Design of capillary flows with functionally graded porous titanium oxide films fabricated by anodization instability

Journal of Colloid and Interface Science

Volumn 423, Issue , 2014, Pages 143-150

  Joung, Young Soo ^a   Figliuzzi, Bruno Michel ^a   Buie, Cullen R ^a  

^a Massachusetts Institute of Technology Cambridge   (United States)

Author keywords

Anodization; Breakdown; Capillary rise; Graded structure; Superhydrophilic; Titanium oxide; Washburn equation

Indexed keywords

CAPILLARY TUBES; ELECTRIC FIELDS; ELECTROLYTES; EQUATIONS OF MOTION; FABRICATION; OXIDE FILMS; SURFACE MORPHOLOGY; TITANIUM; TITANIUM OXIDES;

ANODIZATIONS; BREAKDOWN; CAPILLARY RISE; GRADED STRUCTURE; SUPER-HYDROPHILIC; WASHBURN EQUATION;

CAPILLARITY;

ELECTROLYTE; NANOMATERIAL; TITANIUM DIOXIDE; TITANIUM;

ACIDITY; ARTICLE; BREAKDOWN ANODIZATION; CAPILLARY DIFFUSIVITY; CAPILLARY FLOW; CAPILLARY HEIGHT; CAPILLARY PRESSURE; CAPILLARY TUBE; CONTACT ANGLE; ELECTRIC FIELD; ELECTRIC POTENTIAL; ELECTROCHEMISTRY; ELECTRODE; EVAPORATION; LOW TEMPERATURE; NANOTECHNOLOGY; PAPER CHROMATOGRAPHY; POROSITY; PRIORITY JOURNAL; SCANNING ELECTRON MICROSCOPY; SURFACE PROPERTY; SURFACE TENSION; THEORETICAL MODEL; WASHBURN EQUATION; ZETA POTENTIAL; CHEMISTRY; ELECTROCHEMICAL ANALYSIS; EQUIPMENT DESIGN; FLOW KINETICS; MICROTECHNOLOGY; WETTABILITY;

ELECTROCHEMICAL TECHNIQUES; ELECTRODES; EQUIPMENT DESIGN; MICROTECHNOLOGY; NANOSTRUCTURES; POROSITY; RHEOLOGY; TITANIUM; WETTABILITY;

EID: 84896476339     PISSN: 00219797     EISSN: 10957103     Source Type: Journal    
DOI: 10.1016/j.jcis.2014.02.032     Document Type: Article

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