Our Customers

                                      Testimonials from Our Customers

  • “We were happy to acquire the VistaScope from Molecular Vista. For the past few years, we have actively used the VistaScope to do photo-induced force microscopy (PiFM) measurements on thin-films of porous materials, including zeolites and metal-organic frameworks. This has been done to learn more about reaction intermediates and products, as catalyzed by these solid materials, as well as to study the adsorption of small molecules, currently even under in-situ conditions. Although these experiments are challenging, we have always had full support and help from the team of Molecular Vista. The great advantage is that meaningful infrared spectra can be measured at the nanoscale, and that comparison with other bulk analytical methods, are possible, thereby linking the nanoworld with the macroscopic world. We can very much recommend the VistaScope to anyone interested in performing infrared nano-spectroscopy of functional materials, not limited to solid catalysts.”

    Bert M. Weckhuysen, PhD.
    Distinguished University Professor | Department of Chemistry
    Debye Institute for Nanomaterials Science | Utrecht University
    Utrecht, 3584 CG Utrecht, the Netherlands

    “As a geoscientist working in the interdisciplinary area of biomineralization, I am very open for new approaches and cutting-edge analytical developments. My samples (i.e. nacre or mother-of-pearl) are usually challenging to analyze due to its anisotropic hardness, beam sensitivity, and insulating properties. PiFM simultaneously obtained topography and phase maps with unrivaled nano-scale resolution without inducing any sort of beam damage or sample consumption while complementing other analytical techniques such as atom probe tomography, synchrotron STXM, and S/TEM imaging. Already the first few PiFM measurements of nacre have confirmed that nano-scale organic inclusions contain proteinaceous material as previously suspected. I am enthusiastic to continue using PiFM for more aspects of my research and to deepen the collaboration with the expert staff at Molecular Vista!”

    Dr Laura M Otter
    Postdoctoral Research Associate in Biomineralization
    Department of Earth and Environmental Science
    Macquarie University
    NSW, Australia

    “It is very impressive to know that we are able to use PiFM to acquire infrared spectra of both organic and inorganic materials at the nanoscale. I am a geochemist working on carbonaceous materials within the lithosphere. Although we often use Raman and FTIR to constrain the molecular characters of organic compounds at the micron scale, it is not easy to know the nano-organic chemistry of carbonaceous materials. However, PiFM can help us to get the information of minerals and organic compounds at the nanoscale (<10 nm). This technique allows us to obtain unprecedented new knowledge about the genesis of carbonaceous materials within the lithosphere. Additionally, the PiFM system is easy to control, and we were able to obtain infrared spectra in a short time. We would highly recommend PiFM to geochemists and mineralogists who are interested in nanogeochemistry of organic or inorganic geological materials.”

    Jingbo Nan PhD student | Institute of Deep Sea Science and Engineering
    Chinese Academy of Sciences Sanya, China

    “I am highly impressed about the performance of your IR PiFM instrument in revealing the detailed structure of the wood cell wall (CW).  Although we have successfully applied SEM, HIM, TEM, and TEM tomography for featuring nanoscale structures in 2D and 3D in CW, none of these techniques tells about the chemical composition.  In contrast, IR PiFM provides the chemical information with a spatial resolution of only few nanometers. In the IR PiFM images of ultrathin spruce wood sections, we could see cross sections of individual elementary fibrils (true width 3-4 nm, observed width 5-6 nm, suggesting a spatial resolution of ca. 2 nm) and other < 10 nm scale patterns in the middle lamella and in the transition layer between S1 and S2 layers of CW.  Even though people have detected these details earlier by TEM, with you we are the first ones to extract chemical (spectral) information on these nanoscale structures.  I believe your IR PiFM will revolutionize our understanding of CW with the 100 times higher resolution of the technique in comparison with confocal Raman imaging, which researchers commonly apply for chemical analysis of sections of plant tissues.  Unlike TEM, IR PiFM does not require any chemical pretreatment of the sample.  Simple cryo-cutting with an ultramicrotome is enough!”

    Tapani Vuorinen
    School of Chemical Engineering
    Aalto University
    Espoo, Finland

    We were fortunate to acquire one of the first VistaScope from Molecular Vista. For the past few years, we have used the VistaScope to do photo-induced force microscopy (PiFM) measurements with femtosecond laser pulses. We knew that these experiments were going to be challenging, but they were made so much easier because of the VistaScope. Molecular Vista has done a fantastic job designing the scan head, which allows for coupling light beams in and out of the tip-sample junction with relative ease. The system is stable, easily configurable with additional optics, and is controlled by an intuitive and versatile graphical user interface. We were able to generate interesting PiFM results as soon as the system was installed, and we have been using the system on a daily basis ever since. We can very much recommend the VistaScope to anyone interested in advanced scan probe experiments combined with optical illumination!”

    Eric Potma, PhD.
    Associate Professor | Department of Chemistry
    School of Physical Sciences | University of California, Irvine
    Irvine, CA 92697

    spp thumbnail

    We believe PiFM is poised to become a genuinely unique tool in the exploration of the phenomena derived in nanoscale systems. This new scanning probe imaging paradigm offers the distinctive prospect of detecting optically induced behavior without directly measuring the photon field created. A direct measure of induced photo-induced polarization/polarizability opens a very unique window in the study of complex materials systems. Moreover, exploiting resonance coupling of cantilever nano-mechanical modes as direct detectors of photo-mediated forces will allow phase-sensitive detection techniques to enable the sensitive observation of local optical responses with extraordinary nanoscale resolution.”

    William L. Wilson, PhD.
    Executive Director | Center for Nanoscale Systems
    Faculty of Arts and Sciences | Harvard University
    Cambridge, MA 02138

  • email: info@molecularvista.com
    (408) 915-2595

    6840 Via Del Oro
    Suite 110
    San Jose, CA 95119

  • Join the PiFM Community!

    Receive updates on our latest applications & upcoming events.