Ion transport properties in the pH-dependent bipolar nanochannels.
bipolarity
ion transport characteristics
model comparison
stability
surface charge
Journal
Electrophoresis
ISSN: 1522-2683
Titre abrégé: Electrophoresis
Pays: Germany
ID NLM: 8204476
Informations de publication
Date de publication:
Dec 2023
Dec 2023
Historique:
revised:
05
06
2023
received:
17
04
2023
accepted:
20
06
2023
medline:
4
12
2023
pubmed:
4
7
2023
entrez:
4
7
2023
Statut:
ppublish
Résumé
In recent years, researchers have made significant strides in understanding the ion transport characteristics of nanochannels, resulting in the development of various materials, modifications, and shapes of nano ion channel membranes. The aim is to create a nanochannel membrane with optimal ion transport properties and high stability by adjusting factors, such as channel size, surface charge, and wettability. However, during the nanochannel film fabrication process, controlling the geometric structures of nanochannels can be challenging. Therefore, exploring the stability of nanochannel performance under different geometric structures has become an essential aspect of nanochannel design. This article focuses on the study of cylindrical nanochannel structures, which are categorized based on the different methods for generating bipolar surface charges on the channel's inner surface, either through pH gradient effects or different material types. Through these two approaches, the study designed and analyzed the stability of ion transport characteristics in two nanochannel models under varying geometric structures. Our findings indicate that nanochannels with bipolar properties generated through pH gradients demonstrate more stable ion selection, whereas nanochannels with bipolar properties generated through different materials show stronger stability in ion rectification. This conclusion provides a theoretical foundation for future nanochannel designs.
Identifiants
pubmed: 37401641
doi: 10.1002/elps.202300073
doi:
Substances chimiques
Ion Channels
0
Types de publication
Journal Article
Langues
eng
Sous-ensembles de citation
IM
Pagination
1847-1858Subventions
Organisme : National Key R&D Program of China
ID : 2022YFB3805900
Organisme : National Key R&D Program of China
ID : 2022YFB3805904
Organisme : National Natural Science Foundation of China
ID : 52075138
Organisme : National Natural Science Foundation of China
ID : 61964006
Organisme : Hainan Province Science and Technology Special Fund
ID : ZDYF2022SHFZ301
Organisme : Hainan Province Science and Technology Special Fund
ID : ZDYF2022SHFZ033
Informations de copyright
© 2023 Wiley-VCH GmbH.
Références
Wager B, Baslé A, Delcour AH. Disulfide bond tethering of extracellular loops does not affect the closure of OmpF porin at acidic pH. Proteins. 2010;78:2886-94.
Gouaux E, Mackinnon R. Principles of selective ion transport in channels and pumps. Science. 2005;310:1461-5.
Kudr J, Skalickova S, Nejdl L, Moulick A, Ruttkay-Nedecky B, Adam V, et al. Fabrication of solid-state nanopores and its perspectives. Electrophoresis. 2015;36:2367-79.
Siwy ZS, Howorka S. Engineered voltage-responsive nanopores. Chem Soc Rev. 2010;39:1115.
Xiao K, Wen LP, Jiang L. Biomimetic solid-state nanochannels: from fundamental research to practical applications. Small. 2016;12:2810-31.
Movahed S, Li D. Electrokinetic transport through nanochannels. Electrophoresis. 2011;32:1259-67.
Yuan Z, Garcia AL, Lopez GP, Petsev DN. Electrokinetic transport and separations in fluidic nanochannels. Electrophoresis. 2007;28:595-610.
Alizadeh A, Hsu WL, Wang M, Daiguji H. Electroosmotic flow: from microfluidics to nanofluidics. Electrophoresis. 2021;42:834-68.
Daiguji H. Ion transport in nanofluidic channels. Chem Soc Rev. 2010;39:901-11.
Plett T, Le Thai M, Cai J, Vlassiouk I, Penner RM, Siwy ZS. Ion transport in gel and gel-liquid systems for LiClO4-doped PMMA at the meso- and nanoscales. Nanoscale. 2017;9:16232-43.
White HS, Bund A. Ion current rectification at nanopores in glass membranes. Langmuir. 2008;24:2212-8.
Woermann D. Electrochemical transport properties of a cone-shaped nanopore: high and low electrical conductivity states depending on the sign of an applied electrical potential difference. Phys Chem Chem Phys. 2003;5:1853-8.
Vlassiouk I, Siwy ZS. Nanofluidic diode. Nano Lett. 2007;7:552-6.
Daiguji H, Oka Y, Shirono K. Nanofluidic diode and bipolar transistor. Nano Lett. 2005;5:2274-80.
Lin CY, Wong PH, Wang PH, Siwy ZS, Yeh LH. Electrodiffusioosmosis-induced negative differential resistance in pH-regulated mesopores containing purely monovalent solutions. ACS Appl Mater Interfaces. 2020;12:3198-204.
Hou X, Yang F, Li L, Song YL, Jiang L, Zhu DB. A biomimetic asymmetric responsive single nanochannel. J Am Chem Soc. 2010;132:11736-42.
Xiao K, Chen L, Zhang Z, Xie GH, Li P, Kong XY, et al. A tunable ionic diode based on a biomimetic structure-tailorable nanochannel. Angew Chem Int Ed. 2017;56:8168-72.
Ali M, Ramirez P, Nguyen HQ, Nasir S, Cervera J, Mafe S, et al. Single cigar-shaped nanopores functionalized with amphoteric amino acid chains: experimental and theoretical characterization. ACS Nano. 2012;6:3631-40.
Cheng L-J, Guo LJ. Rectified ion transport through concentration gradient in homogeneous silica nanochannels. Nano Lett. 2007;7:3165-71.
Karnik R, Duan C, Castelino K, Daiguji H, Majumdar A. Rectification of ionic current in a nanofluidic diode. Nano Lett. 2007;7:547-51.
Nguyen G, Vlassiouk I, Siwy ZS. Comparison of bipolar and unipolar ionic diodes. Nanotechnology. 2010;21(8):265301.
Bocquet L, Charlaix E. Nanofluidics, from bulk to interfaces. Chem Soc Rev. 2010;39:1073-95.
Cheng LJ, Guo LJ. Nanofluidic diodes. Chem Soc Rev. 2010;39:923-38.
Guo W, Tian Y, Jiang L. Asymmetric ion transport through ion-channel-mimetic solid-state nanopores. Acc Chem Res. 2013;46:2834-46.
Hou X, Zhang HC, Jiang L. Building bio-inspired artificial functional nanochannels: from symmetric to asymmetric modification. Angew Chem Int Ed. 2012;51:5296-307.
He Y, Gillespie D, Boda D, Vlassiouk I, Eisenberg RS, Siwy ZS. Tuning transport properties of nanofluidic devices with local charge inversion. J Am Chem Soc. 2009;131:5194-202.
Vlassiouk I, Kozel TR, Siwy ZS. Biosensing with nanofluidic diodes. J Am Chem Soc. 2009;131:8211-20.
Ma L, Li ZW, Yuan ZS, Huang CZ, Siwy ZS, Qiu YH. Modulation of ionic current rectification in ultrashort conical nanopores. Anal Chem. 2020;92:16188-96.
Lin C-Y, Yeh L-H, Hsu J-P, Tseng S. Regulating current rectification and nanoparticle transport through a salt gradient in bipolar nanopores. Small. 2015;11:4594-602.
Xiao K, Xie GH, Zhang Z, Kong XY, Liu Q, Li P, et al. Enhanced stability and controllability of an ionic diode based on funnel-shaped nanochannels with an extended critical region. Adv Mater. 2016;28:3345-50.
Xiao K, Li P, Xie GH, Zhang Z, Wen LP, Jiang L. Fabrication and ionic transportation characterization of funnel-shaped nanochannels. RSC Adv. 2016;6:55064-70.
Lin C-Y, Hsu J-P, Yeh L-H. Rectification of ionic current in nanopores functionalized with bipolar polyelectrolyte brushes. Sens Actuators B: Chem. 2018;258:1223-9.
Nasir S, Ali M, Ramirez P, Gomez V, Oschmann B, Muench F, et al. Fabrication of single cylindrical Au-coated nanopores with non-homogeneous fixed charge distribution exhibiting high current rectifications. ACS Appl Mater Interfaces. 2014;6:12486-94.
Chang CW, Chu CW, Su YS, Yeh LH. Space charge enhanced ion transport in heterogeneous polyelectrolyte/alumina nanochannel membranes for high-performance osmotic energy conversion. J Mater Chem A. 2022;10:2867-75.
Gao MY, Zheng MJ, El-Mahdy AFM, Chang CW, Su YC, Hung WH, et al. A bioinspired ionic diode membrane based on sub-2 nm covalent organic framework channels for ultrahigh osmotic energy generation. Nano Energy. 2023;105(11):108007.
Fauziah AR, Chu CW, Yeh LH. Engineered subnanochannel ionic diode membranes based on metal-organic frameworks for boosted lithium ion transport and osmotic energy conversion in organic solution. Chem Eng J. 2023;452(8):139244.
Hsu JP, Su TC, Peng PH, Hsu SC, Zheng MJ, Yeh LH. Unraveling the anomalous surface-charge-dependent osmotic power using a single funnel-shaped nanochannel. ACS Nano. 2019;13:13374-81.
Zhang D, Zhou SQ, Liu Y, Fan X, Zhang ML, Zhai J, et al. Self-assembled porphyrin nanofiber membrane-decorated alumina channels for enhanced photoelectric response. ACS Nano. 2018;12:11169-77.
Peng PH, Ou Yang HC, Tsai PC, Yeh LH. Thermal dependence of the mesoscale ionic diode: modeling and experimental verification. ACS Appl Mater Interfaces. 2020;12:17139-46.
Ren Q, Chen K, Zhu H, Zhang JF, Qu ZG. Nanoparticle enhanced salinity-gradient osmotic energy conversion under photothermal effect. Energy Convers Manage. 2022;251:115032.
Zhu H, Qu Z, Wang Q, Zhang J. Dimension unification and dominance evaluation of multi-physical parameters for nanochannel-based ionic thermoelectric energy conversion using similarity principle. Energy Convers Manage. 2023;276:116589.
Lin TW, Hsu JP, Lin CY, Tseng S. Dual pH gradient and voltage modulation of ion transport and current rectification in biomimetic nanopores functionalized with a pH-tunable polyelectrolyte. J Phys Chem C. 2019;123:12437-43.
Fleharty ME, van Swol F, Petsev DN. Charge regulation at semiconductor-electrolyte interfaces. J Colloid Interface Sci. 2015;449:409-15.
Trefalt G, Behrens SH, Borkovec M. Charge regulation in the electrical double layer: ion adsorption and surface interactions. Langmuir. 2016;32:380-400.
Zeng ZP, Ai Y, Qian SZ. pH-regulated ionic current rectification in conical nanopores functionalized with polyelectrolyte brushes. Phys Chem Chem Phys. 2014;16:2465-74.
Gao M, Tsai PC, Su YS, Peng PH, Yeh LH. Single mesopores with high surface charges as ultrahigh performance osmotic power generators. Small. 2020;16:2006013.
Chang CC, Yeh CP, Yang RJ. Ion concentration polarization near microchannel-nanochannel interfaces: effect of pH value. Electrophoresis. 2012;33:758-64.
Ramon GZ, Feinberg BJ, Hoek EMV. Membrane-based production of salinity-gradient power. Energy Environ Sci. 2011;4:4423-34.
Xin WW, Zhang Z, Huang XD, Hu YH, Zhou T, Zhu CC, et al. High-performance silk-based hybrid membranes employed for osmotic energy conversion. Nat Commun. 2019;10(10):3876.
Su Y-S, Hung W-H, Fauziah AR, Siwy ZS, Yeh L-H. A pH gradient induced rectification inversion in asymmetric nanochannels leads to remarkably improved osmotic power. Chem Eng J. 2023;456:141064.
Peng Y, Zhou T, Li T, Shi L, Wen L. The polarization reverse of diode-like conical nanopore under pH gradient. SN Appl Sci. 2020;2:1932.
Liu Z, Liu X, Wang Y, Yang D, Li C. Ion current rectification in asymmetric charged bilayer nanochannels. Electrochim Acta. 2022;403:139706.
Hiemstra T, Yong H, Van Riemsdijk WH. Interfacial charging phenomena of aluminum (hydr)oxides. Langmuir. 1999;15:5942-55.
Bickmore B, Rosso K, Tadanier C, Bylaska E, Doud D. Bond-valence methods for pKa prediction. II. Bond-valence, electrostatic, molecular geometry, and solvation effects. Geochim Cosmochim Acta. 2006;70:4057-71.
Yeh L-H, Chen F, Chiou Y-T, Su Y-S. Anomalous pH-dependent nanofluidic salinity gradient power. Small. 2017;13:1702691.