Identifying Bottlenecks in the Photocatalytic Oxygen Evolution Reaction with Covalent Organic Frameworks

Identifying Bottlenecks in the Photocatalytic Oxygen Evolution Reaction with Covalent Organic Frameworks

Covalent organic frameworks (COFs) have emerged as promising semiconducting materials for photocatalytic applications due to their large surface area, high crystallinity, and vast synthetic tunability. This is especially noticeable in the context of photocatalytic water splitting, where many COFs ha...

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Bibliographic Details
Main Author: Stefan Trenker (21477936) (author)
Other Authors: Hugo A. Vignolo-Gonzalez (21477939) (author), Andrés Rodríguez-Camargo (12765804) (author), Liang Yao (823113) (author), Martijn A. Zwijnenburg (1301334) (author), Bettina V. Lotsch (1467520) (author)
Published: 2025
Subjects:
Biochemistry
Medicine
Molecular Biology
Evolutionary Biology
Computational Biology
Environmental Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
vast synthetic tunability
using computational methods
sandwich complex onto
retained catalytic activity
promising semiconducting materials
large surface area
hydrogen evolution half
electrocatalytic tests indicate
photocatalytic applications due
photocatalytic water splitting
sacrificial electron acceptor
oxygen evolution cocatalyst
ir ­( iii
careful control experiments
control experiments
subsequent photocatalytic
water oxidation
targeted cocatalyst
evolve oxygen
careful evaluation
work demonstrates
use heterogenization
trace back
reports focus
pitfalls associated
missing performance
limited insight
kinetic limitations
identifying bottlenecks
high crystallinity
especially noticeable
detailed role
cof photocatalysts
cobalt species
bpy cof
based cof
anchored cp
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Summary:Covalent organic frameworks (COFs) have emerged as promising semiconducting materials for photocatalytic applications due to their large surface area, high crystallinity, and vast synthetic tunability. This is especially noticeable in the context of photocatalytic water splitting, where many COFs have been employed for the hydrogen evolution half-reaction. There, sacrificial reagents typically replace the kinetically demanding oxygen evolution half-reaction. On the contrary, only few reports focus on (sacrificial) water oxidation with COF photocatalysts. In most of these cases, cobalt species are employed as oxygen evolution cocatalyst, often with limited insight into their structure and detailed role in the catalysis. Herein, we use heterogenization of a molecularly defined iridium half-sandwich complex onto a bipyridine-based COF (Ir@TAPB-BPY COF) and provide detailed structural insights ensuring the integrity of the targeted cocatalyst. First, we demonstrate the retained catalytic activity of the anchored Cp*Ir­(III) motifs in chemical water oxidation experiments. In contrast, subsequent photocatalytic and electrocatalytic tests indicate that Ir@TAPB-BPY COF does not evolve oxygen and that careful control experiments have to be conducted in order to avoid false positive results, caused for example by the sacrificial electron acceptor. Using computational methods, we trace back the missing performance to thermodynamic and kinetic limitations of the employed systems. This work demonstrates the pitfalls associated with low-performing oxygen evolution photocatalysts as well as the indispensability of control experiments and their careful evaluation.

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