Cathodoluminescence solutions that reveal fundamental properties of matter
Integrated correlative microscopy solutions that combine the power of fluorescence and electron microscopy
Our application specialist Marit Smeets gives an overview of all the steps that are involved in the current sample preparation method, specifically focusing on the role of cryo fluorescence light microscopy (cryo-FLM). We also discuss integrated cryo-FLM and how it can make the workflow easier and more efficient.
Together with our applications specialist Job Fermie you will dive deep into current challenges of electron microscopy and what would be possible without major limitations.
Our Applications Specialist Sangeetha Hari will introduce the importance of sample preparation for acquiring high quality CL data and describe different sample preparation techniques.
A comprehensive overview of the cathodoluminescence technique, latest developments and various applications.
Learn how integrated correlative light and electron microscopy can be beneficial for understanding synaptic connectivity and large-scale interactions in the brain.
Learn how Super-resolution (SR) light microscopy and electron microscopy (EM) together revolutionize our understanding of biological systems, providing highly accurate correlation of fluorescent proteins with cellular structure.
Version 3.0.2, 112 MB
Read about the possibilities of cathodoluminescence imaging for studying meteorite impacts in shocked quartz grains.
Meet our customer, Prof. Cameron Davidson, who is currently working at the Department of Geology, Carleton College.
Learn about integrated correlative light and electron microscopy for studying Type 1 diabetes.
Read how best overlay accuracy in correlative microscopy can be achieved when acquiring fluorescence and electron images on the same resin-embedded section.
Read how integrated correlative light and electron microscopy (CLEM) reveals the giant virus particles by fluorescence light microscopy (LM) while simultaneously providing information on the ultrastructure with electron microscopy (EM).
Learn about the possibilities of integrated correlative light and electron microscopy for studying and understanding marine microbes.
Learn about the concept of correlative light-electron microscopy (CLEM) and how it can be used for various applications in the life sciences.
Learn about the relevance of CLEM in the life sciences, as well as some of the challenges such as overlaying images and retrieving regions of interest.
Learn about how to set up imaging conditions to obtain high quality CL intensity maps and spectra from a range of materials
Learn about the difference between coherent and incoherent CL emission, how it can be identified and what each type of the emission can be used for.
Learn about the possibilities of integrated CLEM for studying giant viruses, which are found in environmental, animal, as well as human samples.
Learn in details about the possibilities of CL imaging for measuring and analysing thin-film solar cells and various materials used in the photovoltaic industry, this is the webinar for you.
Learn about how the measurement of cathodoluminescence emission can be applied in nanoscale optics, geology, and materials science.
Learn about exploration of microstructure and chemistry in minerals using EBSD and CL techniques.
Learn about the different types of cathodoluminescence (CL) and more specifically, how angle-resolved CL is performed.
Learn more the physical background of cathodoluminescence emission in rocks, sample preparation, and the typical CL workflow.
Learn more the properties of ligh, the dynamics in materials, time-resolved imaging techniques (including lifetime imaging and g(2) imaging) and examples of how these technique can be applied to study nanostructured semiconductors.
Learn more the fundamentals of cathodoluminescence for rare-earth doped materials
Learn how cathodoluminescence can be used to retrieve optical properties of plasmonic materials with the deep-subwavelength resolution.
Learn about the principle of operation, details of CLEM, hardware, open source software-based operation and scripting, as well as sample preparation.
Read this application note to learn how cathodoluminescence is used as a prescreening tool for high-resolution secondary-ion- mass spectrometry (SIMS) to image the zonation pattern and identify regions of interest for isotope analysis of geological samples, such as zircons.
Learn more the physical background of CL emission, sample preparation, and the typical CL workflow.
Learn about the possibilities of energy-momentum cathodoluminescence for acquiring hybrid multidimensional high-resolution angle-resolved hyperspectral datasets in the fields of nanophotonics and materials science.
Read how cathodoluminescence can be used for retrieving optical properties of photonic crystals with deep-subwavelength resolution.
Learn why and how cathodoluminescence imaging can be used to directly visualize the internal modal structure of semiconductor nanoparticles.
Learn about the fastest and simplest method to obtain cathodoluminescence contrast: intensity mapping.
Learn how cathodoluminescence imaging and spectroscopy is used extensively to study GaN materials and devices.
Learn how cathodoluminescence imaging and spectroscopy is used to study perovskite materials.
Rare earth materials are a particular class of elements in the periodic table which serve a range of practical uses. Learn how cathodoluminescence can be used to study these materials.
Learn how cathodoluminescence imaging and spectroscopy is used extensively to study properties of thin-film solar cells.
Learn how cathodoluminescence (CL) imaging and spectroscopy provides a powerful method to study the optical properties of 3D perovskites structures on deep-subwavelength scales.
Read this technical note to learn how accurate and unbiased overlay is achieved in SECOM, an integrated correlative light and electron microscope.
Learn the possibilities of angle-resolved imaging mode available in Delmic CL solutions.
Learn the possibilities of hyperspectral imaging mode available in Delmic CL solutions.
Learn the possibilities of polarization-filtered cathodoluminescence imaging mode available in Delmic CL solutions.
Learn the possibilities of cathodoluminescence intensity imaging mode available in Delmic CL solutions.
Read more about the optical modules of the SPARC Spectral and Compact systems, which can be configured for various detection functionalities and wavelength ranges.
Learn about lifetime (or decay trace) mapping which can help to identify a material defect and to characterize materials to improve their performance.
Learn about the possibilities of hyperspectral CL imaging for spatially extended specimen such as zircons and other minerals.
Learn how cathodoluminescence spectroscopy can be used for micro-characterization of rocks and minerals, and how this technique can be employed to study quartz sandstone.
Read about the research on studying alluvial sapphires from Australia to learn how cathodoluminescence can help to assess crystallisation histories of the precious gemstones and underlying causes for luminescence.
Check exact specifications of the SPARC Spectral, a high-performance cathodoluminescence detector, in the product brochure.
Check exact specifications of the SPARC Compact, the cathodoluminescence detector, in the product brochure.
Check exact specifications of integrated correlative light and electron microscope SECOM in the product brochure.
Check exact specifications of super-resolution correlative microscopy system SECOM SR in the product brochure.
Check exact specifications of the integrated tabletop correlative microscopy solution Delphi in the product brochure.
Watch the video to learn the main advantages of the SPARC Spectral system.
Use the databased of Monte Carlo beam tracing simulations for incoherent CL emission for most commonly studied materials to learn how you can set up optimal imaging conditions for your experiments.
Learn about time-resolved cathodoluminescence imaging, which can be extremely valuable for a large range of applications.
Learn the possibilities of lens-scanning energy-momentum imaging mode available in Delmic CL solutions.
In this white paper, we discuss several methods to ensure an integrated imaging workflow, and present results obtained using a variety of techniques and samples.
Get all specifications of the SPARC Spectral cathodoluminescence detector to get full information about the system.
Get all specifications of the panchromatic and RGB cathodoluminescence detector to get full information about the system.
Learn more about SPARC Spectral module for time-resolved cathodoluminescence: lifetime and g(2) imaging.
Samples courtesy of Prof. Jens Jahren, University of Oslo
Sample courtesy: B.N.G. Giepmans & P. de Boer, UMCG
Sample courtesy: P. Ronchi & Y. Schwab, EMBL
Sample courtesy of J. Martinez-Hernandez.
Sample courtesy of D. Falconet.
Sample courtesy of M. Rippe.
Sample courtesy of M. Mourik, LUMC.
Sample courtesy of K. Monier.
Sample courtesy of K. Gorgy
Sample courtesy of S. Lehmann.
Sample courtesy of H. Schwarz.
Sample courtesy C.J. Peddie Francis Crick Institute
Sample courtesy of T. Kurth, Tech. Univ. Dresden.
Sample courtesy: Y. Schwab, EMBL Heidelberg.
Sample courtesy: S. Littmann, MPI Bremen.
Sample courtesy of T. Templier and R.H.R. Hahnloser, Univ. of Zurich and ETH Zurich.
Watch the video to learn about the main advantages of the SECOM system.
What is time-resolved cathodoluminescence? How can it be applied to your research? In this video, Toon Coenen gives an in-depth explanation of this imaging technique.
What is Correlative Light and Electron Microscopy? And how does it work? Why do we combine fluorescence microscopy and electron microscopy? And what are the key advantages of using this technique? Watch the video with Delmic application specialist, Sangeetha Hari.
Time-resolved cathodoluminescence imaging is now available in one solution: the LAB Cube. Delmic is presenting a unique system, which allows performing g(2) and lifetime imaging.
The youngest member of Delmic's cathodoluminescence (CL) solutions family, JOLT is an entry-level SEM-based cathodoluminescence detector, which is ideal for CL intensity mapping.
This CL webinar series will go back to the basics of cathodoluminescence imaging and cover its fundamentals as well as the new research directions in six webinar sessions.
Meet our customer, Dr. Ruggero Verre, who is a post-doctoral researcher in the Department of Applied Physics - Division of Bionanophotonics at the Chalmers University of Technology in Gothenburg in southern Sweden.
Meet our customer, Dr. Sten Littman, who is a scientist working at the department of biogeochemistry in MPI for Marine Microbiology in Bremen.
Meet our customer, Dr. Lindgren, who has worked previously as a senior engineer at Sol Voltaics, a start-up which produced solar cells out of nanowires with a new technique called Aerotaxy.
Learn more about our new integrated cryo-FLM system for FIB/SEM which helps you to make the cryo-CLEM workflow less complex.