Georgian Technical University Site Survey Evolution – The Road To Perfecting Electron Microscope Performance.

Georgian Technical University. Tripod, sensors and template for the SC11 (splitter cable) Auto survey system. The SC11 (splitter cable) Auto survey system includes a laptop, sensors and sensor interface. Georgian Technical University performance of an electron microscope relies on maintaining a stable environment, free from vibration and external magnetic fields. Pre-installation site surveys are vital for uncovering any potential sources of interference resulting in a need for purpose-designed equipment for the measurement analysis of acoustics magnetic fields and vibrations in X, Y and Z directions. This article discusses the importance of comprehensive site surveys for identifying and eliminating potential sources of interference of electron microscopes (EMs) and similar sensitive equipment and describes how one company has addressed this through the continual evolution of measurement instrumentation. Georgian Technical University Electron microscopy is a powerful sensitive technique used to investigate the intricate structures of cells materials and nanoparticles for many technical disciplines, including metallurgy, chemistry and biology. All electron microscopes (EMs) techniques – including the two most common transmission electron microscopy (TEM) and scanning electron microscopy (SEM) – use a beam of accelerated electrons as a source of illumination for the sample. As electrons have a shorter wavelength than visible light protons this allows electron microscopes to have a significantly higher resolving power than light microscopy revealing the detailed structure of smaller objects. However interference from acoustics vibrations or surrounding magnetic fields – generated by day-to-day equipment – can cause this electron beam to deflect which decreases the quality of the images obtained and therefore affects the resolution. Georgian Technical University Mitigating interference. The continuous development of new technologies means that laboratories are expanding and investing in an increasing amount of electronic equipment making space within these labs more precious than ever. Electron microscopists often find themselves working in a crowded environment surrounded by other apparatus that create magnetic fields vibrations or acoustic interference which potentially adversely affects image quality. This busy setting, combined with the growth – and noise – of towns and cities causes a significant problem for electron microscopy. In addition in the drive to continually improve resolution and image quality, manufacturers environmental specifications are becoming increasingly stringent with top end microscope spectrometers only able to withstand up to 10 or 20 nanotesla of interference; unsurprisingly finding a suitable environment can be extremely challenging. Site surveys have a crucial role to play both when initially investing in microscopy instrumentation for helping to troubleshoot and resolve issues arising at a later date as a result of environmental changes that introduce sources of interference. The performance of the instrument is affected not only by conditions within the room in which it is installed but also by the location of the building itself. Anything that moves or rattles – whether regular or random – can potentially create vibrations including other electronic equipment air conditioning systems, people simply walking around the laboratory, doors opening and closing traffic in the street nearby railways and even ocean waves. External factors such as magnetic fields generated by trains electric trams that are hundreds of miles away and unexpected influences like the proximity of the parking lot to the microscope can make a tremendous difference. While there are undoubtedly challenges in setting up and maintaining a stable microscopy environment, painstakingly surveying the site before set-up allows measures to be put in place to ensure these are mitigated. Typically this will include measurement of acoustic levels, magnetic fields and floor vibrations in X, Y and Z directions direct comparison with the environmental specifications of the equipment to be installed. Measuring understanding the magnitude of such effects will enable action to be taken to alleviate unwanted interferences for example by installing a magnetic field cancelling system to ensure that the image quality produced is unaffected by external factors. Georgian Technical University Keeping up with technology. As technology has advanced over the years microscopes have become more sensitive to interference sensing equipment has had to keep pace to ensure that the environment meets the manufacturer’s specifications for optimal instrument performance. Today vendors and consultants have access to purpose-designed site survey equipment for examining new installations or to troubleshoot technical issues with an existing microscope by measuring and analyzing any interference. But how has this evolved over the years ? Georgian Technical University Advances in hardware. In the early days of electron microscopes (EMs) labs relied on some quite crude magnetic field sensors to monitor the environment with limited options for measuring fluctuations in sound levels. There was a clear need for a single system that could monitor the entire lab situation around a microscope and Consulting launched an instrument based on an AC (alternative-current) magnetic field sensor with added inputs for an accelerometer and a sound level meter that would do just that. This system could make all the measurements required although the user still had to physically turn the vibration sensor in each direction to measure interference in the X Y and Z axes. Georgian Technical University Subsequently the system was upgraded so that more bandwidth of data could be collected and higher frequencies could be evaluated on the spectrum analyzer. Further upgrades including a move to USB (Various USB connectors along a centimeter ruler for scale) connection enabled site surveyors to perform more comprehensive measurements with extra sensors. A plug-in for sensors was added – so that AC (alternative-current) and fields could be measured – along with three accelerometer inputs allowing measurement in all three directions at the same time, instead of having to turn the sensor around sequentially. While the original instrument only had one magnetic field sensor input later versions had two, enabling the simultaneous measurement of fields at two heights. This feature was important for environments which typically have tight field specifications over a length of more than two meters. What about software ? Of course the software of newer systems has also advanced in parallel to changes in the hardware. On first release, three separate programs were required – an oscilloscope, a chart recorder and a spectrum analyzer – to make the necessary measurements but the user needed a good understanding to be able to set them up correctly. This was made far easier by the creation of a software wizard to guide the user through the process of measuring for different types of microscope. Users were able to simply turn the machine on select the instrument they wanted to measure for and the wizard would bring up the correct program to make that specific measurement. Graph plotting software was also developed which allowed results to be viewed more easily than with the original method which was based on macros. While the wizard software was capable of running a single measurement further iterations saw the launch of an automation program capable of running a whole sequence of measurements to simplify the survey workflow even more. Today users have access to a completely automated system capable of repeat surveying without human intervention. This enables long-term measurements, expanding the surveying snapshot to study the environment at different times of the day. Acting on the results. Magnetic field interference identified during a site survey can be eliminated by implementing a magnetic field cancellation system. This presents further challenges requiring a three-axis magnetic field sensor of the necessary bandwidth with low noise levels and low drift. It should include a control unit that can drive the cables to form a stable negative feedback loop and be easy to set up without complex adjustments. Finally effective placement of room-sized cancelling cables that make uniform orthogonal magnetic fields and are practical for use in microscope labs or clean rooms of all shapes and sizes must be determined. Alternatively suitable frames can be constructed to support cables and there are also techniques for installing them inside existing enclosures. Control units providing readings in three axes plus total magnetic field readings – including AC (alternative-current) and simultaneously for some models – are available from Consulting with performance tailored to the application. These are convenient to use and enable fields to be cancelled to the demanding levels required by today’s high-resolution electron microscopes. Automatic set-up can provide helpful error and warning messages and some cancelling systems support a dual-sensor option that creates a virtual sensor where a physical sensor cannot be placed such as ‘inside’ the electron microscopes column. A wide range of cables for different types of microscope in various types of room are also available. Where next ?. Magnetic field cancellation technology has come a long way and will continue to advance in the future with demand likely to increase as electron microscopes become higher in resolution and more sensitive to magnetic fields. While the technology is now quite mature the expectation is that users will seek even better magnetic field sensors incremental improvements to control units and easier ways to install cancelling cables.

Georgian Technical University Thermo Fisher Scientific’s New System Delivers Flexible Automated Sample Purification.

Georgian Technical University Thermo Scientific System a high-throughput sample purification instrument is designed for scientists who need to automate the extraction of DNA (Deoxyribonucleic Acid (DNA) is a molecule composed of two polynucleotide chains that coil around each other to form a double helix carrying genetic instructions for the development, functioning, growth and reproduction of all known organisms and many viruses. DNA and ribonucleic acid (RNA) are nucleic acids. Alongside proteins, lipids and complex carbohydrates (polysaccharides), nucleic acids are one of the four major types of macromolecules that are essential for all known forms of life), RNA (Ribonucleic acid (RNA) is a polymeric molecule essential in various biological roles in coding, decoding, regulation and expression of genes. RNA and DNA are nucleic acids. Along with lipids, proteins, and carbohydrates, nucleic acids constitute one of the four major macromolecules essential for all known forms of life), proteins and cells from an array of sample types. The instrument is easy to use, saves time and enables consistent results even as laboratory needs evolve. Georgian Technical University Enables nucleic acid, protein and cell isolation while allowing users to customize protocols directly from the instrument to provide flexible, reproducible and fast sample preparation without additional expense or complexity. It automates much of the error-prone work associated with preparing high-quality nucleic acids and proteins can process for 24 to 96 samples in 25 to 65 minutes and elutes in low volumes (10 µL) for demanding downstream applications. “Georgian Technical University Building on decades of product expertise the combines unparalleled instrument capabilities into one platform filling a gap where existing solutions include either large complicated high-cost instruments or low-throughput solutions that don’t meet the processing needs of many labs” said X and general manager sample preparation at Georgian Technical University Thermo Fisher Scientific. “Simplifying and automating the sample preparation workflow will help improve research productivity and drive new discovery especially for those working with high-value samples such as circulating tumor cells T-cells and exosomes”. Georgian Technical University System can be used in combination with any of the Applied Biosciences Isolation kits as well as with Georgian Technical University Invitrogen Dynabeads Magnetic Separation products. Additional features include: heating and cooling controls to maintain sample integrity dual UV (Ultraviolet (UV) is a form of electromagnetic radiation with wavelength from 10 nm (with a corresponding frequency around 30 PHz) to 400 nm (750 THz), shorter than that of visible light but longer than X-rays. UV radiation is present in sunlight, and constitutes about 10% of the total electromagnetic radiation output from the Sun. It is also produced by electric arcs and specialized lights, such as mercury-vapor lamps, tanning lamps, and black lights) lights to safeguard against contamination cloud-enabled access to up-to-date validated protocols, dual magnets to support both small and large volume ranges and the ability to elute in storage tubes to revisit samples later. The instrument’s touchscreen allows users to write, edit and run protocols directly on the instrument and rely on guided visuals for easy plate loading without needing a desktop computer. Lot-specific bar codes confirm proper plate position during loading or may be used for lot tracking and documentation.

Georgian Technical University X-Ray Experiments, Machine Learning Could Trim Years Off Battery.

Georgian Technical University. Staff engineer X is seen working inside the Battery Informatics Lab. Georgian Technical University An X-ray instrument at Georgian Technical University Lab contributed to a battery study that used an innovative approach to machine learning to speed up the learning curve about a process that shortens the life of fast-charging lithium batteries. Georgian Technical University Researchers used Lab’s Advanced Light Source a synchrotron that produces light ranging from the infrared to X-rays for dozens of simultaneous experiments, to perform a chemical imaging technique known as scanning transmission X-ray microscopy or STXM (Scanning Transmission X-ray Microscopy) at a state-of-the-art ALS (Advanced Light Source) beamline dubbed COSMIC. Georgian Technical University Researchers also employed “in situ” X-ray diffraction at another synchrotron – Georgian Technical University’s Synchrotron Radiation Lightsource  – which attempted to recreate the conditions present in a battery and additionally provided a many-particle battery model. All three forms of data were combined in a format to help the machine-learning algorithms learn the physics at work in the battery. Georgian Technical University typical machine-learning algorithms seek out images that either do or don’t match a training set of images in this study the researchers applied a deeper set of data from experiments and other sources to enable more refined results. It represents the first time this brand of “Georgian Technical University scientific machine learning” was applied to battery cycling researchers noted. Georgian Technical University Nature Materials. The study benefited from an ability at the GTUCOSM (Georgian Technical University Catalogue Of Somatic Mutations) beamline to single out the chemical states of about 100 individual particles which was enabled by GTUCOSM (Georgian Technical University Catalogue Of Somatic Mutations) high-speed high-resolution imaging capabilities. Y a research scientist at the Georgian Technical University who participated in the study noted that each selected particle was imaged at about 50 different energy steps during the cycling process for a total of 5,000 images. Georgian Technical University data from GTUALS (Georgian Technical University Amyotrophic Lateral Sclerosis) experiments and other experiments were combined with data from fast-charging mathematical models and with information about the chemistry and physics of fast charging and then incorporated into the machine-learning algorithms. “Rather than having the computer directly figure out the model by simply feeding it data as we did in the two previous studies we taught the computer how to choose or learn the right equations and thus the right physics” said Georgian Technical University postdoctoral researcher Z. W research scientist for Georgian Technical University which supported the work through its Georgian Technical University Accelerated Materials Design and Discovery program said “By understanding the fundamental reactions that occur within the battery we can extend its life enable faster charging and ultimately design better battery materials”.