Surface-dominated physicochemical phenomena assume a pivotal role in mediating the migration of fluids and suspended or dissolved solutes within nanopores, exhibiting exquisite sensitivity to external stimuli. These nanofluidic phenomena propel not only the fluids themselves but also transport dissolved solutes. Activating nanopores provides precise control of dissolved solutes by modulating the nanopore’s characteristics, such as pore dimensions and surface properties. The solutes encompass nanometer-scale colloids and highly diffusive molecules in diverse configurations, spanning biomolecular to engineered materials. Nanofluidic actuation — encompassing gating, accumulation, and pumping mechanisms — offers both fundamental and advanced methods of microfluidic manipulation. Gating provides foundational controllability over fluidic transport through on-off switching. Accumulation proves a tool to manage low-concentration solutes for targeted ion detection and sample pre-concentration. Meanwhile, the ion pump is utilized to heighten concentration differences of diffusive molecules. These nanofluidic actuations offer the robustness and versatility of fluidic devices, enriching their unique functions and applications. Microfluidics predominantly favors liquid-only systems due to their viscosity-driven benefits. However, the extension of microfluidics with the gas phase overcomes its traditional liquid-centric precepts, embracing a more expansive understanding of "fluid." Incorporating gases into microfluidics involves trade-offs between durable operation and effective transport. However, phase separation in membrane-integrated microfluidic devices enables various functions in both durable and effective manners. These functions enrich versatilities across multiple fields, including biology, chemistry, and physics. The primary objective of this research is to explore an innovative approach for manipulating small molecules and colloids within a microfluidic chip using liquid-gas interphase transport mechanisms. The improvement of precision and labor-efficiency could lead to significant advancements. Spontaneous processes such as pervaporation and diffusion are designed in a guided manner to achieve improvements without relying on external energy sources. Therefore, the primary focus is on designing and fabricating a membrane-integrated microfluidic device. Nanostructures are further integrated to obtain the capability of molecular and colloidal manipulation. The devices are utilized for various purposes depending on the target. First, pervaporation is utilized to control the transport of small molecules along nanoslits. The local and independent switching of humidity conditions near nanoslits facilitates the concentration, separation, and actuation of small molecules. Pervaporation-induced flow of solvent and diffusion of small molecules along nanoslits are analyzed via fluorescent signals and theoretical modeling simultaneously to investigate critical parameters. These parameters are concluded to provide insightful control of small molecules. Second, a pervaporation-assisted method for fabricating a particle assembly membrane (PAM) is developed. The concentrating property of pervaporation-induced flow is utilized to in-situ assemble sub-micron to nano-sized particles in microchannels. The assembled particles containing nanopore networks serve as nanoporous membranes. Forced assembly due to liquid flow enables the adoption of various types of particles in terms of size, surface functionality, and wettability. Furthermore, the heterogeneous structure in parallel and serial configurations offers possibilities for numerous applications. Third, gas dissolution is employed to modulate the functions of ionic diodes. Asymmetrically charged heterogeneous PAMs serve as ionic diodes. A control channel is placed in the middle of the ionic diode to supply gas molecules through diffusion via a gas-permeable film. Gases and gas- dissolved solutions are introduced to construct a concentration gradient in a switchable and programmable manner. The diodes exhibit different responses to bias when gas is supplied from the control channel, resulting in the modulation of rectification ratios. Several demonstrations are also conducted, including chemical reactions in an accumulated state and ion signal amplification. In summary, the methods of fabrication and control serve as the basis for designing liquid-gas interphase transport in an on-chip manner. Furthermore, this research accelerates molecular, colloidal, and ionic manipulation in microfluidic devices, thereby enriching micro/nanofluidics and various fields. Spontaneous working mechanisms, especially, enhance the key value of microfluidics, offering low cost and portability. A wide range of target molecules enables the development of multi-functional devices for practical applications, such as cell culture, chemical reactions/sensing, and colloidal delivery.

• ABSTRACT . I
• Table of Contents III
• List of Figures V
• Nomenclature XVI
• Chapter 1: Introduction
• 1-1. Nanofluidic Actuations for Molecular/Colloidal Transport Control . 1
• 1-2. Multiphasic Intermembrane Transports in Microfluidics 5
• 1-3. Basic Transport Mechanisms of Gas Transport in Microfluidics. 11
• 1-4. Overview of dissertation 14
• Chapter 2: Pervaporation-induced Nanoslits Actuation for Controlling Transport of Small Molecules
• 2-1. Introduction . 16
• 2-2. Methods . 17
• 2-3. Results 21
• 2-4. Conclusion 34
• Chapter 3: Nanoparticle Accumulation via Pervaporation-induced Flow for Fabricating Nanoporous Membrane
• 3-1. Introduction . 36
• 3-2. Methods . 38
• 3-3. Results 42
• 3-4. Conclusion 56
• Chapter 4: Gas-madidate Surface Modification of Nanopores for Modulating Ionic Diode
• 4-1. Introduction . 57
• 4-2. Methods . 58
• 4-3. Results 61
• 4-4. Conclusion 76
• Chapter 5: Conclusion and perspective 78
• REFERENCES . 82
• Acknowledgement . 97

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137. Biomimetic solidstate nanochannels for chemical and biological sensing applications, O. Azzaroni, W. Marmisollé and, C. Trautmann, V. Cayón, M. L. Cortez, M. E. ToimilMolares, Y. Toum Terrones, G. Laucirica, TrAC, Trends Anal. Chem. 144, , 2021

138. Electrostatic Charge and ElectricFieldInduced Smart Gating for Water Transportation, G. Xie, L. Wen and, X. Y. Kong, P. Li, Y. Zhou, K. Xiao, Z. Zhang, L. Jiang, 10 (10), 97039709, , 2016

139. Micro/Nanofluidics for LiquidMediated Patterning of HybridScale Material Structures, J. Bae, J. Lee, T. Kim, Q. Zhou and, 31 (20), e1804953, , 2019

140. Nanoparticleblockageenabled rapid and reversible nanopore gating with tunable memory, T. Porter and, Y. Xu, C. Duan, R. Yazbeck, 119 (27), e2200845119, , 2022

141. Evaluation of porosity and thickness on effective diffusivity in gas diffusion layer,, F. Chen, Y. Gao, A. Montana and, 342, 252265, , 2017

142. Gas diffusion as a new fluidic unit operation for centrifugal microfluidic platforms,, N. Sandez, M. Puyol and, J. AlonsoChamarro, O. Ymbern, A. CalvoLopez, 14 (5), 1014 1022, , 2014

143. MixedGas Selectivity Based on Pure Gas Permeation Measurements: An Approximate Model,, A. O. Malakhov and, V. V. Volkov, 11 (11), 833, , 2021

144. Laser assisted microfluidic membrane evaporator for sample crystallization separation,, X. Zhu, R. Chen, X. He, Q. Liao and, S. Li, 242, 116817, , 2020

145. A review of electrolyte materials and compositions for electrochemical supercapacitors,, J. Qiao, C. Zhong, W. Hu, L. Zhang and, J. Zhang, Y. Deng, 44 (21), 74847539, , 2015

146. Nanofluidic memristor by elastic deformation of nanopores with nanoparticles adsorption,, M. Sun, Y. Zong, Y. Wang, W. Wang, D. Shi, Y. Xie, X. Zhou, G. Du and, 2023, , 2023

147. A bubble and cloggingfree microfluidic particle separation platform with multifiltration,, Y. Wang, X. Ye, Y. Cheng, W. Wang and, Z. Ma, 16 (23), 45174526, , 2016

148. A tensorial approach to computational continuum mechanics using objectoriented techniques, C. Fureby, H. Jasak and, H. G. Weller, G. Tabor, 12 (6), , 1998

149. Crackingassisted photolithography for mixedscale patterning and nanofluidic applications,, M. Kim, D. Ha and, T. Kim, 6, 6247, , 2015

150. Ultrasensitive detection of circulating exosomes with a 3Dnanopatterned microfluidic chip, A. K. Godwin and, M. He, Y. Zeng, X. Zhou, Y. Shang, A. L. Tetlow, P. Zhang, 3 (6), 438451, , 2019

151. Giant osmotic energy conversion measured in a single transmembrane boron nitride nanotube,, R. Fulcrand, X. Blase, A. Siria, P. Poncharal, L. Bocquet, A.L. Biance, S. T. Purcell and, 494, 455, , 2013

152. Study of the mechanism of embolism removal in xylem vessels by using microfluidic devices,, C. Liu and, L. Liu, J. Li, P. Yin, Y. Liu, L. Guo, 23 (4), 737747 (2023, , 2023

153. Liquidbased gating mechanism with tunable multiphase selectivity and antifouling behaviour,, J. Aizenberg, M. Khan and, Y. Hu, X. Hou, A. Grinthal, 519, 70, , 2015

154. Multiphase flow in microfluidics: From droplets and bubbles to the encapsulated structures,, M. Hoorfar, P. Hanafizadeh and, A. Sattari, 282, 102208, , 2020

155. Oxygen control: the often overlooked but essential piece to create better in vitro systems,, V. PalacioCastaneda, S. Le Gac and, W. P. R. Verdurmen, N. Velthuijs, 22 (6), 10681092, , 2022

156. Progress of Microfluidic Continuous Separation Techniques for Micro/Nanoscale Bioparticles,, B. Kim and, M. Kim, S. W. Choe, 11 (11), , 2021

157. Measurements of diffusion coefficients in 1D micro and nanochannels using sheardriven flows,, K. Pappaert, S. Vankrunkelsven and, J. Biesemans, G. Desmet, D. Clicq, 5 (10), 11041110, , 2005

158. Steady microfluidic measurements of mutual diffusion coefficients of liquid binary mixtures,, J. B. Salmon, C. Loussert and, A. Bouchaudy, 64 (1), 358366, , 2017

159. pHmodulated selfassembly of colloidal nanoparticles in a dualdroplet inkjet printing process, K. N. AlMilaji, P. Kamerkar and, H. Zhao, V. Radhakrishnan, 529, 234242, , 2018

160. High Current Ionic Diode Using Homogeneously Charged Asymmetric Nanochannel Network Membrane,, C. Wang, G. T. Chang and, E. Choi, J. Park, 16 (4), 21892197, , 2016

161. A numerical study on desalination performance enhancement by bipolar ionic diode nanochannels,, J. Wang and, T. Li, R. Peng, L. Guo, C. Wang, Y. Song, T. Zhang, M. Xu, 566 (2023, , 2023

162. Carbon nanotubes in microfluidic labonachip technology: current trends and future perspectives, A. R. Aref, H. Zare, A. Hasanzadeh, A. Ghasemi, M. Masroor, M. R. Hamblin, A. Beyzavi, M. Karimi and, H. Amiri, Microfluid Nanofluid 21 (9), , 2017

163. A LowCost, Rapidly Integrated Debubbler (RID) Module for Microfluidic Cell Culture Applications, A. Ahmed and, N. Mazzola, J. A. Mylott, V. V. Abhyankar, N. K. Lee, M. J. Williams, Micromachines (Basel) 10 (6), 360, , 2019

164. Flow chemistry: intelligent processing of gasliquid transformations using a tubeintube reactor,, M. Brzozowski, S. V. Ley and, A. Polyzos, M. O'Brien, 48 (2), 349362, , 2015

165. NanochannelAssisted Perovskite Nanowires: From Growth Mechanisms to Photodetector Applications,, T. Kim, R. Nie, J. G. Park, Q. Zhou, J. Pan, S. I. Seok and, D. Ha, A. K. Thokchom, 12 (8), 84068414, , 2018

166. Recent advances in microfluidic chip integrated electronic biosensors for multiplexed detection, Y. Deng and, Z. Liao, Y. Miao, Y. Zhang, L. Geng, S. Gao, J. Wang, P. Zhang, 121, 272280, , 2018

167. Solidification of a Charged Colloidal Dispersion Investigated Using Microfluidic Pervaporation,, J. B. Salmon, N. Ziane and, 31 (29), 79437952, , 2015

168. Aptamerfunctionalized microtubules for continuous and selective concentration of target analytes, T. Kim, M. Kim and, 202, 12291236, , 2014

169. Asymmetric Nanochannel Network Based Bipolar Ionic Diode for Enhanced Heavy Metal Ion Detection,, J. Kim, C. Wang, J. Park, J. Jeon, G. T. Chang and, 16 (5), 8253 8263, , 2022

170. Automatic concentration and reformulation of PET tracers via microfluidic membrane distillation,, J. Collins, R. Michael van Dam, J. T. Lee and, W. Y. Tseng, P. H. Chao, J. P. Argus, Lab Chip 17 (10), 18021816, , 2017

171. Eliminating air bubble in microfluidic systems utilizing integrated inline sloped microstructures, J. A. Wippold, A. Han, D. StratisCullum and, C. Huang, Biomed. Microdevices 22 (4), 76, , 2020

172. OpenFOAM Computational Fluid Dynamic Simulations of SinglePhase Flows in an AdvancedFlow Reactor,, A. A. Kulkarni and, K. F. Jensen, M. J. NievesRemacha, 54 (30), 75437553, , 2015

173. MicrofluidicBased Oxygen (O(2)) Sensors for OnChip Monitoring of Cell, Tissue and Organ Metabolism, M. Amereh, M. Hoorfar and, P. Khashayar, M. Akbari, N. Tasnim, M. Azimzadeh, 12 (1), 6, , 2021

174. Modelling Sorption and Transport of Gases in Polymeric Membranes across Different Scales: A Review, M. Minelli and, M. G. De Angelis, E. Ricci, 12 (9), 857, , 2022

175. Multiplexed proteomic sample preconcentration device using surfacepatterned ionselective membrane,, J. Han, J. H. Lee, Y. A. Song and, 8 (4), 596601, , 2008

176. Performance study of pervaporation in a microfluidic system for the removal of acetone from water,, N. E. Benes and, Y. Zhang, R. G. H. Lammertink, 284, 13421347, , 2016

177. Dynamic Transport Control of Colloidal Particles by Repeatable Active Switching of Solute Gradients,, S. Seo, T. Kim, K. Lee and, D. Ha, 13 (11), 1293912948, , 2019

178. Highvoltage nanofluidic energy generator based on ionconcentration gradients mimicking electric eels, E. Choi and, J. Park, C. Wang, 43, 291299, , 2018

179. Effective diffusivity and watersaturation distribution in single and twolayer PEMFC diffusion medium,, M. Kaviany, J. H. Nam and, 46 (24), 4595 4611, , 2003

180. Mimicking how plants control CO2 influx: CO2 activation of ion current rectification in nanochannels,, J. Jiang, M. Zhang, Z. Meng, Y. Wang, J. Zhai and, Y. Xu, Y. Shang, T. Tian, 7 (9), e215e215, , 2015

181. Recent advances for serial processes of hazardous chemicals in fully integrated microfluidic systems,, D.P. Kim, A. K. Singh and, R. Singh, H.J. Lee, 33 (8), 22532267, , 2016

182. Continuous in situ generation, separation, and reaction of diazomethane in a dualchannel microreactor,, R. A. Maurya, D. P. Kim, J. H. Lee and, C. P. Park, 50 (26), 59525955, , 2011

183. Flexible GlassBased Hybrid Nanofluidic Device to Enable the Active Regulation of SingleMolecule Flows,, Y. Xu, Y. Tanaka and, S. I. Funano, H. Kawagishi, 23 (6), 22102218 (2023), , 2023

184. Salt stressinduced Ca 2+ waves are associated with rapid, longdistance roottoshoot signaling in plants,, M. Toyota, S.H. Kim, W.G. Choi, R. Hilleary and, S. Gilroy, 111 (17), 64976502, , 2014

185. Water permeability and competitive permeation with CO 2 and CH 4 in perfluorinated polymeric membranes,, S. E. Kentish, S. Kanehashi, G. W. Stevens and, C. A. Scholes, 147, 203209, , 2015

186. Control of Nanopore Wetting by a Photochromic Spiropyran: A LightControlled Valve and Electrical Switch,, S. A. Vail, I. Vlassiouk, C.D. Park, D. Gust and, S. Smirnov, 6 (5), 10131017, , 2006

187. Fabrication of polydimethylsiloxane (PDMS) nanofluidic chips with controllable channel size and spacing,, D. Li, R. Peng and, 16 (19), 37673776, , 2016

188. A low temperature cofired ceramic based microfluidic Clarktype oxygen sensor for realtime oxygen sensing,, J. Luo, R. Eitel, T. Dziubla and, 240, 392 397, , 2017

189. Integration of nanoporous membranes into microfluidic devices: electrokinetic biosample preconcentration,, T. Kim, M. Kim and, 138 (20), 60076015, , 2013

190. Universal lowfrequency asymptotes of dynamic conic nanopore rectification: An ionic nanofluidic inductor,, Y. Yan, J. Schiffbauer, H.C. Chang, G. Yossifon and, 143 (22), , 2015

191. Exceeding ohmic scaling by more than one order of magnitude with a 3D ion concentration polarization system,, J. T. Kim, D. Chen, A. T. Timperman, L. P. Chamorro and, 21 (16), 30943104, , 2021

192. Adsorption of Sulforhodamine Dyes in Cationic Langmuir−Blodgett Films: Spectroscopic and Structural Studies, K. Ray and, H. Nakahara, 106 (1), 92100, , 2001

193. Microfluidic blood oxygenators with integrated hollow chambers for enhanced air exchange from all four sides,, C. Fusch and, N. Saraei, G. Fusch, P. R. Selvaganapathy, M. Dabaghi, N. Rochow, J. L. Brash, 596, 117741, , 2020

194. Steering air bubbles with an addon vacuum layer for biopolymer membrane biofabrication in PDMS microfluidics,, T. Vo and, X. Luo, P. Pham, 17 (2), 248255, , 2017

195. pHdependent aggregation and photoluminescence behavior of thiolcapped CdTe quantum dots in aqueous solutions,, Y. Zhang, P. N. Wang, J. Y. Chen, L. Mi, J. Ma and, 128 (12), 19481951, , 2008

196. Facile construction of gas diode membrane towards in situ gas consumption via coupling two chemical reactions,, A. Gao, Y. Yan, S. Zhao, G. Zhang, J. Cui and, H. Fan, 557, 282290, , 2019

197. AllPolymer BulkHeterojunction Organic Electrochemical Transistors with Balanced Ionic and Electronic Transport,, S. Chen, X. Zhao, X. Wu, T. Salim, T. L. D. Tam, Z. Zhou, Y. L. Loo and, M. Lin, J. Xu, W. L. Leong, 34 (42), e2206118 (2022)., , 2061

198. Biomimetic multifunctional nanochannels based on the asymmetric wettability of heterogeneous nanowire membranes, J. Zhang, P. Wang and, Z. Zhang, Y. Yang, X. Wang, 26 (7), 10711075, , 2014

199. Iontronic analog of synaptic plasticity: Hydrogelbased ionic diode with chemical precipitation and dissolution,, S. H. Han, S. I. Kim, T. D. Chung, M. A. Oh and, 120 (1), e2211442120 (2023), , 2114

200. Tunable reverse electrodialysis microplatform with geometrically controlled selfassembled nanoparticle network,, D. Kim and, E. Choi, K. Kwon, J. Park, 15 (1), 168178, , 2015

201. Experimental and computational study of gas bubble removal in a microfluidic system using nanofibrous membranes,, H. G. Derami, R. Vundavilli and, J. Darabi, 23 (7), 26852698, , 2016

202. Membrane integration into PDMSfree microfluidic platforms for organonchip and analytical chemistry applications,, A. Richter and, D. Gruner, S. Schneider, P. Loskill, 21 (10), 18661885, , 2021

203. Microfluidic Integrated Organic Electrochemical Transistor with a Nanoporous Membrane for Amyloidbeta Detection,, I. McCulloch, S. Inal, V. E. Musteata, M. Moser, S. Wustoni, S. P. Nunes and, A. Koklu, D. Ohayon, 15 (5), 81308141 (2021)., , 2021

204. Passive Transportation of Low Surface Tension Liquids Induced by Patterned Omniphobic Liquidlike Polymer Brushes, K. Golovin Lossless, M. Soltani and, 32 (1), 2107465, , 2021

205. A review on nondispersive infrared gas sensors: Improvement of sensor detection limit and interference correction, T.V. Dinh, J.C. Kim, I.Y. Choi, Y.S. Son and, 231, 529538, , 2016

206. Vacuumdriven powerfree microfluidics utilizing the gas solubility or permeability of polydimethylsiloxane (PDMS),, D. Jetta and, H. Lee, K. W. Oh, L. Xu, 15 (20), 3962 3979, , 2015

207. Measuring and regulating oxygen levels in microphysiological systems: design, material, and sensor considerations,, P. D. Erb, V. A. Pozdin and, K. R. Rivera, M. Daniele, M. A. Yokus, 144 (10), 31903215, , 2019

208. CO2 Intrinsic Product, Essential Substrate, and Regulatory Trigger of Microbial and Mammalian Production Processes, B. Blombach and, R. Takors, Front Bioeng Biotechnol 3, 108, , 2015

209. PDMSfree microfluidic cell culture with integrated gas supply through a porous membrane of anodized aluminum oxide,, F. Bunge, M. J. Vellekoop, S. van den Driesche and, Biomed. Microdevices 20 (4), 98, , 2018

210. Polymers of intrinsic microporosity and thermally rearranged polymer membranes for highly efficient gas separation,, R. Ahmadi, J. C. Jansen and, A. Fuoco, S. Shirazian, H. Sanaeepur, S. Bandehali, A. Ebadi Amooghin, 278, 119513, , 2021

211. Surface Diffusion of Adsorbed Molecules in Porous Media: Monolayer, Multilayer, and Capillary Condensation Regimes,, J.G. Choi, D. D. Do and, H. D. Do, 40 (19), 40054031, , 2001

212. When PDMS isn't the best. What are its weaknesses, and which other polymers can researchers add to their toolboxes?, R. Mukhopadhyay, 79 (9), 32483253, , 2007

213. An electrokinetic study on tunable 3D nanochannel networks constructed by spatially controlled nanoparticle assembly, J. Park, K. Kwon, D. Kim and, E. Choi, 15 (2), 512523, , 2015

214. Peptide Assembled in a Nanoconfined Space as a Molecular Rectifier for the Availability of Ionic Current Modulation,, M. Jalalah, L. Shi, D. Kuang, X. Ma, T. Gao, J. Yang and, S. A. Alsareii, F. A. Harraz, G. Li, 22 (3), 10831090 (2022)., , 2022

215. Pervaporationassisted in situ formation of nanoporous microchannels with various material and structural properties,, J. Bae, S. Seo, H. Jeon, T. Kim, S. Lee and, 22 (8), 14741485, , 2022

216. Exploring Anomalous Fluid Behavior at the Nanoscale: Direct Visualization and Quantification via Nanofluidic Devices,, C. Duan and, D. Sinton, Y. Xu, M. A. Alibakhshi, J. Riordon, J. Zhong, Q. Xie, 53 (2), 347357, , 2020

217. Selfassembled particle membranes for in situ concentration and chemostatlike cultivation of microorganisms on a chip,, J. Lee, T. Kim, M. Kim, J. Park and, Lab Chip 16 (6), 10721080, , 2016

218. Detection and sizing of nanoparticles and DNA on PDMS nanofluidic chips based on differential resistive pulse sensing,, D. Li, R. Peng and, 9 (18), 59645974, , 2017

219. Review of micro/nanofluidic particle separation mechanisms: Toward combined multiple physical fields for nanoparticles, K. Lee, R. Mishra and, T. Kim, Sens. Actuators, A: Phys. 363, , 2023

220. A Magnetic Gated Nanofluidic Based on the Integration of a Superhydrophilic Nanochannels and a Reconfigurable Ferrofluid,, H. Yang and, W. Miao, L. Jiang, H. Wang, D. Wang, Y. Tian, S. Zheng, H. Liu, J. Tang, 31 (7), 1805953, , 2019

221. Numberingup strategies of microchemical process: Uniformity of distribution of multiphase flow in parallel microchannels,, C. Zhu, M. F. Tahir, Q. Shen, T. Fu, C. Zhang, Y. Ma and, S. Jiang, Chem. Eng. Process. Process Intensif. 132, 148159, , 2018

222. Effects of Ionic Strength on the Colloidal Stability and Interfacial Assembly of Hydrophobic Ethyl Cellulose Nanoparticles,, N. Bizmark and, M. A. Ioannidis, 31 (34), 9282 9289, , 2015

223. ZirconiumBased Nanoscale MetalOrganic Framework/Poly(epsiloncaprolactone) MixedMatrix Membranes as Effective Antimicrobials,, M. Liu, Z. Xie, X. Zheng and, L. Wang, 9 (47), 4151241520, , 2017

224. Dynamics of bubble formation in spontaneous microfluidic devices: Controlling dynamic adsorption via liquid phase properties,, K. Schroen and, B. Deng, J. de Ruiter, 622, 218227, , 2022

225. Design, fabrication and performance evaluation of a printedcircuitboard microfluidic electrolytic pump for labonachip devices,, H. Kim, H. Hwang, S. Baek and, D. Kim, 277, 7384, , 2018

226. Effects of heat transfer and the membrane thermal conductivity on the thermally nanofluidic salinity gradient energy conversion,, Z. Luo, Z. Liu and, W. Liu, R. Long, Z. Kuang, 67, 104284, , 2020

227. Hostguest supramolecular chemistry in solidstate nanopores: potassiumdriven modulation of ionic transport in nanofluidic diodes,, G. PerezMitta, W. Knoll, O. Azzaroni, A. G. Albesa, C. Trautmann, M. E. ToimilMolares and, 7 (38), 1559415598 (2015)., , 2015

228. LightRegulated Nanofluidic Ionic Diodes with Heterogeneous Channels Stemming from Asymmetric Growth of Metal Organic Frameworks,, J. Lu, P. Yu, W. Jiang and, Y. Jiang, T. Xiong, L. Mao, 94 (10), 43284334, , 2022

229. The analysis of dissolved inorganic carbon in liquid using a microfluidic conductivity sensor with membrane separation of CO(2),, B. Ward and, D. Sun, P. D. Maguire, M. Tweedie, D. R. Gajula, Microfluid Nanofluid 24 (5), 37, , 2020

230. Wetting, Scaling, and Fouling in Membrane Distillation: StateoftheArt Insights on Fundamental Mechanisms and Mitigation Strategies, Z. Wang, T. Tong and, T. Horseman, S. Lin, Y. Yin, K. S. S. Christie, ACS EST Engg. 1 (1), 117140, , 2020

231. An Experimental and Numerical Study of Polyelectrolyte Hydrogel Ionic Diodes: Towards Electrical Detection of Charged Biomolecules,, R. Zhang and, Y. Liu, C. Xiong, B. Zhang, 21 (24), , 2021

232. Bioinspired Microfluidic Device by Integrating a Porous Membrane and Heterostructured Nanoporous Particles for Biomolecule Cleaning, S. Wang, J. Luo, J. B. Fan, Z. Wang, Y. Song, X. Chen and, S. Zhang, B. Wang, J. Meng, Z. Zheng, Z. Luo, 13, , 2019

233. Rectification of Concentration Polarization in Mesopores Leads To High Conductance Ionic Diodes and High Performance Osmotic Power,, C.Y. Lin, Y.S. Su, Z. S. Siwy, L.H. Yeh and, C. Combs, 141 (8), 36913698, , 2019

234. ContinuousFlow Processing of Gaseous Ammonia Using a Teflon AF2400 TubeinTube Reactor: Synthesis of Thioureas and InLine Titrations,, D. Browne, A. Polyzos and, M. O'Brien, P. Cranwell, S. Ley, P. Koos, 23 (09), 14021406, , 2012

235. Nano and MicroPatterned S, H, and XPDMS for CellBased Applications: Comparison of Wettability, Roughness, and CellDerived Parameters, D. F. Gilbert, T. Dirnecker, O. Friedrich, M. ScharinMehlmann, A. Haring, M. Rommel, L. Frey and, Front Bioeng Biotechnol 6, 51 (2018)., , 2018

236. Inline sample concentration by evaporation through porous hollow fibers and micromachined membranes embedded in microfluidic devices,, H. Zhang, H. Gardeniers, S. Schlautmann, J. Bart and, R. M. Tiggelaar, 37 (3), 463471, , 2016

237. Development of a gasdiffusion microfluidic paperbased analytical device (muPAD) for the determination of ammonia in wastewater samples, I. D. McKelvie and, S. D. Kolev, B. M. Jayawardane, 87 (9), 46214626, , 2015

238. Highly Efficient Gating of Electrically Actuated Nanochannels for Pulsatile Drug Delivery Stemming from a Reversible Wettability Switch, X. Diao, Z. Liu and, J. Zhai, J. Kang, Q. Zhang, Z. Xie, 30 (4), 1703323, , 2018

239. A polymeric microfluidic device integrated with nanoporous alumina membranes for simultaneous detection of multiple foodborne pathogens,, J. Lyu, J. Shi, F. Tian, F. Tan and, M. Yang, 225, 312318, , 2016

240. Single Conical Nanopores Displaying pHTunable Rectifying Characteristics. Manipulating Ionic Transport With Zwitterionic Polymer Brushes,, M. Ali, O. Azzaroni, R. Neumann, W. Knoll and, B. Yameen, W. Ensinger, 131 (6), 20702071, , 2009

241. Single and multifunctional coating strategies for enhancing the biocompatibility and tissue integration of bloodcontacting medical implants, M. Badv, T. F. Didar, J. I. Weitz and, F. Bayat, 258, 120291, , 2020

242. Bubble inclusion and removal using PDMS membranebased gas permeation for applications in pumping, valving and mixing in microfluidic devices,, M. Eddings and, G. Liddiard, B. Gale, M. Johnson, J. Micromech. Microeng. 19 (9), 095011, , 2009

243. On the propagation of concentration polarization from microchannelnanochannel interfaces. Part I: Analytical model and characteristic analysis,, A. Mani, T. A. Zangle and, J. G. Santiago, 25 (6), 38983908, , 2009

244. Flow characterization of electroconvective micromixer with a nanoporous polymer membrane insitu fabricated using a laser polymerization technique,, S. Hwang and, S. Song, 9 (3), 034108, , 2015

245. Characterization and resolution of evaporationmediated osmolality shifts that constrain microfluidic cell culture in poly(dimethylsiloxane) devices,, L. M. Cabrera, J. W. Song, Y. C. Tung, S. Takayama, N. Futai, G. D. Smith and, Y. S. Heo, 79 (3), 11261134 (2007)., , 2007

246. Determining the Partial Pressure of Volatile Components via SubstrateIntegrated Hollow Waveguide Infrared Spectroscopy with Integrated Microfluidics, V. Kokoric, J. Theisen, J. P. Gabriel, G. Bernard, C. Penisson, A. Wilk, B. Mizaikoff and, 90 (7), 4445 4451, , 2018

247. A robust thin film composite membrane incorporating thermally rearranged polymer support for organic solvent nanofiltration and pressure retarded osmosis,, S. H. Park, S. J. Moon, Y. M. Lee, M. Cook, J. H. Kim, A. G. Livingston and, 550, 322331, , 2018

248. Water/gas separation based on the selective bubblepassage effect of underwater superaerophobic and superaerophilic meshes processed by a femtosecond laser,, J. Huo, X. Bai, J. Zhuang, J. Yong, F. Chen, Q. Yang, X. Hou and, 13 (23), 1041410424, , 2021

249. Integrated multilayer microfluidic device with a nanoporous membrane interconnect for online coupling of solidphase extraction to microchip electrophoresis,, Z. Long, B. Lin, Z. Shen, J. Qin and, D. Wu, 7 (12), 18191824, , 2007

250. A Novel Connectivity Factor for Morphological Characterization of Membranes and Porous Media: A Simulation Study on Structures of MonoSized Spherical Particles,, Y. Sun and, M. Grandinetti, G. De Marco, A. Caravella, S. Bellini, G. Azzato, V. Stellato, 8 (4), 573, , 2018

251. Bioinspired Heterogeneous Ion Pump Membranes: Unidirectional Selective Pumping and Controllable Gating Properties Stemming from Asymmetric Ionic Group Distribution,, P. Li, Y. Tian, Z. Zhang, L. Wen and, Y. Qian, X. Y. Kong, G. Xie, L. Jiang, Z. Wang, 140, , 2018

252. A gasdiffusion microfluidic paperbased analytical device (muPAD) coupled with portable surfaceenhanced Raman scattering (SERS): facile determination of sulphite in wines,, X. Chen, H. Yang, M. Chen, L. Rong and, 141 (19), 55115519, , 2016

253. Microfluidic Collective Cell Migration Assay for Study of Endothelial Cell Proliferation and Migration under Combinations of Oxygen Gradients, Tensions, and Drug Treatments, W. H. Liao and, H. C. Shih, T. A. Lee, H. M. Wu, Y. C. Tung, P. L. Ko, 9 (1), 8234, , 2019

254. High performance organic solvent nanofiltration membranes: Development and thorough testing of thin film composite membranes made of polymers of intrinsic microporosity (PIMs), P. Merten, D. Fritsch, M. Priske, M. Lazar and, K. Heinrich, 401402, 222 231, , 2012