An additional Friday publication update! Controlled etching behavior is extremely important to be able to create crystal solids with defined structures and functions. In this newest publication, in situ liquid cell transmission electron microscopy was used to oberserve the dynamic behavior during the pencil shape evolution of a single crystal ZnO nanorod in aqueous hydrochloric … Read More
Are you interested in photonic devices? Please take a look at this new research using the #FusionSelect! In this publication TiO2/In2O3 nanowires were investigated for their microstructural evolution during annealing experiments. Elemental analysis (EDS) was used to analyze the reaction mechanisms at different temperatures. Do you want to know more? Follow the link: https://lnkd.in/gsSq7MEZ … Read More
Another new publication on a Tuesday! In this new publication the researchers combined X-ray absorption spectroscopy and #LiquidEM electrochemistry. Using small-angle X-ray scattering, they were able to probe particle-particle interactions of large ensambles of nanoparticles, while doing electrochemistry simultaneously! Please take a look at their research here: https://lnkd.in/gecsg-an #microscopy #electronmicroscopy #insituTEM #catalysis #PoseidonSelect#electrochemistry #SAXS … Read More
In this newest published research the #FusionSelect was used to heat and efficiently quench antiskyrmions. Different lattice formations were observed ranging from triangular, circular or rotated-square geometry. These nice results from the University of Tokyo demonstrate a roadmap for generating and controlling antiskyrmions in a confining geometry. Read more about the paper here: https://lnkd.in/dGfYEF3e … Read More
In this new exciting paper the researchers have looked into grain boundary engineering by electron beam patterning using the #FusionSelect holder. If you want to know about how this atomic precision technique can be capable of engineering precise nanomaterials, please follow the link: https://lnkd.in/dxrWePfh #energyresearch #2Dmaterials #materialscience #electronmicroscopy#microscopy #findyourbreakthrough
Please take a look at this great new paper just published in #JACS by the group at Cornell University. They are combining 4D-STEM and Electrochemistry all with in situ #LiquidEM. In this study the authors look at the corrosion of bulk electrodes, impacting the structural degradation. Yao Yang Cornell University If you want to … Read More
MOF derivatives display superior electrical conductivity and thermal stability and have therefore drawn widespread attention. Recently, researchers from Northwest University in Xi’an have combined in situ and ex situ techniques to observe the pyrolysis process of ZIF materials. Find out about their research here: https://lnkd.in/gCWN66KF #electronmicroscopy #insitumicroscopy #microscopy#findyourbreakthrough #Protochips #FusionSelect
Publication update on a Tuesday! Check out these incredible results from Chinese Academy of Sciences and Tsinghua University just published in Nature. Using the Protochips #Atmosphere system they were able to observe the deformation of #zeolite pores at incredible resolution during the benzene adsorption. Tsinghua University Read more on their research here: https://lnkd.in/gnkFMPJi #materialsscience … Read More
Researchers, Caitlin Taylor, Tina Nenoff, Sara Pratt, and Khalid Hattar utilize #LiquidEM to study the crystallization processes of rare earth elements. You can read more about there work in their Nanoscale Advances paper: https://lnkd.in/ehbt4wU7 #Protochips, NanoMEGAS, Sandia National Laboratories, JEOL USA, JEOL Ltd. #electronmicroscopy #insitumicroscopy#microscopy #findyourbreakthrough#PoseidonSelect #ProtochipsPoseidon
Publication update on a Tuesday! Researchers at Universiteit Utrecht University have recently published on how yolk-shell particle behaviour can be influenced by an AC field using the #PoseidonSelect in an #LiquidEM environment. The mobility of the core particles was impacted just by changing the AC field creating a frequency-dependent mobility. You can read more … Read More