Effect of pH waves on capacitive charging in microfluidic flow channels

Ionics

Volumn 20, Issue 9, 2014, Pages 1315-1322

  Roelofs, Susan H ^a   van Soestbergen, Michiel ^b   Odijk, Mathieu ^a   Eijkel, Jan C T ^a   van den Berg, Albert ^a  

^a UNIVERSITY OF TWENTE   (Netherlands)

^b EINDHOVEN UNIVERSITY OF TECHNOLOGY   (Netherlands)

Author keywords

Capacitive deionization; Desalination; Fluorescence; Lab on chip; pH

Indexed keywords

CHANNEL FLOW; CLIMATE CHANGE; FLUORESCENCE; FLUORESCENCE MICROSCOPY; MICROFLUIDICS; PH; WATER SUPPLY;

CAPACITIVE DEIONIZATION; CHANNEL CROSS SECTION; ELECTRICAL DOUBLE LAYERS; ELECTRICAL POTENTIAL; FARADAIC REACTIONS; LAB-ON-CHIP; MICROFLUIDIC FLOW CHANNEL; POTENTIAL DIFFERENCE;

DESALINATION;

EID: 84906778772     PISSN: 09477047     EISSN: 18620760     Source Type: Journal    
DOI: 10.1007/s11581-014-1083-6     Document Type: Article

References (49)

1. Shannon MA, Bohn PW, Elimelech M, Georgiadis JG, Mariñas BJ, Mayes AM (2008) Science and technology for water purification in the coming decades. Nature 452: 301.
2. Marris E (2008)Water: More crop per drop. Nature 452: 273.
3. Hightower M, Pierce SA (2008) The energy challenge. Nature 452: 285.
4. Porada S, Zhao R, van der Wal A, Presser V, Biesheuvel PM (2013) Review on the science and technology of water desalination by capacitive deionization. Prog Mater Sci 58: 1388.
5. Welgemoed TJ, Schutte CF (2005) Capacitive Deionization Technology: An alternative desalination solution. Desalination 183: 327.
6. Długołe{ogonek}cki P, van der Wal Environ A (2013) Energy Recovery in Membrane Capacitive Deionization. Sci Technol 47: 4904.
7. Brogioli D (2009) Document Extracting renewable energy from a salinity difference using a capacitor. Phys Rev Lett 103: 058501.
8. Brogioli D, Zhao R, Biesheuvel PM (2011) A prototype cell for extracting energy from a water salinity difference by means of double layer expansion in nanoporous carbon electrodes. Energy Environ Sci 4: 772.
9. 3 solutions with carbon aerogel electrodes. J Electrochem Soc 143: 159.
10. Rica RA, Ziano R, Salerno D, Mantegazza F, van Roij R, Brogioli D (2013) Capacitive Mixing for Harvesting the Free Energy of Solutions at Different Concentrations. Entropy 15: 1388.
11. Rica RA, Ziano R, Salerno D, Mantegazza F, Brogioli D (2012) Thermodynamic Relation between voltage-concentration dependence and salt adsorption in electrochemical cells. Phys Rev Lett 109: 156103.
12. Mossad M, Zhang W, Zou L (2013) Using capacitive deionisation for inland brackish groundwater desalination in a remote location. Desalination 308: 154.
13. Zhao R, van Soestbergen M, Rijnaarts HHM, van der Wal A, Bazant MZ, Biesheuvel PM (2012) Time-dependent ion selectivity in capacitive charging of porous electrodes. J Coll Int Sci 384: 38.
14. Biesheuvel PM, Zhao R, Porada S, van der Wal A (2011) Theory of membrane capacitive deionization including the effect of the electrode pore space. J Coll Int Sci 360: 239.
15. Zou L, Li L, Song H, Morris G (2008) Using mesoporous carbon electrodes for brackishwater desalination. Water Res 42: 2340.
16. Li H, Zou L, Pan L, Sun Z (2010) Novel Graphene-Like Electrodes for Capacitive Deionization. Env Sci Technol 44: 8692.
17. Porada S, Bryjak M, van der Wal A, Biesheuvel PM (2012) Effect of electrode thickness variation on operation of capacitive deionization. Electrochim Acta 75: 148.
18. Zhao R, Satpradit O, Rijnaarts HHM, Biesheuvel PM, van der Wal A (2013) Optimization of salt adsorption rate in membrane capacitive deionization. Water Res 47: 1941.
19. Oren Y, Soffer A (1983) Water desalting by means of electrochemical parametric pumping. I. The equilibrium properties of a batch unit cell. Journal of Applied Electrochemistry 13: 473.
20. Johnson AM, Newman J (1971) Desalting by Means of Porous Carbon Electrodes. J Electrochem Soc 118: 510.
21. Biesheuvel PM, Bazant MZ (2010) Nonlinear dynamics of capacitive charging and desalination by porous electrodes. Phys Rev E 81: 031502.
22. Anderson MA, Cudero AL, Palma J (2010) Capacitive deionization as an electrochemical means of saving energy and delivering clean water. Comparison to present desalination practices: Will it compete? Electrochim Acta 55: 3845.
23. Demirer ON, Hidrovo CH (2013) Laser-induced fluorescence visualization of ion transport in a pseudo-porous capacitive deionization microstructure. Microfluids and Nanofluids (in press).
24. Probstein RF, Hicks RE (1993) Removal of contaminants from soils by electric fields. Science 260: 498.
25. Kamran K, van Soestbergen M, Huinink HP, Pel L (2012) Inhibition of electrokinetic ion transport in porous materials due to potential drops induced by electrolysis. Electrochim Acta 78: 229.
26. Lee J-H, Bae W-S, Choi J-H (2010) Electrode reactions and adsorption/desorption performance related to the applied potential in a capacitive deionization process. Desalination 258: 159.
27. Lee J-B, Park K-K, Eum H-M, Lee C-W (2006) Desalination of a thermal power plant wastewater by membrane capacitive deionization. Desalination 196: 125.
28. Bouhadana Y, Avraham E, Noked M, Ben-Tzion M, Soffer A, Aurbach D (2011) Capacitive Deionization of NaCl Solutions at Non-Steady-State Conditions: Inversion Functionality of the Carbon Electrodes. J Phys Chem C 115: 16567.
29. Veenhuis RBH, van der Wouden EJ, van Nieuwkasteele JW, van den Berg A, Eijkel JCT (2009) Field-effect based attomole titrations in nanoconfinement. Lab Chip 9: 3472.
30. Soffer A, Folman M (1972) The electrical double layer of high surface porous carbon electrode. J Electroanal Chem Int Electrochem 38: 25.
31. Diehl H, Markuszewski R (1989) Studies on fluorescein-VII. The fluorescence of fluorescein as a function of pH. Talanta 36: 416.
32. Shao J, Guo H, Ji S, Zhao J (2011) Styryl-BODIPY based red-emitting fluorescent OFF-ON molecular probe for specific detection of cysteine. Biosens Bioelectron 26: 3012.
33. Klonis N, Sawyer WH (1996) Spectral Properties of the Prototropic Forms of Fluorescein in Aqueous Solution. J Fluoresc 6: 147.
34. Fiedler S, Hagedom R, Schnelle T, Richter E, Wagner B, Fuhr G (1995) Diffusional Electrotitration: Generation of pH Gradients over Arrays of Ultramicroelectrodes Detected by Fluorescence. Anal Chem 67: 820.
35. Alodan MA, Smyrl WH (1998) Detection of localized corrosion of aluminum alloys using fluorescence microscopy. J Electrochem Soc 145: 1571.
36. Suss ME, Mani A, Zangle TA, Santiago JG (2011) Electroosmotic pump performance is affected by concentration polarizations of both electrodes and pump. Sensors Actuators A 165: 310.
37. van Soestbergen M, Mavinkurve A, Rongen RTH, Jansen KMB, Ernst LJ, Zhang GQ (2010) Theory of aluminum metallization corrosion in microelectronics. Electrochim Acta 55: 5459.
38. Andersen MB, van Soestbergen M, Mani A, Bruus H, Biesheuvel PM, Bazant MZ (2012) Current-induced membrane discharge. Phys Rev Lett 109: 108301.
39. Biesheuvel PM, van Soestbergen M, Bazant MZ (2009) Imposed currents in galvanic cells. Electrochim Acta 54: 4857.
40. van Soestbergen M, Biesheuvel PM, Bazant MZ (2010) Diffuse-charge effects on the transient response of electrochemical cells. Phys Rev E 81: 021503.
41. Kamran K, van Soestbergen M, Pel L (2013) Electrokinetic Salt Removal from Porous Building Materials Using Ion Exchange Membranes. Trans Porous Media 96: 221.
42. Culbertson CT, Jacobson SC, Ramsey JM (2002) Diffusion coefficient measurements in microfluidic devices. Talanta 56: 365.
43. Mavré F, Anand RK, Laws DR, Chow K-F, Chang B-Y, Crooks JA, Crooks RM (2010) Bipolar electrodes: A useful tool for concentration, separation, and detection of analytes in microelectrochemical systems. Anal Chem 82: 8766.
44. Newman JS (1973) Electrochemical systems. Prentice-Hall, Englewood Cliffs.
45. Alvarez-Pez JM, Ballesteros L, Talavera E, Yguerabide J (2001) Fluorescein excited-state proton exchange reactions: Nanosecond emission kinetics and correlation with steady-state fluorescence intensity. J Phys Chem A 105: 6320.
46. Nightingale ER (1959) Phenomenological theory of ion solvation - effective radii of hydrated ions. J Phys Chem 63: 1381.
47. Kilic MS, Bazant MZ, Ajdari A (2007) Steric effects in the dynamics of electrolytes at large applied voltages. I. Double-layer charging. Phys Rev E 75: 021502.
48. Avraham E, Bouhadana Y, Soffer A, Aurbach D (2009) Limitation of Charge efficiency in capacitive deionization: I. on the behavior of single activated carbon. J Electrochem Soc 156: 95.
49. Persat A, Chambers RD, Santiago JG (2009) Basic principles of electrolyte chemistry for microfluidic electrokinetics. Part I: Acid-base equilibria and pH buffers. Lab Chip 9: 2437.