Creating two-dimensional solid helium via diamond lattice confinement

Weitong Lin; Yiran Li; Sytze de Graaf; Gang Wang; Junhao Lin; Hui Zhang; Shijun Zhao; Da Chen; Shaofei Liu; Jun Fan; Bart J. Kooi; Yang Lu; Tao Yang; Chin-Hua Yang; Chain Tsuan Liu; Ji-jung Kai

doi:10.1038/s41467-022-33601-5

Creating two-dimensional solid helium via diamond lattice confinement

Weitong Lin, Yiran Li, Sytze de Graaf, Gang Wang, Junhao Lin, Hui Zhang, Shijun Zhao, Da Chen, Shaofei Liu, Jun Fan, Bart J. Kooi, Yang Lu, Tao Yang^*, Chin-Hua Yang, Chain Tsuan Liu, Ji-jung Kai^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

8 Citations (Scopus)

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Abstract

The universe abounds with solid helium in polymorphic forms. Therefore, exploring the allotropes of helium remains vital to our understanding of nature. However, it is challenging to produce, observe and utilize solid helium on the earth because high-pressure techniques are required to solidify helium. Here we report the discovery of room-temperature two-dimensional solid helium through the diamond lattice confinement effect. Controllable ion implantation enables the self-assembly of monolayer helium atoms between {100} diamond lattice planes. Using state-of-the-art integrated differential phase contrast microscopy, we decipher the buckled tetragonal arrangement of solid helium monolayers with an anisotropic nature compressed by the robust diamond lattice. These distinctive helium monolayers, in turn, produce substantial compressive strains to the surrounded diamond lattice, resulting in a large-scale bandgap narrowing up to ~2.2 electron volts. This approach opens up new avenues for steerable manipulation of solid helium for achieving intrinsic strain doping with profound applications.

Original language	English
Article number	5990
Journal	Nature Communications
Volume	13
Online published	11 Oct 2022
DOIs	https://doi.org/10.1038/s41467-022-33601-5
Publication status	Published - 2022

Funding

We thank the director of Accelerator Laboratory, Dr. H. Niu, at National Tsing Hua University for giving us access to the 4He+ ion beamline and Mr. H.K. You for the technical support. We are grateful to Prof. A. Kouchi and Dr. T. Yamazaki at Hokkaido University for performing in situ cooling TEM experiments to explore solid helium inside nanobubbles at the initial stage of this project. J.J.K. was supported by the Hong Kong Research Grants Council (Nos. CityU11209021, CityU11214820, and CityU11205018). T.Y. was financially supported by the Hong Kong Research Grants Council (No. CityU21205621). Y.L. acknowledges the funding support from the National Natural Science Foundation of China (No. 11922215) and the Research Grants Council of the Hong Kong Special Administrative Region, China (No. RFS2021-1S05). J.L. and G.W. acknowledged the support from the National Natural Science Foundation of China (No. 11974156), Guangdong Innovative and Entrepreneurial Research Team Program (Grant No. 2019ZT08C044), Shenzhen Science and Technology Program (No. KQTD20190929173815000), and the technical support from SUSTech Core Research Facilities and Pico-Centre.

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@article{c76095e9587b42a9aca9d5d8eadbd6d9,

title = "Creating two-dimensional solid helium via diamond lattice confinement",

abstract = "The universe abounds with solid helium in polymorphic forms. Therefore, exploring the allotropes of helium remains vital to our understanding of nature. However, it is challenging to produce, observe and utilize solid helium on the earth because high-pressure techniques are required to solidify helium. Here we report the discovery of room-temperature two-dimensional solid helium through the diamond lattice confinement effect. Controllable ion implantation enables the self-assembly of monolayer helium atoms between {100} diamond lattice planes. Using state-of-the-art integrated differential phase contrast microscopy, we decipher the buckled tetragonal arrangement of solid helium monolayers with an anisotropic nature compressed by the robust diamond lattice. These distinctive helium monolayers, in turn, produce substantial compressive strains to the surrounded diamond lattice, resulting in a large-scale bandgap narrowing up to ~2.2 electron volts. This approach opens up new avenues for steerable manipulation of solid helium for achieving intrinsic strain doping with profound applications.",

author = "Weitong Lin and Yiran Li and {de Graaf}, Sytze and Gang Wang and Junhao Lin and Hui Zhang and Shijun Zhao and Da Chen and Shaofei Liu and Jun Fan and Kooi, {Bart J.} and Yang Lu and Tao Yang and Chin-Hua Yang and Liu, {Chain Tsuan} and Ji-jung Kai",

year = "2022",

doi = "10.1038/s41467-022-33601-5",

language = "English",

volume = "13",

journal = "Nature Communications",

issn = "2041-1723",

publisher = "Springer Nature",

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TY - JOUR

T1 - Creating two-dimensional solid helium via diamond lattice confinement

AU - Lin, Weitong

AU - Li, Yiran

AU - de Graaf, Sytze

AU - Wang, Gang

AU - Lin, Junhao

AU - Zhang, Hui

AU - Zhao, Shijun

AU - Chen, Da

AU - Liu, Shaofei

AU - Fan, Jun

AU - Kooi, Bart J.

AU - Lu, Yang

AU - Yang, Tao

AU - Yang, Chin-Hua

AU - Liu, Chain Tsuan

AU - Kai, Ji-jung

PY - 2022

Y1 - 2022

N2 - The universe abounds with solid helium in polymorphic forms. Therefore, exploring the allotropes of helium remains vital to our understanding of nature. However, it is challenging to produce, observe and utilize solid helium on the earth because high-pressure techniques are required to solidify helium. Here we report the discovery of room-temperature two-dimensional solid helium through the diamond lattice confinement effect. Controllable ion implantation enables the self-assembly of monolayer helium atoms between {100} diamond lattice planes. Using state-of-the-art integrated differential phase contrast microscopy, we decipher the buckled tetragonal arrangement of solid helium monolayers with an anisotropic nature compressed by the robust diamond lattice. These distinctive helium monolayers, in turn, produce substantial compressive strains to the surrounded diamond lattice, resulting in a large-scale bandgap narrowing up to ~2.2 electron volts. This approach opens up new avenues for steerable manipulation of solid helium for achieving intrinsic strain doping with profound applications.

AB - The universe abounds with solid helium in polymorphic forms. Therefore, exploring the allotropes of helium remains vital to our understanding of nature. However, it is challenging to produce, observe and utilize solid helium on the earth because high-pressure techniques are required to solidify helium. Here we report the discovery of room-temperature two-dimensional solid helium through the diamond lattice confinement effect. Controllable ion implantation enables the self-assembly of monolayer helium atoms between {100} diamond lattice planes. Using state-of-the-art integrated differential phase contrast microscopy, we decipher the buckled tetragonal arrangement of solid helium monolayers with an anisotropic nature compressed by the robust diamond lattice. These distinctive helium monolayers, in turn, produce substantial compressive strains to the surrounded diamond lattice, resulting in a large-scale bandgap narrowing up to ~2.2 electron volts. This approach opens up new avenues for steerable manipulation of solid helium for achieving intrinsic strain doping with profound applications.

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U2 - 10.1038/s41467-022-33601-5

DO - 10.1038/s41467-022-33601-5

M3 - RGC 21 - Publication in refereed journal

C2 - 36220818

SN - 2041-1723

VL - 13

JO - Nature Communications

JF - Nature Communications

M1 - 5990

ER -

Creating two-dimensional solid helium via diamond lattice confinement

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GRF: Enhancing Irradiation Resistance of High Entropy Alloys Through FCC-BCC Eutectic Structure

ECS: Grain-Boundary Toughening Mechanisms and Thermal Resistance of Novel Nanoparticles-Strengthened High-Entropy Alloys with Hetero-Lamellar Grain Structures at Intermediate Temperatures

RFS: Nanomechanics of Covalent Crystals and Their Elastic Strain Engineering

Cite this

Creating two-dimensional solid helium via diamond lattice confinement

Abstract

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Publisher's Copyright Statement

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Projects

GRF: Enhancing Irradiation Resistance of High Entropy Alloys Through FCC-BCC Eutectic Structure

ECS: Grain-Boundary Toughening Mechanisms and Thermal Resistance of Novel Nanoparticles-Strengthened High-Entropy Alloys with Hetero-Lamellar Grain Structures at Intermediate Temperatures

RFS: Nanomechanics of Covalent Crystals and Their Elastic Strain Engineering

Cite this