthroughs you work for and to provide the support you need from any of our offices based globally. Visit our website at https://parksystems.com/ and explore the numerous possibilities we offer to help you achieve excellence.

A Broad Overview Of Scanning Probe Microscopy

The term scanning probe microscopy refers to the group of techniques scientist relies upon to accurately study the surfaces of nanoscale objects. It also aids in the process to manipulate the atoms into certain patterns. Park Systems is a globally recognised brand offering these kinds of advanced technology and their trusted team has given an overview of what a scanning probe microscope is and some history regarding its development.

The process relies on a microscopic probe which scans the surface of the specific specimen and from the data gathered through the advanced technology used in the probe, scientists can gather an image to reflect the surface of the specimen under the microscope. The microscopic probe is attached at the end of a cantilever and it works through movement over the top of the surface and once the probe comes near to the surface it is deflected by a force.

The success of the instrument relies on laser technology to reflect from the probe onto photo bodies which capture the movement of the probe and delivers an accurate image of the surface which the probe scanned. These forces deflecting the probe can vary in strengths and manner as different kinds of material has different forces to it. These forces are also from electrostatic, magnetic, mechanical or chemical bonds. While the images captured this way, do not have any colour to it and is represented in various levels of light, the advanced software used to capture these images can add colour to improve the clarity of the images, making various kinds of scientific research possible which used to be off-limits.

This kind of technique differs completely from that of optical microscopes as here scientist observe the object through the assistance of the image the probe created and not by directly looking at it as with an optical microscope. The scanning probe microscope delivers a very accurate image and can therefore make studying surfaces in nanotechnology much easier. These microscopes also have a very high resolution as they are often created with an accuracy of up to one nanometre.

During the course of history, the first microscopes which were ever developed were optical microscopes. Although scientists considered this to be an outstanding advancement in technology, it was not long before they realised this kind of microscope has only a limited ability to allow them to explore the specimens which were smaller than one wavelength of light. During the observation of such small items, the image often appeared to be blurry, limiting their capabilities.

Next in the development phase of microscopic advances were electron microscopes. It was the year 1921 and once again scientists revelled in the new possibilities the design held in the world of science. It offered a far greater ability to explore microscopic images and delivered much clearer images. Yet, there were still limitations to even this highly advanced device.

Much later in the twentieth century, Dr Gerd Binning and Dr Heinrich Rohrer delivered yet another solution which enabled scientists to explore the world of nanotechnology and atomic surfaces with far greater clarity. It was 1981 when they invented the scanning tunnelling microscope. This invention was a major breakthrough in science. For the first time, scientists could explore the surface of atomic level samples.

Scientists could finally study the structure and features of different atoms. As important is the fact that they were now able to manipulate these small structures and form them into new structures.

The specific kind of technology is fulfilling a vital role in various fields of research and development. Some of the end-user applications of the device include various military sectors, aerospace development and the immense amount of research going into such an endeavour as well as the automotive industry.

About Us

Our team at Park Systems is always working to create change through advances in the field of research and technology by supplying premium quality equipment scientists need for microscopic exploration on a nano level. One of our most advanced features is our commitment to absolute accuracy and precision in all we do and the products we deliver. We aim to deliver the resources you need to have the breakthroughs you work for and to provide the support you need from any of our offices based globally. Visit our website at https://parksystems.com/ and explore the numerous possibilities we offer to help you achieve excellence.