The nanoOCM is a compact, cutting-edge Optical Channel Monitor (OCM) instrument. It is designed to be the smallest form factor available, implying the use of advanced miniaturization techniques like integrated photonics or nanophotonics. Function: It utilizes a narrow-band, fast-tuning reconfigurable filter to scan the C-band and provide a high-resolution spectral view of optical signals. Purpose: This functionality is crucial for diagnosing issues, troubleshooting problems, and optimizing performance in complex optical networks. Technology: The device's extreme miniaturization and function in the C-band (a common telecommunications band) positions it as a product of integrated photonics—using nanoscale components to manage and analyze light signals.

The VT-iSIM (Instantaneous Structured Illumination Microscopy) is the world's first truly high-speed super-resolution live-cell imaging system. It is an advanced microscopy module designed to be integrated with commercial microscopes (Nikon, Olympus, Zeiss, Leica) to significantly enhance their performance. - Function: It uses a patented multi-point scanning architecture (Ingwaz scanning architecture) combined with a spinning disk to generate super-resolution images rapidly. - Nanotech Relevance: It achieves a high spatial resolution of $100\text{ nm}$ laterally and $300\text{ nm}$ axially, which is well below the diffraction limit and essential for observing nanoscale structures and dynamic events within live biological cells (live-cell imaging). - Key Features: It offers high temporal resolution (up to $200\text{ fps}$), exceptional depth penetration ($>10\text{x}$ deeper than traditional SIM), high signal-to-noise ratio, and low phototoxicity, making it ideal for studying dynamic biological processes at the nanoscale.

Being the smallest YbF₃ nanoparticles on the market, filyxio® brings radiopacity to dental materials while maximizing depth of cure and aesthetics. Available in sizes of 20 nm (all applications) or 40 nm (non dental applications). Provided in a broad range of fluid dispersions exhibiting the highest solid loading on the market. Main benefits are the following: - Smallest ytterbium fluoride nanoparticles on the market, 20 nm or 40 nm - Compatibility with all dental monomers - High translucency of dental composites - High depth of cure - Low viscosity at high particle loading - Improved flexural strength

Our smallest nanozirconia grade has a particle size as small as 5 nm. It brings strong benefits to high-end applications where small particle size is key, including high refractive index modulation of transparent materials. 5 nm ZrO₂ nanoparticles with narrow size distribution* Agglomerate-free dispersions High crystallinity Refractive index up to 2.0 Doped and undoped grades available Tunable surface chemistry to ensure compatibility with various dispersion media such as acrylates and silicones

The well-known, high-precision STOE STADI P two circle goniometer is the basis of STOE’s powder diffraction building block system (read more about it here). Vertically or horizontally mounted, the STADI P can be built in Transmission/Debye-Scherrer or Bragg-Brentano geometry. Moreover, two STADI P goniometers, either in the same or different configurations, can be mounted in the same cabinet resulting in two completely independent instruments. However, the two goniometers can also share one source. - Various single-photon-counting X-ray detectors - Pure Kα1 radiation using Co, Cu, Mo and Ag sources - The ultimate platform for laboratory PDF calculations using Ag Kα1 data - Transmission/Debye-Scherrer or Bragg-Brentano mode - Ideally suited for the analysis of air/moisture-sensitive and microsamples - A range of high- and low-temperature attachments available

The miniGaLF is an entry-level GaLF model designed for companies, universities, research institutes, and individuals who want to learn about ultrafine bubble technology. The miniGaLF offers numerous possibilities for creating your ultrafine bubble application, as it is easily fitted and retrofitted into existing machines and processes. In the most straightforward setup, just connect the miniGaLF to your water tap and add a gas source, either from a compressor or a gas cylinder, and you are ready to go. In the more advanced setup, you can add a recirculation system to achieve higher concentrations of ultrafine bubble water, which we refer to as Plus as an option. The "-Plus" version has a check valve and a pump. Read the blog post about the miniGaLF -Plus version for more information on how to integrate the unit with a pump. Easy to install and use The nanobubble unit is the most popular model. The miniGaLF comes with a power adapter from 115 Volts to 230 Volts, so it always matches the local power in your office or home. When connecting the miniGaLF to a faucet, ensure the water supply is at least 7.5 liters/minute. Test this by running the faucet for 1 minute, collecting the water in a bucket, and measuring the volume.

The Vista 300 is a highly advanced nano-chemical metrology instrument designed for research & development and failure analysis in nanofabrication. It is based on Photo-induced Force Microscopy (PiFM) and PiF-IR spectroscopy. This instrument combines Atomic Force Microscopy (AFM) functionality with chemical identification capabilities at the nanoscale. Key features and functionalities include: - Imaging Modes: Non-contact AFM, PiFM, KPFM (Kelvin Probe Force Microscopy), cAFM, nano DMA (Dynamic Mechanical Analysis), and Force vs. Distance (FvD) mapping. - Spectroscopy Modes: PiF-IR (Photo-induced Force Infrared Spectroscopy) and FvD. - Automation: Features like AutoPiFM and automatic alignment simplify data generation and operation. - Sample Size: It supports a large sample stage travel of 300 mm x 300 mm.

PHI’s patented Parallel Imaging MS/MS mass spectrometer provides superior sensitivity, low spectral background, unique ability to image highly topographic surfaces, high mass accuracy and mass resolution, and unambiguous peak identification with parallel tandem MS imaging capability. The PHI nanoTOF 3 can be configured with a wide variety of options to optimize performance for organic materials, inorganic materials, or both, depending on customer requirements. NEW Pulsed Dual-Beam Charge Neutralization For Truly Turn-Key Insulator Analysis - Self-regulating charge neutralization by low energy electrons and low energy inert gas ions - Artifact-free chemical imaging by neutralization of the position-dependent surface charges NEW Bi Cluster Emitter With Smaller Beam Diameter For Improved High-Throughput HR2 Imaging - The most utilitarian analysis mode with 8 kHz) TOF-SIMS (MS1) and tandem MS (MS2) imaging - High resolution ( 1.5 keV) collision-induced dissociation (keV-CID) for identification Solutions For In Situ Characterization Of Advanced Materials - All operation modes available for automated and unattended analysis - Cryo- and high-temperature analysis via the Hot/Cold and High-Temperature module options; full 5-axis sample motion is maintained during temperature-controlled analysis - Advanced 3D imaging with use of optional Ar, O2, Cs, C60, Ar cluster, and Ga-FIB ion beams - Solid-state electrochemistry (biasing, polarization) experiments with the Static Voltage & Power Cycling option - Inert Sample Transfer Vessel and Transfer Vessel Adapter (25 mm AES/XPS puck) options

The Vertex Series from Lighthouse Worldwide Solutions redefines performance in liquid particle counting. Available in two models — the Vertex 50 and Vertex 100 — this line delivers unparalleled detection sensitivity and compact precision for ultrapure water applications. The Vertex 50 is the smallest and lightest 50 nm liquid particle counter on the market, featuring the industry’s lowest zero count levels and integrated manual flow control. The Vertex 100, designed for 100 nm sensitivity, maintains the same compact footprint while setting a new benchmark for ultraclean monitoring at larger channel sizes. Gamma Immunity Lighthouse’s advanced photodetector technology has reduced optical noise and minimized gamma-ray interference twentyfold, ensuring the detection of only true particle counts in your ultrapure water system. Count subtraction is not required because Lighthouse instruments achieve the lowest false count rates in the industry. Both the Vertex 50 and Vertex 100 report counts in real time—without delay—providing reliable, immediate results. Early Detection and Fast Recovery The Vertex 50 and Vertex 100 are designed for rapid response. After a contamination event, each system returns to baseline levels within approximately 120 seconds, supporting early detection and quick recovery in critical water systems. Vertex50 Key Features: Channel sizes: 50nm, 100nm, 150nm, 200nm Four channels of simultaneous count data 100 mL per minute flow rate Built-in 3.5” color touch screen display 316L stainless steel construction Ethernet, RS485 Modbus Serial, 4-20mA NEMA style enclosure Integrated manual flow control Interfaces with existing building automation and facility management systems

Holotomography merges holography and tomography to solve the challenge of recovering light phase shifts to generate image contrast in Quantitative Phase Imaging, revealing intricate three-dimensional details within samples that would otherwise remain hidden with traditional techniques. Just as a CT scan uses X-ray absorptivity as the imaging contrast to see inside a patient’s organs without invasive procedures, HT uses the refractive index (RI), an intrinsic optical parameter describing the speed of light passing through a specific material, to visualize living cells and tissues. Since variations in the biomolecular concentration directly impact the overall RI of the cellular biomaterials, the reconstruction of RI tomogram by Holotomography can retrieve important biophysical parameters such as cell volume, surface area, or protein concentration for further analysis. In general, all Holotomography systems consist of three essential components: (1) illumination optics to capture structural information of the specimen in light wave; (2) imaging optics to encode information in light onto a 2D intensity image; and (3) a reconstruction algorithm to decode and synthesize the raw data into a 3D tomogram. Holotomography’s advantages lie in its capability to provide non-invasive, label-free 3D images of live cells, allowing real-time studies while the measurement of RI tomogram also allows quantitative analysis. Its data acquisition speed surpasses traditional methods, making it invaluable for quick results in medical diagnostics and drug research. Holotomography’s applications span from cellular components like nuclei and mitochondria to studying organoids, tissues, and even whole organisms, enabling breakthroughs in cellular biology understanding. Its applications continue to expand as new advances are made in tomographic imaging.

Holographix designs and produces cost-effective, high quality, custom engineered optical diffusers to customer specifications. We design and manufacture a wide range of solutions, from basic patterns to more complex random and pseudo-random profiles. Holographix’ optical diffusers are produced to submicron tolerances in a variety of shapes and packing configurations. Holographix differentiates itself from the competition by offering: Cost-Effective Solutions: Holographix’ replication process is economically scalable for volume manufacturing. Production quantities ranging from 100 individual components to 10,000 wafers per year can be accommodated. Optical Design: Holographix’ optical design team fully utilizes the unique abilities of our proprietary replication materials to achieve the highest performance possible for our customers. Exceptional Performance: Up to 99% transmission throughput with AR coating. Low stray light. Manufacturing Excellence: High quality, custom optical diffusers with repeatable performance! Holographix is ISO 9001:2015 certified, and proudly manufactures all optical components and assemblies in the USA.

Holographix specializes in the production of high fidelity surface relief structures using our state-of-the-art replication technology. Our proprietary cold forming replication process can reproduce virtually any surface structure onto a variety of substrate shapes, sizes and materials. From lenslet arrays and sub-micron motheye structures to high-aspect-ratio diffraction gratings, we can mold the surface structure with such fidelity that the performance of the component in many cases equals the master it was derived from. Holographix replicates structures with pitches and depths ranging from less than 10 nm to more than 100 microns. Applications Include: Patterned quartz masks and silicon wafers Microwells for microfluidic applications Optical diffusers Diffractive and refractive micro-optics Waveguide structures Motheye anti-reflection structures Benefits Include: Cost effective approach to both low or high volume production without compromising quality Provides security for your initial investment through generation of replicated stamper and template tools

Gold Nanohelices - Chirality Tomography Markers The Gold Nanohelices (L,R) are chiral nanoscale markers especially suited for 3D Tomography / Electron Microscopy (EM) / CryoEM. Our chiral markers show pure chirality (L or R), which can easily be detected with EM due to the high contrast and the precise arrangement of the gold nanoparticles. The Gold Nanohelices (L,R) are fabricated with the DNA origami technique where gold nanoparticles (10nm) are arranged into nanoscale helices (helical pitch 57 nm; length 110 nm; diameter 34 nm). In Solution: The Nanohelices are delivered in buffer (keep at 4°C): 1x TAE, 11mM MgCl2. The sample size is ~30µl which is enough for the preparation of more than 10 TEM grids. Also available as mounted version: The samples are shipped ready to use on a TEM grid.

The Evactron E50 Plasma De-contaminator was designed to remove hydrocarbon contamination from vacuum chambers such as SEMs, FIBs, TEMs, XPS and semiconductor equipment including CD-SEMs, ALD and EUVL. Its compact design fits all models of FIB/SEM chambers and loadlocks to provide in-situ sample cleaning. Evactron plasma cleaning shortens pumpdown time, maintains the ultimate vacuum level of your system and increases sample throughput with powerful yet thorough contamination removal. Evactron E50 System Specifications: Remote hollow cathode plasma radical source Desktop controller with pushbutton operation Android tablet with Bluetooth communication Library of tested recipes and options to change power, cycles, length of cleaning, etc. Chassis dimensions WxHxD: 17” x 3.4” x 6.7” (43 cm x 8.6 cm x 17 cm) RF Power: 35 – 75 Watts at 13.56 MHz RFHC 100-240 VAC 50/60 HZ input RoHS, CE, NRTL, TUV and SEMI S2 compliant

Vmicro has a long term experience of microfabrication engineering with design rules from 100 nm to 100 µm. We are able to offer advanced lithography processes using e-beam and optical techniques. Optical lithography from 1 µm to 100µm E-beam lithography from 50 nm to 1µm Fast prototyping with e-beam lithography on large areas Wide range of resists: DUV, PMMA, Az nLOF, HSQ Proximity correction for dense patterns generation with 100kV ebeam Lithography sequences combining high resolution to thick resists. Mask engineering for deep etching of small structures

Lprobes are based on a new MEMS patented technology enabling improvements as compared to silicon AFM cantilevers with tip fabricated using mainstream processes developed in the 90’s. Vmicro In-plane technology enables full batch fabrication of tips with high lengths, low masses and high aspect ratios not only close to apex. Both cantilever and tip are made of highly doped monocrystalline silicon. Lprobes are compatible with most SPMs. Our chip is designed with vertical sidewalls that enable safer handling with tweezers.

Lprobes are based on a new MEMS patented technology enabling improvements as compared to silicon AFM cantilevers with tip fabricated using mainstream processes developed in the 90’s. Vmicro In-plane technology enables full batch fabrication of tips with high lengths, low masses and high aspect ratios not only close to apex. Both cantilever and tip are made of highly doped monocrystalline silicon. Lprobes are compatible with most SPMs. Our chip is designed with vertical sidewalls that enable safer handling with tweezers.

Compact Electrospinning Unit is a high-tech system that combines the rotary movement of the collector with the x-y movement of the spinneret to create a uniform substrate of both random or aligned nanofibers, by simply changing the configuration. Obtain fibers with uniform thickness With this unit, safe and ready to use, you can electrospin any type of organic, synthetic, or ceramic polymer. Nanofibers are characterized by a high reproducibility over time and by a uniform thickness along the axis of the collector. Thanks to the detachable mandrels, collectors of different sizes can be mounted. Besides giving you the possibility to work with collectors of different sizes, that gives you the possibility to obtain tubular structures, avoiding the membrane cutting to peel off the fibers. It is also possible to install a flat collector easily, by using the provided screws. The internal chamber ican reach a temperature of +50°C Compared to a classic rotary collector, this system rotates and the needle moves simultaneously to guarantee a uniform deposition of fibers along the collector.

Traditional spectrometers use a slit to allow light to pass into the instrument and focus on the target substance. Our spectrometers are different: we use optical fibres of 1 mm – 3 mm, although a 5 mm is possible. Using a fibre rather than a slit aids transmission; where light is usually lost, it is retained and, therefore, can be focused on the target. More light on the target delivers a stronger signal, particularly helpful when measuring substances with weak Raman signals. ISI’s standard HES spectrometer offers a 100-fold increase in throughput over current conventional systems. This increased throughput can lead to a superior signal-to-noise ratio (SNR) for a given observation over a Czerny Turner instrument. The HES spectrometer contains no moving parts and yet offers the advantages of a Michelson Interferometer with the spectral properties of a traditional diffraction grating-based device, such as a Czerny Turner spectrometer.

Meet the Precision Multiferroic II Ferroelectric Tester. It has a unique frequency rating of 270KHz at +/-100V built-in to the system. The Multiferroic II tester makes testing of thin films and bulk ceramics a fast and simple process. It captures 32,000 points at 2 MHz to achieve exquisite frequency resolution in DLTS or PAINT measurements. The Precision Multiferroic II is offered with a variety of internal amplifiers. The Multiferroic II is offered with a ±100V, 200V and 500V built-in drive volt option. It can be expanded to 10kV with the addition of a high voltage interface and an amplifier. The Precision Multiferroic II executes hysteresis, pulse, leakage, IV, and CV (and many other tasks) measurements without changing sample connections. With the addition of extra fixtures, the Precision Multiferroic II can measure pyroelectric properties, magneto-electric properties, transistor characteristics, cryogenic properties, bulk ceramic and/or thin film piezoelectric properties.