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1. A Laser Ablation ICP‐MS Protocol for High‐Resolution Iodine‐to‐Calcium Ratio (I/Ca) Analysis on Corals

   https://doi.org/10.1002/rcm.10002  

   Prow‐Fleischer, Ashley N.; Lu, Zunli (February 2025, Rapid Communications in Mass Spectrometry)

   ABSTRACT RationaleCorals are continuous, time‐resolved archives of ambient seawater geochemistry and can extend climate records beyond direct monitoring. The iodine‐to‐calcium (I/Ca) ratio may be a proxy for local oxygen depletion in corals, but the current solution‐based ICP‐MS protocol limits sampling resolution. A protocol was developed for rapid analysis of coral I/Ca using laser ablation ICP‐MS. MethodsTwo reference materials, a powdered coral (JCp‐1) and a synthetic carbonate (MACS‐3), were compared for precision in measuring Sr, Mg, I, Ba, and U. Then, the influence of laser parameters (spot size, fluence, repetition rate, and scan speed) on iodine sensitivity from the reference material was evaluated to optimize laser settings for accurate and reproducible I/Ca calibration. Then, I/Ca was measured in line scans along and across the ambulacrum in aDiploria labyrinthiformiscoral. ResultsWe find that JCp‐1 has greater precision in measuring iodine, as well as other traces, compared to MACS‐3. At a 10 Hz repetition rate, spot sizes from 150 to 85 μm obtained concentrations in agreement with certified values, but higher repetition rates overestimated iodine concentrations from JCp‐1. Certain scan speeds and fluence can introduce noise, likely due to matrix effects, but the signal‐to‐noise ratio can be improved by adjacent‐average filtering. Using this simple data filtering routine and optimized laser settings, the highest resolution for accurate I/Ca analysis is < 100 μm. While the fine‐scale (< 250 μm) I/Ca variabilities in parallel transects in a coral sample likely resulted from biomineralization processes, large ‐scale features (> 500 μm) along the ambulacrum tend to correlate. ConclusionsLA‐ICP‐MS has great potential for accurate, high‐resolution I/Ca profiling in corals using JCp‐1 as a calibration standard. Because of compositional variability near centers of calcification, it is important to pay attention to how the laser transect is aligned relative to skeletal elements, which may incorporate iodine differently. 

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2. Suppressing Metal Nanoparticle Ablation with Double-Pulse Femtosecond Laser Sintering

   https://doi.org/10.1089/3dp.2022.0229  

   Park, Janghan; Ye, Zefang; Celio, Hugo; Wang, Yaguo (February 2023, 3D Printing and Additive Manufacturing)

   As a branch of laser powder bed fusion, selective laser sintering (SLS) with femtosecond (fs) lasers and metal nanoparticles (NPs) can achieve high precision and dense submicron features with reduced residual stress, due to the extremely short pulse duration. Successful sintering of metal NPs with fs laser is challenging due to the ablation caused by hot electron effects. In this study, a double-pulse sintering strategy with a pair of time- delayed fs-laser pulses is proposed for controlling the electron temperature while still maintaining a high enough lattice temperature. We demonstrate that when delay time is slightly longer than the electron-phonon coupling time of Cu NPs, the ablation area was drastically reduced and the power window for successful sintering was extended by about two times. Simultaneously, the heat-affected zone can be reduced by 66% (area). This new strategy can be adopted for all the SLS processes with fs laser and unlock the power of SLS with fs lasers for future applications. 

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3. Dynamics of nanoscale phase decomposition in laser ablation

   https://doi.org/10.1038/s43246-025-00785-4  

   Sun, Yanwen; Chen, Chaobo; Albert, Thies J; Li, Haoyuan; Arefev, Mikhail I; Chen, Ying; Dunne, Mike; Glownia, James M; Jerman, Martin; Hoffmann, Matthias; et al (December 2025, Communications Materials)

   Abstract Laser ablation is a process that bears both fundamental physics interest and has wide industrial applications. For decades, the lack of probes on the relevant time and length scales has prevented access to the highly nonequilibrium phase decomposition processes triggered by laser excitation. In this study, a close integration of time-resolved probing by intense femtosecond X-ray pulses with large-scale atomistic modeling has yielded unique insights into the ablation dynamics of thin gold films irradiated by femtosecond laser pulses. The emergence and growth of nanoscale density heterogeneities in the expanding ablation plume, predicted in the simulations, are mapped to the rapid evolution of distinct small angle diffraction features. This mapping enables identification of the characteristic signatures of different phase decomposition processes occurring simultaneously in the plume, which are driven by photomechanical and thermodynamic driving forces. Beyond the specific insights into the ablation phenomenon, this study demonstrates the power of joint X-ray probing and atomistic modeling of material dynamics under extreme conditions of thermal and mechanical nonequilibrium. 

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4. High Spatial Resolution Petrochronology by Laser Ablation: Application to Complex Accessory Minerals

   Kylander-Clark, Andrew; Cottle, John; Adamson, M (July 2025, Geochemical Society)

   Our ability to reconstruct the crystallization history of a given accessory mineral (i.e., geochronometers such as zircon, titanite, monazite, etc.)—and thus the geologic processes of its host—has increased severalfold over the past few decades; primarily through advances in precision, concurrent chemical analysis, throughput, and spatial resolution. In this contribution, we present a methodology that takes these advances a step further through the rapid characterization of a large number of accessory minerals at micron-scale resolution via laser-ablation inductively coupled plasma mass spectrometry. Our analytical setup employs an ultrafast washout laser (~1 ms; Element Scientific Laser) that can send individual, <5um ablation pulses to either one or both of two instruments: a Nu Plasma 3D mulitcollector ICP-MS and a Nu Vitesse time-of-flight ICP-MS. Because either ICP-MS can measure at the sub-ms timescale, every pulse can be analyzed at 100’s of Hz; 1D, 2D, or 3D analysis is possible, and data can be processed in a matter of minutes and hours, instead of days or weeks. We highlight the advantages of this methodology through examples of accessory phases in complex plutonic rocks and high-grade metamorphic terranes. 

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5. Rapid high-resolution volumetric imaging via laser ablation delayering and confocal imaging

   https://doi.org/10.1038/s41598-022-16519-2  

   Phoulady, Adrian; May, Nicholas; Choi, Hongbin; Suleiman, Yara; Shahbazmohamadi, Sina; Tavousi, Pouya (December 2022, Scientific Reports)

   Abstract Acquiring detailed 3D images of samples is needed for conducting thorough investigations in a wide range of applications. Doing so using nondestructive methods such as X-ray computed tomography (X-ray CT) has resolution limitations. Destructive methods, which work based on consecutive delayering and imaging of the sample, face a tradeoff between throughput and resolution. Using focused ion beam (FIB) for delayering, although high precision, is low throughput. On the other hand, mechanical methods that can offer fast delayering, are low precision and may put the sample integrity at risk. Herein, we propose to use femtosecond laser ablation as a delayering method in combination with optical and confocal microscopy as the imaging technique for performing rapid 3D imaging. The use of confocal microscopy provides several advantages. First, it eliminates the 3D image distortion resulting from non-flat layers, caused by the difference in laser ablation rate of different materials. It further allows layer height variations to be maintained within a small range. Finally, it enables material characterization based on the processing of material ablation rate at different locations. The proposed method is applied on a printed circuit board (PCB), and the results are validated and compared with the X-ray CT image of the PCB part. 

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