A micro-capillary local probe mass spectrometer is integrated with open-cell ETEM for localized product detection, demonstrated with Co3O4 nanoplates placed via a micro-shuttle transfer method.
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Simulations find that increasing crack width in graphene amplifies toughness gains from larger inter-crack spacing, yielding over twofold higher normalized toughness via delayed rupture rather than coalescence.
Exchange-coupled Fe-FePc molecular pairs enable remote all-electrical spin initialization through spin-polarized tunneling current and angular momentum transfer.
CASSCF-NEVPT2 calculations map the excited-state fine structure, pseudo-Jahn-Teller distortion, singlet-triplet crossings, and pressure dependence of the V_B^- center in hBN.
Oligothiophene-filled BNNTs form weakly emissive, length-dependent heterogeneous ensembles without J-aggregate radiative enhancement, while Nile Red shows dielectric tuning of its charge-transfer state.
QCOF ML potentials tuned on COF data outperform general MACE models for defective systems and reveal higher thermal defect sensitivity in CTF-1 versus COF-LZU1 with nearly invariant low-strain mechanics.
Short-range order in GeSn alloys directly influences bandgap and can be tuned by annealing, as measured by a new ML-enabled EXAFS analysis linked to photoluminescence data.
ARPES on NiPS3 reveals a many-body feature at the valence band edge matching mixed d7 and d8L multiplet states from NiS6 cluster diagonalization, indicating local Ni-S physics beyond mean-field theory.
Ammonia poisons PEM fuel cell cathodes by ammonium ions displacing hydronium at sulfonic acid sites and forming hydronium-absorbing ion clusters via hydrogen bonds, with higher temperatures helping to break up clusters and restore proton transport.
An encoder-decoder neural network trained on boundary element method data designs and compares layered cloaks for 2D Helmholtz scattering, showing object-fitted layers reduce scattering more than circular ones for circular, star, and kite objects.
Self-organising memristive networks exhibit collective nonlinear dynamics that can support physical learning with parallels to biological plasticity and potential for energy-efficient edge intelligence.
Quantum confinement in 2D hexagonal crystals like graphene and TMDs produces discrete electronic and excitonic spectra with strongly amplified interactions that enable correlated quantum states.
The paper provides an overview of symmetry-protected nodal-line structures in semimetals and their signatures in spectroscopy and transport measurements.
citing papers explorer
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A Local Probe Mass Spectrometer for Localized and Sensitive Product Detection in Environmental Electron Microscopy
A micro-capillary local probe mass spectrometer is integrated with open-cell ETEM for localized product detection, demonstrated with Co3O4 nanoplates placed via a micro-shuttle transfer method.
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Geometry-Dependent Crack Interaction and Toughening in Graphene
Simulations find that increasing crack width in graphene amplifies toughness gains from larger inter-crack spacing, yielding over twofold higher normalized toughness via delayed rupture rather than coalescence.
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Electrical Spin Pumping in Exchange-coupled Molecules
Exchange-coupled Fe-FePc molecular pairs enable remote all-electrical spin initialization through spin-polarized tunneling current and angular momentum transfer.
-
An extended ab initio theory of the V$_{\text{B}}^-$ center in hBN: excited states, Jahn-Teller distortion, and pressure dependence
CASSCF-NEVPT2 calculations map the excited-state fine structure, pseudo-Jahn-Teller distortion, singlet-triplet crossings, and pressure dependence of the V_B^- center in hBN.
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Liquid-phase encapsulation of $\pi$-conjugated dyes in boron nitride nanotubes: Ensemble and single-nanotube optical characterization
Oligothiophene-filled BNNTs form weakly emissive, length-dependent heterogeneous ensembles without J-aggregate radiative enhancement, while Nile Red shows dielectric tuning of its charge-transfer state.
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Data-Driven Thermal and Mechanical Modeling of Defective Covalent Organic Frameworks
QCOF ML potentials tuned on COF data outperform general MACE models for defective systems and reveal higher thermal defect sensitivity in CTF-1 versus COF-LZU1 with nearly invariant low-strain mechanics.
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Shining light on short-range atomic ordering in semiconductors alloys
Short-range order in GeSn alloys directly influences bandgap and can be tuned by annealing, as measured by a new ML-enabled EXAFS analysis linked to photoluminescence data.
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Evidence for Many-Body States in NiPS$_3$ Revealed by Angle-Resolved Photoelectron Spectroscopy
ARPES on NiPS3 reveals a many-body feature at the valence band edge matching mixed d7 and d8L multiplet states from NiS6 cluster diagonalization, indicating local Ni-S physics beyond mean-field theory.
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Poisoning mechanism of ammonia on proton transport and ionomer structure in cathode catalyst layer of PEM fuel cells
Ammonia poisons PEM fuel cell cathodes by ammonium ions displacing hydronium at sulfonic acid sites and forming hydronium-absorbing ion clusters via hydrogen bonds, with higher temperatures helping to break up clusters and restore proton transport.
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Solving forward and inverse wave scattering via boundary integral equations and deep learning. Applications to cloaking design
An encoder-decoder neural network trained on boundary element method data designs and compares layered cloaks for 2D Helmholtz scattering, showing object-fitted layers reduce scattering more than circular ones for circular, star, and kite objects.
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Self-Organising Memristive Networks as Physical Learning Systems
Self-organising memristive networks exhibit collective nonlinear dynamics that can support physical learning with parallels to biological plasticity and potential for energy-efficient edge intelligence.
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Correlated Quantum Phenomena in Confined Two-Dimensional Hexagonal Crystals
Quantum confinement in 2D hexagonal crystals like graphene and TMDs produces discrete electronic and excitonic spectra with strongly amplified interactions that enable correlated quantum states.
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Contemporary Insights into Electronic Structure and Microscopic Transport in Nodal-Line Semimetals
The paper provides an overview of symmetry-protected nodal-line structures in semimetals and their signatures in spectroscopy and transport measurements.