The design of heterogeneous catalysts is challenged by the complexity of materials and processes that govern reactivity and by the fact that the number of good catalysts is very small in comparison to the number of possible materials. Here, we show how the subgroup-discovery (SGD) artificial-intelligence approach can be applied to an experimental plus theoretical data set to identify constraints on key physicochemical parameters, the so-called SG rules, which exclusively describe materials and reaction conditions with outstanding catalytic performance. By using high-throughput experimentation, 120 SiO2-supported catalysts containing ruthenium, tungsten, and phosphorus were synthesized and tested in the catalytic oxidation of propylene. As c...
International audienceAutonomous atomistic computations are excellent tools to accelerate the develo...
High throughput experimentation (HTE) in catalysis has proven useful in expediting materials discove...
Catalytic-materials design requires predictive modeling of the interaction between catalyst and reac...
The design of heterogeneous catalysts is challenged by the complexity of materials and processes tha...
The performance in heterogeneous catalysis is an example of a complex materials function, governed b...
The design of heterogeneous selective oxidation catalysts based upon complex metal oxides is governe...
In order to estimate the reactivity of a large number of potentially complex heterogeneous catalysts...
In order to estimate the reactivity of a large number of potentially complex heterogeneous catalysts...
Catalytic-materials design requires predictive modeling of the interaction between catalyst and reac...
Catalytic-materials design requires predictive modeling of the interaction between catalyst and reac...
Catalyst discovery is increasingly relying on computational chemistry, and many of the computational...
The continuing development of high throughput experiments (HTE) in the field of catalysis has dramat...
We present a new framework for catalyst design that integrates computer-aided extraction of knowledg...
Experimental catalyst optimization is plagued by slow and laborious efforts. Finding innovative mate...
Artificial intelligence (AI) can accelerate catalyst design by identifying key physicochemical descr...
International audienceAutonomous atomistic computations are excellent tools to accelerate the develo...
High throughput experimentation (HTE) in catalysis has proven useful in expediting materials discove...
Catalytic-materials design requires predictive modeling of the interaction between catalyst and reac...
The design of heterogeneous catalysts is challenged by the complexity of materials and processes tha...
The performance in heterogeneous catalysis is an example of a complex materials function, governed b...
The design of heterogeneous selective oxidation catalysts based upon complex metal oxides is governe...
In order to estimate the reactivity of a large number of potentially complex heterogeneous catalysts...
In order to estimate the reactivity of a large number of potentially complex heterogeneous catalysts...
Catalytic-materials design requires predictive modeling of the interaction between catalyst and reac...
Catalytic-materials design requires predictive modeling of the interaction between catalyst and reac...
Catalyst discovery is increasingly relying on computational chemistry, and many of the computational...
The continuing development of high throughput experiments (HTE) in the field of catalysis has dramat...
We present a new framework for catalyst design that integrates computer-aided extraction of knowledg...
Experimental catalyst optimization is plagued by slow and laborious efforts. Finding innovative mate...
Artificial intelligence (AI) can accelerate catalyst design by identifying key physicochemical descr...
International audienceAutonomous atomistic computations are excellent tools to accelerate the develo...
High throughput experimentation (HTE) in catalysis has proven useful in expediting materials discove...
Catalytic-materials design requires predictive modeling of the interaction between catalyst and reac...