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1. A multi-mass and multi-hit two-camera 3D ion momentum imaging system

   https://doi.org/10.1063/5.0220000  

   Orunesajo, Emmanuel; Abubakar, Sulaiman; Oguh, Blessed; Lee, Suk Kyoung; Li, Wen (July 2024, Review of Scientific Instruments)

   We demonstrate an improved two-camera system for multi-mass and multi-hit three-dimensional (3D) momentum imaging of ions. The imaging system employs two conventional complementary metal–oxide–semiconductor cameras. We have shown previously that the system can time slice ion Newton spheres with a time resolution of 8.8 ns, limited by camera timing jitter [J. Chem. Phys., 158, 191104 (2023)]. In this work, a jitter correction method was developed to suppress the camera jitter and improve the time resolution to better than 2 ns. With this resolution, full 3D momentum distributions of ions can be obtained. We further show that this method can detect two ions with different masses when utilizing both the rising and falling edges of the cameras. 

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2. Dual-Hyperspectral Optical Pump-Probe Microscopy with Single-Nanosecond Time Resolution

   https://doi.org/10.1021/jacs.3c12284  

   Li, Bowen; Xu, Joy; Kocoj, Conrad A.; Li, Shunran; Li, Yanyan; Chen, Du; Zhang, Shuchen; Dou, Letian; Guo, Peijun (January 2024, Journal of the American Chemical Society)

   In recent years, optical pump-probe microscopy (PPM) has become a vital technique for spatiotemporally imaging electronic excitations and charge-carrier transport in metals and semiconductors. However, existing methods are limited by mechanical delay lines with a probe time window of only several nanoseconds (ns), or monochromatic pump and probe sources with restricted spectral coverage and temporal resolution, hindering their amenability in studying relatively slow processes. To bridge these gaps, we introduce a dual-hyperspectral PPM setup with a time window spanning from ns to milliseconds and single-ns resolution. Our method features a wide-field probe tunable from 370 nm to 1000 nm and a pump spanning from 330 nm to 16 µm. We apply this PPM technique to study various two-dimensional metal-halide perovskites (2D-MHPs) as representative semiconductors by imaging their transient responses near the exciton resonances under both above-bandgap, electronic pump excitation, and below-bandgap, vibrational pump excitation. The resulting spatially- and temporally-resolved images reveal insights into heat dissipation, film uniformity, distribution of impurity phases, and film-substrate interfaces. In addition, the single-ns temporal resolution enables the imaging of in-plane strain wave propagation in 2D-MHP single crystals. Our method, which offers extensive spectral tunability and significantly improved time resolution, opens new possibilities for the imaging of charge carriers, heat, and transient phase transformation processes, particularly in materials with spatially-varying composition, strain, crystalline structure, and interfaces. 

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3. Nanospray Desorption Electrospray Ionization (nano-DESI) Mass Spectrometry Imaging of Drift Time-Separated Ions

   https://doi.org/10.26434/chemrxiv.12609536.v1  

   Unsihuay, D.; Yin, R; Mesa Sanchez, D.; Li, Y.; Sun, X.; Dey, S.K.; Laskin, J. (June 2020, ChemRxiv)

   null (Ed.)

   Simultaneous spatial localization and structural characterization of molecules in complex biological samples currently represents an analytical challenge for mass spectrometry imaging (MSI) techniques. In this study, we describe a novel experimental platform, which substantially expands the capabilities and enhances the depth of chemical information obtained in high spatial resolution MSI experiments performed using nanospray desorption electrospray ionization (nano-DESI). Specifically, we designed and constructed a portable nano-DESI MSI platform and coupled it with a drift tube ion mobility spectrometer-mass spectrometer (IM-MS). Separation of biomolecules observed in MSI experiments based on their drift times provides unique molecular descriptors necessary for their identification by comparison with databases. Furthermore, it enables isomer-specific imaging, which is particularly important for unraveling the complexity of biological systems. Imaging of day 4 pregnant mouse uterine sections using the newly developed nano-DESI-IM-MSI system demonstrates rapid isobaric and isomeric separation and reduced chemical noise in MSI experiments. A direct comparison of the performance of the new nano-DESI-MSI platform operated in the MS mode with the more established nano-DESI-Orbitrap platform indicates a comparable performance of these two systems. A spatial resolution of better than ~16 μm and similar molecular coverage was obtained using both platforms. The structural information provided by the ion mobility separation expands the molecular specificity of high-resolution MSI necessary for the detailed understanding of biological systems. 

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4. Advanced picosecond precision Radio Frequency Timer

   https://doi.org/10.1088/1748-0221/19/02/C02014  

   Zhamkochyan, S.; Kakoyan, V.; Abrahamyan, S.; Elbakyan, H.; Ayvazyan, G.; Ayvazyan, R.; Ghalumyan, A.; Kakoyan, A.; Mayilyan, S.; Papyan, A.; et al (February 2024, Journal of Instrumentation)

   Abstract A new type of radio frequency (RF) timing technique is presented. It is based on a helical deflector, which performs circular or elliptical sweeps of photo- or secondary electrons, accelerated to keV energies, by means of RF fields in the 500–1000 MHz range. By converting a time distribution of the electrons to a hit position distribution on a circle or ellipse, this device achieves extremely precise timing, similar to streak cameras. Detection of the scanned electrons, using a position sensitive detector based on microchannel plates and a delay line anode, resulted in a timing resolution of 10 ps, which can be potentially improved to 1 ps. RF-Timer-based single photon and heavy ion detectors have potential applications in different fields of science and industry, which include high energy nuclear physics and imaging technologies. This technique could play a crucial role in developing of sub 10 ps Time-of-Flight Positron Emission Tomography. 

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5. Ultrahigh-resolution scanning microwave impedance microscopy of moiré lattices and superstructures

   https://doi.org/10.1126/sciadv.abd1919  

   Lee, Kyunghoon; Utama, M. Iqbal; Kahn, Salman; Samudrala, Appalakondaiah; Leconte, Nicolas; Yang, Birui; Wang, Shuopei; Watanabe, Kenji; Taniguchi, Takashi; Altoé, M. Virginia; et al (December 2020, Science Advances)

   null (Ed.)

   Two-dimensional heterostructures composed of layers with slightly different lattice vectors exhibit new periodic structure known as moiré lattices, which, in turn, can support novel correlated and topological phenomena. Moreover, moiré superstructures can emerge from multiple misaligned moiré lattices or inhomogeneous strain distributions, offering additional degrees of freedom in tailoring electronic structure. High-resolution imaging of the moiré lattices and superstructures is critical for understanding the emerging physics. Here, we report the imaging of moiré lattices and superstructures in graphene-based samples under ambient conditions using an ultrahigh-resolution implementation of scanning microwave impedance microscopy. Although the probe tip has a gross radius of ~100 nm, spatial resolution better than 5 nm is achieved, which allows direct visualization of the structural details in moiré lattices and the composite super-moiré. We also demonstrate artificial synthesis of novel superstructures, including the Kagome moiré arising from the interplay between different layers. 

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