
Frontal polymerization can be harnessed to autonomously fabricate patterned crystalline domains in polymers, enabling the control of material properties through the manipulation of processing conditions.


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Frontal polymerization spin mode dynamics is used to autonomously fabricate patterned crystalline domains in poly(cyclooctadiene) with multiscale organization.

Controlled patterning of crystalline domains by frontal polymerization - Nature

autonomous-fabrication-of-patterned-crystalline-domains-in-polymers-through-frontal-polymerization


Autonomous Fabrication of Patterned Crystalline Domains in Polymers through Frontal Polymerization


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A novel H2-based redox synthesis and compaction approach that merges metal extraction, alloying, and thermomechanical processing into a single solid-state operation, enabling the production of sustainable bulk alloys with application-worthy properties.


A one-step hydrogen-based redox process turns oxides directly into green alloys in bulk forms, with application-worthy properties.

One step from oxides to sustainable bulk alloys - Nature

sustainable-bulk-alloy-production-transforming-oxides-into-high-performance-alloys-through-innovative-solid-state-processing


Sustainable Bulk Alloy Production: Transforming Oxides into High-Performance Alloys through Innovative Solid-State Processing



The research presents a comprehensive scientometric analysis of the field of metal-organic frameworks (MOFs), integrating natural language processing, topic modeling, and network analysis methods, and engaging domain experts to provide in-depth interpretation and refinement of the results.


comprehensive-scientometric-analysis-of-the-evolving-field-of-metal-organic-frameworks


Comprehensive Scientometric Analysis of the Evolving Field of Metal-Organic Frameworks



Machine learning-assisted screening of over 12,000 metal binary alloys identified hundreds of promising anode candidates with low potential and high specific capacity for Li, Na, K, Zn, Mg, Ca, and Al-based battery systems.


efficient-screening-of-metal-binary-alloys-as-promising-anode-materials-for-various-battery-systems-using-machine-learning


Efficient Screening of Metal Binary Alloys as Promising Anode Materials for Various Battery Systems Using Machine Learning



A semi-supervised disentangled variational autoencoder is developed to efficiently and interpretably design single-phase high-entropy alloys by learning a probabilistic relationship between materials representations and target properties.


data-efficient-and-interpretable-inverse-design-of-single-phase-high-entropy-alloys-using-a-disentangled-variational-autoencoder


Data-Efficient and Interpretable Inverse Design of Single-Phase High-Entropy Alloys using a Disentangled Variational Autoencoder



A graph neural network model leverages latent structural and compositional information from a pretrained universal neural network potential to accurately predict electronic, ionic, and total dielectric tensors for inorganic materials.


accurate-prediction-of-dielectric-tensors-for-inorganic-materials-using-latent-information-from-a-pretrained-neural-network-potential


Accurate Prediction of Dielectric Tensors for Inorganic Materials Using Latent Information from a Pretrained Neural Network Potential



Controlled doping of perovskite semiconductors can tune their electrical conductivity and enable switching between positive and negative charge carrier conduction.


An approach for changing the density of charge carriers in perovskites.

Future optoelectronics unlocked by ‘doping’ strategy

controlled-doping-unlocks-new-possibilities-for-perovskite-optoelectronics


Controlled Doping Unlocks New Possibilities for Perovskite Optoelectronics



Reliable control of p- and n-type conductivity in perovskite semiconductors, enabling high-performance optoelectronic devices.


The charge carrier polarity and&nbsp;concentrations in an emissive perovskite semiconductor can be adjusted by incorporating a molecular dopant widely used for the passivation and structural control of optoelectronic perovskite materials.

Controllable p- and n-type behaviours in emissive perovskite semiconductors - Nature

achieving-controllable-p-and-n-type-conductivity-in-high-performance-perovskite-semiconductors


Achieving Controllable p- and n-type Conductivity in High-Performance Perovskite Semiconductors



A novel Ti-Ni strain glass alloy demonstrates an exceptional combination of ultrahigh yield strength, ultralow elastic modulus, and super-large rubber-like elastic strain, making it a promising candidate for futuristic technologies.


A polymer-like ultrahigh-strength TiNi alloy was fabricated by a simple three-step process to give a combination of a polymer-like ultralow elastic modulus and a steel-like ultrahigh yield strength over a wide temperature range, and such exotic properties arise from a unique strain glass state.

A polymer-like ultrahigh-strength metal alloy - Nature

innovative-ti-ni-strain-glass-alloy-exhibits-exceptional-strength-flexibility-and-temperature-stability


Innovative Ti-Ni Strain Glass Alloy Exhibits Exceptional Strength, Flexibility, and Temperature Stability



Illumination at 455 nm can accelerate the phase transition from semiconducting 2H to metallic 1T phase in 2D transition metal dichalcogenides by up to six orders of magnitude, enabled by a photoredox process that improves the rate-limiting charge-transfer kinetics.


Chemical lithiation of two-dimensional transition metal dichalcogenides can be accelerated by up to six orders of magnitude using low-power illumination and a variety of phase transition agents.

Photoredox phase engineering of transition metal dichalcogenides - Nature

accelerating-phase-transition-in-2d-transition-metal-dichalcogenides-through-photoredox-engineering


Accelerating Phase Transition in 2D Transition Metal Dichalcogenides through Photoredox Engineering
