1,170 research outputs found
Dynamic Transformations of Genome-wide Epigenetic Marking and Transcriptional Control Establish T Cell Identity
T cell development comprises a stepwise process of commitment from a multipotent precursor. To define molecular mechanisms controlling this progression, we probed five stages spanning the commitment process using RNA-seq and ChIP-seq to track genome-wide shifts in transcription, cohorts of active transcription factor genes, histone modifications at diverse classes of cis-regulatory elements, and binding repertoire of GATA-3 and PU.1, transcription factors with complementary roles in T cell development. The results highlight potential promoter-distal cis-regulatory elements in play and reveal both activation sites and diverse mechanisms of repression that silence genes used in alternative lineages. Histone marking is dynamic and reversible, and though permissive marks anticipate, repressive marks often lag behind changes in transcription. In vivo binding of PU.1 and GATA-3 relative to epigenetic marking reveals distinctive factor-specific rules for recruitment of these crucial transcription factors to different subsets of their potential sites, dependent on dose and developmental context
Machine-Learning Interatomic Potentials Enable First-Principles Multiscale Modeling of Lattice Thermal Conductivity in Graphene/Borophene Heterostructures
One of the ultimate goals of computational modeling in condensed matter is to
be able to accurately compute materials properties with minimal empirical
information. First-principles approaches such as the density functional theory
(DFT) provide the best possible accuracy on electronic properties but they are
limited to systems up to a few hundreds, or at most thousands of atoms. On the
other hand, classical molecular dynamics (CMD) simulations and finite element
method (FEM) are extensively employed to study larger and more realistic
systems, but conversely depend on empirical information. Here, we show that
machine-learning interatomic potentials (MLIPs) trained over short ab-initio
molecular dynamics trajectories enable first-principles multiscale modeling, in
which DFT simulations can be hierarchically bridged to efficiently simulate
macroscopic structures. As a case study, we analyze the lattice thermal
conductivity of coplanar graphene/borophene heterostructures, recently
synthesized experimentally (Sci. Adv. 2019; 5: eaax6444), for which no viable
classical modeling alternative is presently available. Our MLIP-based approach
can efficiently predict the lattice thermal conductivity of graphene and
borophene pristine phases, the thermal conductance of complex
graphene/borophene interfaces and subsequently enable the study of effective
thermal transport along the heterostructures at continuum level. This work
highlights that MLIPs can be effectively and conveniently employed to enable
first-principles multiscale modeling via hierarchical employment of DFT/CMD/FEM
simulations, thus expanding the capability for computational design of novel
nanostructures
First-Principles Multiscale Modeling of Mechanical Properties in Graphene/Borophene Heterostructures Empowered by Machine-Learning Interatomic Potentials
Density functional theory calculations are robust tools to explore the mechanical properties of pristine structures at their ground state but become exceedingly expensive for large systems at finite temperatures. Classical molecular dynamics (CMD) simulations offer the possibility to study larger systems at elevated temperatures, but they require accurate interatomic potentials. Herein the authors propose the concept of first-principles multiscale modeling of mechanical properties, where ab initio level of accuracy is hierarchically bridged to explore the mechanical/failure response of macroscopic systems. It is demonstrated that machine-learning interatomic potentials (MLIPs) fitted to ab initio datasets play a pivotal role in achieving this goal. To practically illustrate this novel possibility, the mechanical/failure response of graphene/borophene coplanar heterostructures is examined. It is shown that MLIPs conveniently outperform popular CMD models for graphene and borophene and they can evaluate the mechanical properties of pristine and heterostructure phases at room temperature. Based on the information provided by the MLIP-based CMD, continuum models of heterostructures using the finite element method can be constructed. The study highlights that MLIPs were the missing block for conducting first-principles multiscale modeling, and their employment empowers a straightforward route to bridge ab initio level accuracy and flexibility to explore the mechanical/failure response of nanostructures at continuum scale
Highly anisotropic mechanical and optical properties of 2D NbOX2 (X = Cl, Br, I) revealed by first-principle
In the latest experimental success, NbOI2 two-dimensional (2D) crystals with anisotropic electronic and optical properties have been fabricated (Adv. Mater. 33 (2021), 2101505). In this work inspired by the aforementioned accomplishment, we conduct first-principles calculations to explore the mechanical, electronic, and optical properties of NbOX2 (X = Cl, Br, I) nanosheets. We show that individual layers in these systems are weakly bonded, with exfoliation energies of 0.22, 0.23, and 0.24 J m-2, for the isolation of the NbOCl2, NbOBr2, and NbOI2 monolayers, respectively, distinctly lower than those of the graphene. The optoelectronic properties of the single-layer, bilayer, and bulk NbOCl2, NbOBr2, and NbOI2 crystals are investigated via density functional theory calculations with the HSE06 approach. Our results indicate that the layered bulk NbOCl2, NbOBr2, and NbOI2 crystals are indirect gap semiconductors, with band gaps of 1.79, 1.69, and 1.60 eV, respectively. We found a slight increase in the electronic gap for the monolayer and bilayer systems due to electron confinement at the nanoscale. Our results show that the monolayer and bilayer of these novel 2D compounds show suitable valence and conduction band edge positions for visible-light-driven water splitting reactions. The first absorption peaks of these novel monolayers along the in-plane polarization are located in the visible range of light which can be a promising feature to design advanced nanoelectronics. We found that the studied 2D systems exhibit highly anisotropic mechanical and optical properties. The presented first-principles results provide a comprehensive vision about direction-dependent mechanical and optical properties of NbOX2 (X = Cl, Br, I) nanosheets
Electronic, Optical, Mechanical and Li-Ion Storage Properties of Novel Benzotrithiophene-Based Graphdiyne Monolayers Explored by First Principles and Machine Learning
Recently, benzotrithiophene graphdiyne (BTT-GDY), a novel two-dimensional (2D) carbon-based material, was grown via a bottom-up synthesis strategy. Using the BTT-GDY lattice and by replacing the S atoms with N, NH and O, we designed three novel GDY lattices, which we named BTHP-, BTP- and BTF-GDY, respectively. Next, we explored structural, electronic, mechanical, optical, photocatalytic and Li-ion storage properties, as well as carrier mobilities, of novel GDY monolayers. Phonon dispersion relations, mechanical and failure behavior were explored using the machine learning interatomic potentials (MLIPs). The obtained HSE06 results reveal that BTX-GDYs (X = P, F, T) are direct gap semiconductors with band gaps in the range of 2.49–2.65 eV, whereas the BTHP-GDY shows a narrow indirect band gap of 0.06 eV. With appropriate band offsets, good carrier mobilities and a strong capability for the absorption of visible and ultraviolet range of light, BTF- and BTT-GDYs were predicted to be promising candidates for overall photocatalytic water splitting. The BTHP-GDY nanosheet, noticeably, was found to yield an ultrahigh Li-ion storage capacity of over 2400 mAh/g. The obtained findings provide a comprehensive vision of the critical physical properties of the novel BTT-based GDY nanosheets and highlight their potential for applications in nanoelectronics and energy storage and conversion systems
Exploring Phononic Properties of Two-Dimensional Materials using Machine Learning Interatomic Potentials
Phononic properties are commonly studied by calculating force constants using
the density functional theory (DFT) simulations. Although DFT simulations offer
accurate estimations of phonon dispersion relations or thermal properties, but
for low-symmetry and nanoporous structures the computational cost quickly
becomes very demanding. Moreover, the computational setups may yield
nonphysical imaginary frequencies in the phonon dispersion curves, impeding the
assessment of phononic properties and the dynamical stability of the considered
system. Here, we compute phonon dispersion relations and examine the dynamical
stability of a large ensemble of novel materials and compositions. We propose a
fast and convenient alternative to DFT simulations which derived from
machine-learning interatomic potentials passively trained over computationally
efficient ab-initio molecular dynamics trajectories. Our results for diverse
two-dimensional (2D) nanomaterials confirm that the proposed computational
strategy can reproduce fundamental thermal properties in close agreement with
those obtained via the DFT approach. The presented method offers a stable,
efficient, and convenient solution for the examination of dynamical stability
and exploring the phononic properties of low-symmetry and porous 2D materials
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