Add to ORKGLight-induced chemical processes are ubiquitous in nature and have widespread technological applications. For example, photoisomerization can allow a drug with a photo-switchable scaffold such as azobenzene to be activated with light. In principle, photoswitches with desired photophysical properties like high isomerization quantum yields can be identified through virtual screening with reactive simulations. In practice, these simulations are rarely used for screening, since they require hundreds of trajectories and expensive quantum chemical methods to account for non-adiabatic excited state effects. Here we introduce a diabatic artificial neural network (DANN) based on diabatic states to accelerate such simulations for azobenzene derivativ...
Many emerging technologies depend on human’s ability to control and manipulate the excited-state pro...
Azobenzene is one of the most ubiquitous photoswitches in photochemistry and a prototypical model fo...
In this work we show that deep learning (DL) can be used for exploring complex and highly nonlinear ...
The processes which occur after molecules absorb light underpin an enormous range of fundamental tec...
Azobenzene, a versatile and polymorphic molecule, has been extensively and successfully used for pho...
Azobenzene, a versatile and polymorphic molecule, has been extensively and successfully used for pho...
Understanding the excited state properties of molecules provides insight into how they interact with...
An accurate simulation of the excited states of molecules can enable the study of many important pro...
The thermal helix inversion (THI) of the overcrowded alkene-based molecular motors determines the sp...
Understanding the excited state properties of molecules provides insight into how they interact with...
International audienceTheoretical simulations of electronic excitations and associated processes in ...
International audienceTheoretical simulations of electronic excitations and associated processes in ...
International audienceTheoretical simulations of electronic excitations and associated processes in ...
This work presents a proof-of-concept study in artificial-intelligence-assisted (AI-assisted) chemis...
In this work we show that deep learning (DL) can be used for exploring complex and highly nonlinear ...
Many emerging technologies depend on human’s ability to control and manipulate the excited-state pro...
Azobenzene is one of the most ubiquitous photoswitches in photochemistry and a prototypical model fo...
In this work we show that deep learning (DL) can be used for exploring complex and highly nonlinear ...
The processes which occur after molecules absorb light underpin an enormous range of fundamental tec...
Azobenzene, a versatile and polymorphic molecule, has been extensively and successfully used for pho...
Azobenzene, a versatile and polymorphic molecule, has been extensively and successfully used for pho...
Understanding the excited state properties of molecules provides insight into how they interact with...
An accurate simulation of the excited states of molecules can enable the study of many important pro...
The thermal helix inversion (THI) of the overcrowded alkene-based molecular motors determines the sp...
Understanding the excited state properties of molecules provides insight into how they interact with...
International audienceTheoretical simulations of electronic excitations and associated processes in ...
International audienceTheoretical simulations of electronic excitations and associated processes in ...
International audienceTheoretical simulations of electronic excitations and associated processes in ...
This work presents a proof-of-concept study in artificial-intelligence-assisted (AI-assisted) chemis...
In this work we show that deep learning (DL) can be used for exploring complex and highly nonlinear ...
Many emerging technologies depend on human’s ability to control and manipulate the excited-state pro...
Azobenzene is one of the most ubiquitous photoswitches in photochemistry and a prototypical model fo...
In this work we show that deep learning (DL) can be used for exploring complex and highly nonlinear ...