Publication date: Jan 29, 2024
Frustrated Lewis pairs (FLPs), featuring reactive combinations of Lewis acids and Lewis bases, have been utilized for myriad metal-free homogeneous catalytic processes. Immobilizing the active Lewis sites to a solid support, especially to porous scaffolds, has shown great potential to ameliorate FLP catalysis by circumventing some of its inherent drawbacks, such as product separation and catalyst recyclability. Nevertheless, designing immobilized Lewis pair active sites (LPASs) is challenging due to the requirement of placing the donor and acceptor centers in appropriate geometric arrangements while maintaining the necessary chemical environment to perform catalysis, and clear design rules have not yet been established. In this work, we formulate simple guidelines to build highly active LPASs for direct catalytic hydrogenation of CO₂ through a large-scale screening of a diverse library of 25,000 immobilized FLPs. The library is built by introducing boron-containing acidic sites in the vicinity of the existing basic nitrogen sites of the organic linkers of metal-organic frameworks collected in a "top-down" fashion from an experimental database. The chemical and geometrical appropriateness of these LPASs for CO₂ hydrogenation is determined by evaluating a series of simple descriptors representing the intrinsic strength (acidity and basicity) of the components and their spatial arrangement in the active sites. Analysis of the leading candidates enables the formulation of pragmatic and experimentally-relevant design principles and they constitute the starting point for further exploration of FLP-based catalysts for the reduction of CO₂.
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File name | Size | Description |
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README.txt
MD5md5:d68d80db815226438d37f78c103de3ba
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1.4 KiB | README file detailing the contents of this record. |
I2-BPh2-final_chemiscope.json.gz
MD5md5:54514429171569ae3472ea159d184cbb
Visualize on Chemiscope
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57.7 KiB | Chemiscope file containing the properties and structures of the final BPh2 functionalized linkers. |
I2-BMe2-final_chemiscope.json.gz
MD5md5:2051f8702b5c42c3046f3fbe43b3a0f1
Visualize on Chemiscope
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4.9 KiB | Chemiscope file containing the properties and structures of the final BMe2 functionalized linkers. |
I2-BBN-final_chemiscope.json.gz
MD5md5:66ba60e0a3024cad111f39cf3b66d140
Visualize on Chemiscope
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25.8 KiB | Chemiscope file containing the properties and structures of the final BBN functionalized linkers. |
I2-BPh2-final.csv
MD5md5:635f6deebd73b7c4ab6566bf3557f3d9
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5.6 KiB | CSV file containing the tabulated properties for the final BPh2-functionalized linkers. |
I2-BMe2-final.csv
MD5md5:d98097fb743d73b81e6ff018be41cd90
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532 Bytes | CSV file containing the tabulated properties for the final BMe2-functionalized linkers. |
I2-BBN-final.csv
MD5md5:0b2b945e3a53be0b2427f90a949d65e6
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2.6 KiB | CSV file containing the tabulated properties for the final BBN-functionalized linkers. |
I2.tar.gz
MD5md5:22ce2481629f337f5baf28295a55bbcf
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14.2 MiB | Compressed file with all the XYZ files of the filtered, pre and post screened I2 of the functionalized linkers. |
LPAS.tar.gz
MD5md5:b4df3718fe70c9456697cc53415a175c
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16.4 MiB | Compressed file with all the XYZ files of the filtered functionalized linkers. |
DL-database.tar.gz
MD5md5:dbf1118341b6add829acf456ce5cb44e
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29.8 MiB | Compressed file with all the XYZ files of the functionalized linkers. |
seed-database.tar.gz
MD5md5:64128ee5d2b44ed2854639b9522715ef
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756.1 KiB | Compressed file with all the XYZ files of the initial N-containing linkers. |
chemiscopify.ipynb
MD5md5:3f1f769af8f50f9efacffa2791359107
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6.5 KiB | Notebook exemplifying how the provided XYZ structures and csv files can be combined to generate the Chemiscope json files. |
predicted_PLD.csv
MD5md5:e080b276abd94560ed14ca6fd95c5cae
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1.1 MiB | Predicted PLD for the functionalized linkers. |
2024.58 (version v3) | Apr 17, 2024 | DOI10.24435/materialscloud:90-b6 |
2024.15 (version v2) [This version] | Jan 29, 2024 | DOI10.24435/materialscloud:dq-z3 |
2023.66 (version v1) | Apr 18, 2023 | DOI10.24435/materialscloud:31-wz |