A new hybrid exchange–correlation functional using the Coulomb-attenuating method (CAM-B3LYP) T Yanai, DP Tew, NC Handy Chemical physics letters 393 (1-3), 51-57, 2004 | 9464 | 2004 |

The D alton quantum chemistry program system K Aidas, C Angeli, KL Bak, V Bakken, R Bast, L Boman, O Christiansen, ... Wiley Interdisciplinary Reviews: Computational Molecular Science 4 (3), 269-284, 2014 | 982* | 2014 |

Explicitly correlated electrons in molecules C Hättig, W Klopper, A Köhn, DP Tew Chemical reviews 112 (1), 4-74, 2012 | 432 | 2012 |

New correlation factors for explicitly correlated electronic wave functions DP Tew, W Klopper The Journal of chemical physics 123 (7), 074101, 2005 | 260 | 2005 |

Communications: Accurate and efficient approximations to explicitly correlated coupled-cluster singles and doubles, CCSD-F12 C Hättig, DP Tew, A Köhn The Journal of chemical physics 132 (23), 231102, 2010 | 247 | 2010 |

Quintuple-ζ quality coupled-cluster correlation energies with triple-ζ basis sets DP Tew, W Klopper, C Neiss, C Hättig Physical Chemistry Chemical Physics 9 (16), 1921-1930, 2007 | 245 | 2007 |

Basis-set extrapolation techniques for the accurate calculation of molecular equilibrium geometries using coupled-cluster theory M Heckert, M Kállay, DP Tew, W Klopper, J Gauss The Journal of chemical physics 125 (4), 044108, 2006 | 223 | 2006 |

Quantitative quantum chemistry T Helgaker, W Klopper, DP Tew Molecular Physics 106 (16-18), 2107-2143, 2008 | 209 | 2008 |

Full-dimensional quantum calculations of ground-state tunneling splitting of malonaldehyde using an accurate *ab initio* potential energy surfaceY Wang, BJ Braams, JM Bowman, S Carter, DP Tew The Journal of chemical physics 128 (22), 224314, 2008 | 147 | 2008 |

A diagonal orbital-invariant explicitly-correlated coupled-cluster method DP Tew, W Klopper, C Hättig Chemical Physics Letters 452 (4-6), 326-332, 2008 | 124 | 2008 |

Simulating the vibrational quantum dynamics of molecules using photonics C Sparrow, E Martín-López, N Maraviglia, A Neville, C Harrold, J Carolan, ... Nature 557 (7707), 660-667, 2018 | 116 | 2018 |

Experimental Bayesian quantum phase estimation on a silicon photonic chip S Paesani, AA Gentile, R Santagati, J Wang, N Wiebe, DP Tew, ... Physical review letters 118 (10), 100503, 2017 | 116 | 2017 |

Witnessing eigenstates for quantum simulation of Hamiltonian spectra R Santagati, J Wang, AA Gentile, S Paesani, N Wiebe, JR McClean, ... Science advances 4 (1), eaap9646, 2018 | 110 | 2018 |

TURBOMOLE: Modular program suite for *ab initio* quantum-chemical and condensed-matter simulationsSG Balasubramani, GP Chen, S Coriani, M Diedenhofen, MS Frank, ... The Journal of chemical physics 152 (18), 184107, 2020 | 104 | 2020 |

Electron correlation: The many‐body problem at the heart of chemistry DP Tew, W Klopper, T Helgaker Journal of computational chemistry 28 (8), 1307-1320, 2007 | 98 | 2007 |

Atomization energies from coupled-cluster calculations augmented with explicitly-correlated perturbation theory W Klopper, B Ruscic, DP Tew, FA Bischoff, S Wolfsegger Chemical Physics 356 (1-3), 14-24, 2009 | 95 | 2009 |

Local explicitly correlated second-and third-order Møller–Plesset perturbation theory with pair natural orbitals C Hättig, DP Tew, B Helmich The Journal of chemical physics 136 (20), 204105, 2012 | 93 | 2012 |

The MP2‐F12 method in the TURBOMOLE program package RA Bachorz, FA Bischoff, A Glöß, C Hättig, S Höfener, W Klopper, DP Tew Journal of computational chemistry 32 (11), 2492-2513, 2011 | 93 | 2011 |

Basis set limit CCSD (T) harmonic vibrational frequencies DP Tew, W Klopper, M Heckert, J Gauss The Journal of Physical Chemistry A 111 (44), 11242-11248, 2007 | 93 | 2007 |

Local explicitly correlated second-order Møller–Plesset perturbation theory with pair natural orbitals DP Tew, B Helmich, C Hättig The Journal of chemical physics 135 (7), 074107, 2011 | 87 | 2011 |