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Nitrogen-doped amorphous monolayer carbon

Free-standing nitrogen-doped amorphous monolayer carbon consisting of mixed five-, six- and seven-membered rings was prepared through the polymerization of pyrrole within the confined interlayer cavity of a removable layered-double-hydroxide template.

Xiuhui Bai
Pengfei Hu
Lin Guo
Research25 Sept 2024
Nature

Volume: 634, P: 80-84
Omnireg-gpt: a high-efficiency foundation model for comprehensive genomic sequence understanding

Understanding long-range genomic regulation is a key challenge for DNA foundation models. Here, authors develop OmniReg-GPT with a hybrid local-global attention architecture, enabling efficient analysis of multi-scale regulatory features across long DNA sequences.

Aowen Wang
Jiaqi Li
Junbo Zhao
ResearchOpen Access19 Nov 2025
Nature Communications

Volume: 16, P: 1-17
Single-atom vibrational spectroscopy with chemical-bonding sensitivity

Vibrational spectroscopy now allows for the exploration of lattice vibrational properties at the chemical-bond level, revealing the impact of chemical-bonding configurations and atomic mass on local phonon modes in graphene with a new level of sensitivity.

Mingquan Xu
De-Liang Bao
Wu Zhou
Research16 Mar 2023
Nature Materials

Volume: 22, P: 612-618
Publisher Correction: Nitrogen-doped amorphous monolayer carbon

Xiuhui Bai
Pengfei Hu
Lin Guo
Amendments and Corrections07 Oct 2024
Nature

Volume: 634, P: E16
Shielding Pt/γ-Mo₂N by inert nano-overlays enables stable H₂ production

Atomically dispersed inert oxide nano-overlays on a highly active Pt/γ-Mo₂N catalyst can block the redundant surface sites of γ-Mo₂N responsible for surface oxidation of this reactive support and the resulting deactivation, without compromising the intrinsic activity of active Pt@Mo2N interface.

Zirui Gao
Aowen Li
Ding Ma
Research12 Feb 2025
Nature

Volume: 638, P: 690-696
Synergizing metal–support interactions and spatial confinement boosts dynamics of atomic nickel for hydrogenations

Synergizing metal–support interactions and spatial confinement through atomic copper grippers boost the dynamics of highly loaded atomic nickel for high activity, high thermal/chemical stability and unprecedented coke inhibition in hydrogenation reactions.

Jian Gu
Minzhen Jian
Junling Lu
Research26 Jul 2021
Nature Nanotechnology

Volume: 16, P: 1141-1149
Electrochemical CO₂ reduction to ethylene by ultrathin CuO nanoplate arrays

Oxide-derived copper has been extensively studied as catalysts for CO₂ electroreduction but its catalytic stability and selectivity still need to be improved. Here, the authors report ultrathin CuO nanoplate arrays for CO₂ reduction with high ethylene selectivity and enhanced long-term stability.

Wei Liu
Pengbo Zhai
Yongji Gong
ResearchOpen Access06 Apr 2022
Nature Communications

Volume: 13, P: 1-12
Copper-catalysed exclusive CO₂ to pure formic acid conversion via single-atom alloying

Alloying copper with isolated heteroatoms enables the C protonation of CO₂ to HCOO* on activated copper sites, resulting in exclusive electrochemical CO₂-to-HCOOH conversion with considerably high activity.

Tingting Zheng
Chunxiao Liu
Jie Zeng
Research16 Sept 2021
Nature Nanotechnology

Volume: 16, P: 1386-1393
Atomic-level insights in optimizing reaction paths for hydroformylation reaction over Rh/CoO single-atom catalyst

Despite the advantages of using heterogeneous catalysts, most successful rhodium hydrogenations are carried out with homogeneous catalysts. Here the authors report a supported single atom rhodium catalyst providing high activities and selectivities for propene hydroformylation.

Liangbing Wang
Wenbo Zhang
Jie Zeng
ResearchOpen Access22 Dec 2016
Nature Communications

Volume: 7, P: 1-8
A stable low-temperature H₂-production catalyst by crowding Pt on α-MoC

A stable, low-temperature water–gas shift catalyst is achieved by crowding platinum atoms and clusters on α-molybdenum carbide; the crowding protects the support from oxidation that would cause catalyst deactivation.

Xiao Zhang
Mengtao Zhang
Ding Ma
Research20 Jan 2021
Nature

Volume: 589, P: 396-401

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