6533b870fe1ef96bd12d0518
RESEARCH PRODUCT
Accelerated dinuclear palladium catalyst identification through unsupervised machine learning.
Jas. S. WardTheresa SpergerFranziska SchoenebeckIgnacio Funes-ardoizJulian A. HueffelKari Rissanensubject
Identification (information)MultidisciplinaryComputer sciencebusiness.industryUnsupervised learningHomogeneous catalysisArtificial intelligencebusinessMachine learningcomputer.software_genrecomputerPalladium catalystBottleneckdescription
Although machine learning bears enormous potential to accelerate developments in homogeneous catalysis, the frequent need for extensive experimental data can be a bottleneck for implementation. Here, we report an unsupervised machine learning workflow that uses only five experimental data points. It makes use of generalized parameter databases that are complemented with problem-specific in silico data acquisition and clustering. We showcase the power of this strategy for the challenging problem of speciation of palladium (Pd) catalysts, for which a mechanistic rationale is currently lacking. From a total space of 348 ligands, the algorithm predicted, and we experimentally verified, a number of phosphine ligands (including previously never synthesized ones) that give dinuclear Pd
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2021-11-25 | Science (New York, N.Y.) |