Bipolar Electrochemistry: From Materials Science to Motion and Beyond

Loget, Gabriel; Zigah, Dodzi; Bouffier, Laurent; Šojić, Nešo; Kuhn, Alexander

doi:10.1021/ar400039k

Cited by 332 publications

(314 citation statements)

References 61 publications

(141 reference statements)

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“…13 This is consistent with the fact that the D gradient is adjustable with the applied electric field because the polarization potential is proportional to the imposed electric field. 13 The largest tubes, shown in Fig.4b, had a diameter of 180 nm and were obtained for E = 55 V.cm ). These results illustrate that TiO 2 NTs also with a gradient in diameter can be easily fabricated and tailored using bipolar anodization.…”

supporting

confidence: 79%

“…When an electric field is applied between the feeder electrodes, namely an anode at a potential E a and a cathode at a potential E c , a V arises along the surface of the Ti foil. 13 As shown in Fig. 1b, this potential is maximal at the edges of the foil and gradually decreases towards its middle.…”

Section: Introductionmentioning

confidence: 69%

“…If the generated polarization potential is high enough, a fraction of the delivered current flows through the Ti foil, inducing redox reactions along the metal conducting path but most pronounced at its extremities, where the polarization potential is maximum. 13 Reduction happens at the cathodic pole of the Ti foil (the extremity which faces the feeder anode), together with oxidation at the anodic pole (extremity which faces the feeder cathode). Under such conditions the Ti foil behaves at the same time as an anode and a cathode, that is a bipolar electrode.…”

Section: Introductionmentioning

confidence: 99%

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Bipolar anodization enables the fabrication of controlled arrays of TiO₂ nanotube gradients

Loget

Hahn

et al. 2014

J. Mater. Chem. A

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We report here a new concept, the use of bipolar electrochemistry, which allows the rapid and wireless growth of self-assembled TiO 2 NT layers that consist of highly defined and controllable gradients in NT length and diameter. The gradient height and slope can be easily tailored with the time of electrolysis and the applied electric field, respectively. As this technique allows obtaining in one run a wide range of self-ordered TiO 2 NT dimensions, it provides the basis for rapid screening of TiO 2 NT properties. In two examples, we show how these gradient arrays can be used to screen for an optimized photocurrent response from TiO 2 NT based devices such as dye-sensitized solar cells.

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supporting

confidence: 79%

Section: Introductionmentioning

confidence: 69%

Section: Introductionmentioning

confidence: 99%

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Bipolar anodization enables the fabrication of controlled arrays of TiO₂ nanotube gradients

Loget

Hahn

et al. 2014

J. Mater. Chem. A

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“…[28][29][30] Logic computation based on bipolar electrochemistry has attracted tremendous interest recently owing to its ease of construction, integration and control. 25,[31][32][33] Crooks pioneered the integration of logic circuits with a split BPE using electrochemiluminescence as an output signal in an open BPE system.…”

Section: Introductionmentioning

confidence: 99%

Dual-electrochromic bipolar electrode-based universal platform for the construction of various visual advanced logic devices

et al. 2017

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A universal logic platform based on dual-electrochromic bipolar electrodes (BPEs) for the operation of various visual advanced logic devices was designed and constructed for the first time. Two BPEs separated by three reaction channels filled with different reaction solutions constituted the closed BPE system and were used as the initial state. Under different input combinations, the electrochemical oxidation of 2, 2′ -azinobis (3-ethylbenzthiazoline-6-sulfonic acid) and the electrodeposition of Prussian blue occurred at different poles simultaneously and triggered rapid color changes that could be easily visualized by the naked eye. By defining the color changes at the two specific poles as outputs, visual advanced logic devices, including an encoder, a decoder, a demultiplexer, a keypad lock and a three-input concatenated logic circuit with two outputs, were successfully constructed.

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“…[1][2][3][4][5][6][7][8][9][10][11] The driving force for bipolar electrochemistry is the ohmic potential variation in solution that forms during the passage of current in an electrochemical cell. When there is an appreciable ohmic potential drop through solution, and a conductor is in that potential gradient, the path of least resistance for current flow can sometimes be through the conductor via bipolar electrochemistry.…”

mentioning

confidence: 99%

Localized Electrodeposition and Patterning Using Bipolar Electrochemistry

Braun

Schwartz

2015

J. Electrochem. Soc.

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Microscopic, spatially controlled, and highly efficient bipolar electrochemistry can be performed on an electrically-floating macroscopic conductive substrate using a tool we call the Scanning Bipolar Cell (SBC). The operating principle for the SBC is that current follows the path of least resistance. A high ohmic potential drop can be generated in the electrolyte adjacent to the conductive substrate by using a moderate conductivity electrolyte with a microjet cell geometry, inducing localized charge transfer on the substrate beneath the microjet. The equal and opposite redox chemistry necessary for sustained bipolar electrochemistry is spread over the macroscopic far-field of the floating conductive substrate. We combine experiments and finite element simulations to demonstrate this system using reversible copper redox chemistry. Bipolar electrochemical coupling to the surface can be highly efficient in the SBC and is governed by the balance of interfacial charge transfer and solution ohmic resistances, as characterized by the Wagner number of the system. Bipolar electrochemistry-spatially segregated, equal and opposite reduction and oxidation on an electrically-floating conductor-is a widely recognized phenomenon that is being reinvigorated as a useful tool for new kinds of electrochemical applications.1-11 The driving force for bipolar electrochemistry is the ohmic potential variation in solution that forms during the passage of current in an electrochemical cell. When there is an appreciable ohmic potential drop through solution, and a conductor is in that potential gradient, the path of least resistance for current flow can sometimes be through the conductor via bipolar electrochemistry.Electrodeposition processes are among the most common domains for this new breed of engineering-oriented bipolar electrochemistry applications. For example, copper interconnects can be grown between two electrically isolated copper posts without any direct electrical contact by placing them in a solution with high ohmic resistance.1,2 This generates a large electric field that creates sufficient voltage across each post to drive copper reduction and the growth of material between them (since it is bipolar, there is an equal but opposite oxidation also occurring). Similarly, one can also use the equal and opposite nature of bipolar electrochemistry to make Janus type conducting particles that are differentially decorated based on the induced bias across the dimensions of the particle.3 Bipolar electrochemistry that employs a reversible electrodeposition/etching chemistry can cause a free floating conductor of the active material to etch on one side and deposits an equal amount on the other side, resulting in a propagating chemical wave that moves in the direction of the solution potential gradient. 4 Applications for surface modification and electroanalytics have also recently been explored using bipolar electrochemistry. For example, bipolar electrochemistry induced by the solution potential gradient across a conductive subs...

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Bipolar Electrochemistry: From Materials Science to Motion and Beyond

Cited by 332 publications

References 61 publications

Bipolar anodization enables the fabrication of controlled arrays of TiO₂ nanotube gradients

Bipolar anodization enables the fabrication of controlled arrays of TiO₂ nanotube gradients

Dual-electrochromic bipolar electrode-based universal platform for the construction of various visual advanced logic devices

Localized Electrodeposition and Patterning Using Bipolar Electrochemistry

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Bipolar Electrochemistry: From Materials Science to Motion and Beyond

Cited by 332 publications

References 61 publications

Bipolar anodization enables the fabrication of controlled arrays of TiO2 nanotube gradients

Bipolar anodization enables the fabrication of controlled arrays of TiO2 nanotube gradients

Dual-electrochromic bipolar electrode-based universal platform for the construction of various visual advanced logic devices

Localized Electrodeposition and Patterning Using Bipolar Electrochemistry

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Product

Resources

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Bipolar anodization enables the fabrication of controlled arrays of TiO₂ nanotube gradients

Bipolar anodization enables the fabrication of controlled arrays of TiO₂ nanotube gradients