×
模态框(Modal)标题
在这里添加一些文本
Close
Close
Submit
Cancel
Confirm
×
模态框(Modal)标题
×
中文
Progress in Chemistry
About journal
About journal
Editorial board
Ethical statements
Contact
Cooperation
Browse
Current issue
Earlier issues
Special issues
Special topics
Feature section
MiniAccounts
Foot print of Chinese chemistry
Browse by areas
Top downloaded
Top viewed
Top cited
Just accepted
Author center
Instructions authors
Author center
Download center
Manuscript center
Editor login
EiC login
Peer reviewer login
Subscription
Print journal
E-mail Alert
Rss
Feedback
News
中文
Earlier issues
About journal
About journal
Editorial board
Ethical statements
Contact
Cooperation
Browse
Current issue
Earlier issues
Special issues
Special topics
Feature section
MiniAccounts
Foot print of Chinese chemistry
Browse by areas
Top downloaded
Top viewed
Top cited
Just accepted
Author center
Guide for author
Submission now
Download center
Manuscript center
Editor login
EiC login
Peer reviewer login
Subscription
Print journal
E-mail Alert
Rss
Feedback
News
Announcement
More
Figure/Table detail
Crystal Material Construction Based on DNA Nanotechnology
Peixin Li, Mushi Peng, Xuehui Yan, Yifan Yu, Ye Tian
Progress in Chemistry
, 2024, 36(
7
): 949-960. DOI:
10.7536/PC240116
Fig. 1
Three important DNA nanotechnology techniques for constructing crystal materials: DNA tiles, programmable atomic equivalents, and DNA origami
Other figure/table from this article
Fig. 2
(a) Archimedean shapes and the DNA tiles composing them
[
19
]
, Copyright © 2013, American Chemical Society; (b) A schematic diagram of a hexagonal lattice composed of “six-pointed star” DNA tiles consisting of three strands
[
6
]
, Copyright © 2006, American Chemical Society; (c) A schematic diagram of DNA tensegrity triangles
[
25
]
; (d) Diamond (R3) and hexagonal (P63) lattices constructed using DNA tensegrity triangles
[
10
]
, Copyright © 2021, American Chemical Society.
Fig. 3
(a) Schematic diagram of PAE composition and crystal structure
[
31
]
, Copyright © 2022 Wiley‐VCH GmbH; (b) Programmed assembly of gold nanoparticles DNA conjugates into different crystal arrangements by changing the sequence of DNA linkers
[
60
]
, Copyright © 2013 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim; (c) Lattice contraction and expansion caused by pH changes
[
40
]
, Copyright © 2018, American Chemical Society; (d) Four colloidal crystal alloy equivalents composed of EEs and PAE
[
61
]
, Copyright © 2019, American Chemical Society
Fig. 4
(a) The invention of DNA origami
[
95
]
; (b) Multiple layers of DNA origami form a honeycomb lattice
[
96
]
,Copyright © 2020, Springer Nature Switzerland AG; (c) Different DNA origami frameworks self assemble to form a lattice
[
86
]
, Copyright © 2016, Springer Nature Limited; (d) Preparation of Wulff shaped single crystals using DNA origami octahedra
[
94
]
,scale bar:1 μm
