Evaluation of the role that photoacid excited-state acidity has on photovoltage and photocurrent of dye-sensitized ion-exchange membranes

Light-driven ion pumps can be fabricated from ion-exchange membranes infiltrated with water as the protonic semiconductor. Absorption of visible light and generation of mobile charge carrier protons are accomplished using photoacids that are covalently bonded to the membranes. Prior results from our work suggest that the photoacid excited-state acidity is not large enough to result in significant yields for conversion of light into mobile protons. Herein we compare a series of photoacid-bearing membranes that are even stronger acids in their excited states, and we determine that excited-state acidity does not correlate with photovoltage. By assessing the photoresponse of a series of bipolar membranes fabricated by laminating a photoacid-bearing cation-exchange membrane to an anionexchange membrane, no clear trend was observed between net built-in electric potential and photovoltaic performance. This suggests that other properties dictate the effectiveness of these light-driven proton pumps.

[1]  William N. White,et al.  Communication—Electrochemical Characterization of Commercial Bipolar Membranes under Electrolyte Conditions Relevant to Solar Fuels Technologies , 2016 .

[2]  D. Huppert,et al.  Ultrafast excited-state proton transfer from hydroxycoumarin-dipicolinium cyanine dyes , 2013 .

[3]  I. Riemann,et al.  Highly photostable “super”-photoacids for ultrasensitive fluorescence spectroscopy , 2014, Photochemical & photobiological sciences : Official journal of the European Photochemistry Association and the European Society for Photobiology.

[4]  K. Solntsev,et al.  Excited-state proton transfer: from constrained systems to "super" photoacids to superfast proton transfer. , 2002, Accounts of chemical research.

[5]  Christopher D. Sanborn,et al.  Observation of Photovoltaic Action from Photoacid-Modified Nafion Due to Light-Driven Ion Transport. , 2017, Journal of the American Chemical Society.

[6]  G. W. Murphy Model systems in photoelectrochemical energy conversion , 1978 .

[7]  Shane Ardo,et al.  Conversion of Visible Light into Ionic Power Using Photoacid-Dye-Sensitized Bipolar Ion-Exchange Membranes , 2017 .

[8]  H. Takeuchi,et al.  Proton transfer reactions in the excited state of 1-aminopyrene by picosecond/streak camera and nanosecond spectroscopy , 1981 .

[9]  Christopher D. Sanborn,et al.  Interfacial and Nanoconfinement Effects Decrease the Excited-State Acidity of Polymer-Bound Photoacids , 2019, Chem.

[10]  M. Baranov,et al.  Unveiling Structural Motions of a Highly Fluorescent Superphotoacid by Locking and Fluorinating the GFP Chromophore in Solution. , 2017, The journal of physical chemistry letters.

[11]  Lei Jiang,et al.  Artificial light-driven ion pump for photoelectric energy conversion , 2019, Nature Communications.

[12]  Kyle N. Grew,et al.  Understanding Transport at the Acid-Alkaline Interface of Bipolar Membranes , 2016 .

[13]  Eric Bakker,et al.  Photocurrent generation based on a light-driven proton pump in an artificial liquid membrane. , 2014, Nature chemistry.

[14]  Z. Grabowski,et al.  Generalised Förster cycle. Thermodynamic and extrathermodynamic relationships between proton transfer, electron transfer and electronic excitation , 1977 .