论文成果
- [1] 裘英华. High-performance nanofluidic osmotic power generation enabled by exterior surface charges under the natural salt gradient. JOURNAL OF POWER SOURCES, 229637, 2021.
- [2] 裘英华. Electrochemical Generation of Individual Nanobubbles Comprising H2, D2, and HD. LANGMUIR, 6073, 2020.
- [3] 裘英华. Modulation of Ionic Current Rectification in Ultrashort Conical Nanopores. ANALYTICAL CHEMISTRY, 16188, 2020.
- [4] 马龙. Significantly Enhanced Performance of Nanofluidic Osmotic Power Generation by Slipping Surfaces of Nanopores. The Journal of Physical Chemestry C, 125, 14195, 2021.
- [5] 马龙. High-performance nanofluidic osmotic power generation enabled by exterior surface charges under the natural salt gradient. JOURNAL OF POWER SOURCES, 492, 2021.
- [6] 裘英华. Modulation of Ionic Current Rectification in Ultrashort Conical Nanopores. Analytical Chemistry, 92, 16188, 2020.
- [7] 马龙. Modulation of Ionic Current Rectification in Ultrashort Conical Nanopores. ANALYTICAL CHEMISTRY, 92, 16188, 2020.
- [8] 裘英华. Prewetting Polypropylene-Wood Pulp Fiber Composite Nonwoven Fabric for Oil–Water Separation. ACS Applied Materials & Interfaces, 46923, 2020.
- [9] Yuan, Zhishan. Prewetting Polypropylene-Wood Pulp Fiber Composite Nonwoven Fabric for Oil-Water Separation. ACS Applied Materials & Interfaces, 12, 46923, 2020.
- [10] 裘英华. Optimal Voltage for Nanoparticle Detection with Thin Nanopores. Analyst, 2018.
- [11] 裘英华. Abnormal Ionic-Current Rectification Caused by Reversed Electroosmotic Flow under Viscosity Gradients across Thin Nanopores. ANALYTICAL CHEMISTRY, 2019.
- [12] 裘英华. Effects of Surface Trapping and Contact Ion Pairing on Ion Transport in Nanopores. The Journal of Physical Chemestry C, 2019.
- [13] 裘英华. Highly Charged Particles Cause a Larger Current Blockage in Micropores Compared to Neutral Particles. ACS nano, 2016.
- [14] 裘英华. Viscosity and Conductivity Tunable Diode-like Behavior for Meso- and Micropores. The Journal of Physical Chemistry Letters , 2017.
- [15] 裘英华. Probing Charges on Solid-Liquid Interfaces with the Resistive-Pulse Technique. Nanoscale, 2017.
- [16] 裘英华. High-performance nanofluidic osmotic power generation enabled by exterior surface charges under the natural salt gradient. Journal of Power Sources, 492, 229637, 2021.
- [17] 裘英华. Experimental Investigation of Dynamic Deprotonation/Protonation of Highly Charged Particles. The Journal of Physical Chemestry C, 2017.
- [18] 裘英华. Direction Dependence of Resistive-Pulse Amplitude in Conically Shaped Mesopores. Analytical Chemistry, 2016.
- [19] 裘英华. Role of Particle Focusing in Resistive-Pulse Technique: Direction-Dependent Velocity in Micropores. ACS nano, 2016.
- [20] 裘英华. Ionic Behavior in Highly Concentrated Aqueous Solutions Nanoconfined between Discretely Charged Silicon Surfaces. LANGMUIR, 2016.