We demonstrate the use of dataflow technology in the computation of the correlation energy in molecules at the Møller-Plesset perturbation theory (MP2) level. Specifically, we benchmark density fitting (DF)-MP2 for as many as 168 atoms (in valinomycin) and show that speed-ups between 3 and 3.8 times can be achieved when compared to the MOLPRO package run on a single CPU. Acceleration is achieved by offloading the matrix multiplications steps in DF-MP2 to Dataflow Engines (DFEs). We project that the acceleration factor could be as much as 24 with the next generation of DFEs
We study the recently developed Density Matrix Renormalization Group (DMRG) algorithm in the context...
A proper treatment of electron correlation effects is indispensable for accurate simulation of compo...
We propose to construct electron correlation methods that are scalable in both molecule size and agg...
We demonstrate the use of dataflow technology in the computation of the correlation energy in molecu...
Quantum chemistry plays an important role in elucidating molecular geometries, electronic states, ...
Wavefunction-less, density matrix-based approach to computational quantum chemistry is briefly discu...
Chemically accurate and comprehensive studies of the virtual space of all possible molecules are sev...
We describe a hierarchy of approximations (MP2[x]) that allow one to estimate second-order Møller-Pl...
Kohn-Sham density functional theory (DFT) is a standard tool in most branches of chemistry, but accu...
Accurate ab-initio prediction of electronic energies is very expensive for macromolecules by explici...
Correlation methods within electronic structure theory focus on recovering the exact electron-electr...
This work reports an efficient density‐fitting implementation of the density‐based basis‐set correct...
Kohn-Sham density functional theory (DFT) is a standard tool in most branches of chemistry, but a...
Algorithms for treating large molecules are developed and implemented within the DeFT density functi...
A framework for the reduced-scaling implementation of excited-state correlation methods is presented...
We study the recently developed Density Matrix Renormalization Group (DMRG) algorithm in the context...
A proper treatment of electron correlation effects is indispensable for accurate simulation of compo...
We propose to construct electron correlation methods that are scalable in both molecule size and agg...
We demonstrate the use of dataflow technology in the computation of the correlation energy in molecu...
Quantum chemistry plays an important role in elucidating molecular geometries, electronic states, ...
Wavefunction-less, density matrix-based approach to computational quantum chemistry is briefly discu...
Chemically accurate and comprehensive studies of the virtual space of all possible molecules are sev...
We describe a hierarchy of approximations (MP2[x]) that allow one to estimate second-order Møller-Pl...
Kohn-Sham density functional theory (DFT) is a standard tool in most branches of chemistry, but accu...
Accurate ab-initio prediction of electronic energies is very expensive for macromolecules by explici...
Correlation methods within electronic structure theory focus on recovering the exact electron-electr...
This work reports an efficient density‐fitting implementation of the density‐based basis‐set correct...
Kohn-Sham density functional theory (DFT) is a standard tool in most branches of chemistry, but a...
Algorithms for treating large molecules are developed and implemented within the DeFT density functi...
A framework for the reduced-scaling implementation of excited-state correlation methods is presented...
We study the recently developed Density Matrix Renormalization Group (DMRG) algorithm in the context...
A proper treatment of electron correlation effects is indispensable for accurate simulation of compo...
We propose to construct electron correlation methods that are scalable in both molecule size and agg...