Reversing the ion transport selectivity through arm modification of an artificial molecular hourglass

文献情報

出版日 2023-11-17

DOI 10.1039/D3CC04573K

インパクトファクター 6.222

著者

Wen-Long Huang, Xu-Dong Wang

原文を見る

要旨

An arm modification strategy, by replacing relatively rigid, electron-deficient side arms with flexible ether chain arms and linking them onto a tetraoxacalix[2]arene[2]triazine skeleton, was utilized to design an artificial molecular hourglass. The planar bilayer experiments confirmed the unimolecular channel mechanism and suggested reversed ion selectivity from the previously reported anion selectivity to weak cation selectivity.

掲載誌

Chemical Communications

CiteScore: 8.6

自己引用率: 4.7%

年間論文数: 2458

ChemComm publishes urgent research which is of outstanding significance and interest to experts in the field, while also appealing to the journal’s broad chemistry readership. Our communication format is ideally suited to short, urgent studies that are of such importance that they require accelerated publication. Our scope covers all topics in chemistry, and research at the interface of chemistry and other disciplines (such as materials science, nanoscience, physics, engineering and biology) where there is a significant novelty in the chemistry aspects. Major topic areas covered include: Analytical Chemistry Catalysis Chemical Biology and medicinal chemistry Computational Chemistry and Machine Learning Energy and sustainable chemistry Environmental Chemistry Green Chemistry Inorganic Chemistry Materials Chemistry Nanoscience Organic Chemistry Physical Chemistry Polymer Chemistry Supramolecular Chemistry

Reversing the ion transport selectivity through arm modification of an artificial molecular hourglass

文献情報

おすすめジャーナル

関連文献

A nickel hydroxide-coated 3D porous graphene hollow sphere framework as a high performance electrode material for supercapacitors

A donor–acceptor pair for the real time study of vibrational energy transfer in proteins

Photochemistry of a 1 : 1 hydrogen-bonded CH3CN : HCOOH complex under astrochemically-relevant conditions

Highly porous structure strategy to improve the SnO2 electrode performance for lithium-ion batteries

Adsorption studies of a phosphonic acid on ITO: film coverage, purity, and induced electronic structure changes

Electron impact induced anion production in acetylene

Absolute thermodynamic properties of molten salts using the two-phase thermodynamic (2PT) superpositioning method

The strong catalytic effect of Pb(ii) on the oxygen reduction reaction on 5 nm gold nanoparticles

The formation of carbamate ions in interstellar ice analogues

Insights into mechanical compression and the enhancement in performance by Mg(OH)2 coating in flexible dye sensitized solar cells

こちらもおすすめ

3-イチチルビフェニルはどのように合成されますか？

8-溴-5-三氟甲基喹啉はどのように合成されますか？

ジメチル4-(4,4,5,5-テトラメチル-1,3,2-ドioxaborolan-2-基)-2,6-ピリジンジカルボイル酸フェニルアミニドの代替品はありますか？

N-(3,5-ヘキサクロロ-4-ピリドインイル)-8-メチオキシ-5-キノリンカーボン酸の市場動向や研究トレンドはどのようなものでしょうか？

イソステアロイルグリセリルは安全ですか？

1-(二苯甲基)-3,3-二氟-氮杂环丁烷の市場動向や研究トレンドはどうですか？

3-チオフェンスチオールの物理化学的性質は何ですか？

2-Methyl-2-propanyl (2S)-2-(aminomethyl)-1-piperidinecarboxylateは安全ですか？

CAS番号1316822-90-8の化合物は安全ですか？

Tert-butyl 2-(2-羟基乙基)哌嗪-1-羧酸はどのように保存すればよいですか？

掲載誌

Chemical Communications

おすすめ化合物

N-{[(2-Methyl-2-propanyl)oxy]carbonyl}-L-methionylglycine

6-Ethoxy-2-pyridinecarbaldehyde

N-Methyl-3-(1-naphthyloxy)-3-(2-thienyl)-1-propanamine hydrochloride (1:1)

5-Iodo-4,6-dimethyl-2-pyrimidinamine

5'-Fluoro-[2,3'-biindolinylidene]-2',3-dione

おすすめサプライヤー