**Author details**

Markus D. Kärkäs\* , Tanja M. Laine, Eric V. Johnston\* and Björn Åkermark\*


\*Address all correspondence to: bjorn.akermark@su.se (B. Å.)

Department of Organic Chemistry, Arrhenius Laboratory, Stockholm University, Stock‐ holm, Sweden.

#### **References**


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separately. The current limitation of these assemblies is related to the inefficient coupling of the individual catalytic events, which is necessary for the development of efficient artificial

Considerable progress has been made during the last decade in constructing photochemical cells capable of splitting water. However, the fundamental aspects, including their synthesis, their long-term durability, and the mechanistic understanding, are far from resolved and are of significant concern. Further elaboration and assembling of all of the integral components through cooperative interplay will certainly continue, thereby realizing efficient artificial

Financial support from the Swedish Research Council (637-2013-7314, 2015-04995 and 621-2013-4872), Swedish Foundation for Strategic Research, Stiftelsen Olle Engkvist Byggmäs‐ tare, the Knut and Alice Wallenberg Foundation, and the Carl Trygger Foundation is gratefully

Department of Organic Chemistry, Arrhenius Laboratory, Stockholm University, Stock‐

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and Björn Åkermark\*

, Tanja M. Laine, Eric V. Johnston\*

\*Address all correspondence to: markus.karkas@su.se (M. D. K.)

\*Address all correspondence to: eric.johnston@su.se (E. V. J.)

\*Address all correspondence to: bjorn.akermark@su.se (B. Å.)

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210 Applied Photosynthesis - New Progress

**Acknowledgements**

acknowledged.

**Author details**

Markus D. Kärkäs\*

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