Publications

You can find a more concise list of my publications here.

12. Anomalous propagators and the particle-particle channel: Hedin’s equations (pdf/si)

A. Marie, P. Romaniello and P.-F. Loos.

Phys. Rev. B 110,115155 (2024) | arXiv

11. Cumulant Greens’s function methods for molecules (pdf/si)

P.-F. Loos, A. Marie and A. Ammar.

Faraday Discuss. (2024) | arXiv

10. Reference energies for valence ionizations and satellite transitions (pdf)

A. Marie and P.-F. Loos.

J. Chem. Theory Comput. (Open access) 20, 4751 (2024) | arXiv

9. Can \(GW\) handle multireference systems? (pdf/si)

A. Ammar, A. Marie, M. Rodríguez-Mayorga, H. G. A. Burton, and P. F. Loos.

J. Chem. Phys. 160, 114101 (2024). | arXiv

8. The \(GW\) Approximation: A Quantum Chemistry Perspective (pdf/si)

A. Marie, A. Ammar and P.-F. Loos.

Adv. Quant. Chem. 90, 157 (2024) | arXiv

7. A similarity renormalization group approach to Green's function methods (pdf/si)

A. Marie and P.-F. Loos.

J. Chem. Theory Comput. (Open access) 19, 3943 (2023). | arXiv

6. Excited states, symmetry breaking, and unphysical solutions in state-specific CASSCF theory (pdf/si)

A. Marie and H. G. A. Burton.

J. Phys. Chem. A 127, 4538 (2023). Front cover | arXiv

5. Connections between many-body perturbation and coupled-cluster theories (pdf)

R. Quintero-Monsebaiz, E. Monino, A. Marie and P.-F. Loos.

Journal of Chemical Physics (Open Access) 157, 231102 (2022). | arXiv

\begin{equation*} \boldsymbol{\Sigma}^{GW} = \boldsymbol{V}^{\text{2h1p}} \cdot \boldsymbol{T}^{\text{2h1p}} + \boldsymbol{V}^{\text{2p1h}} \cdot \boldsymbol{T}^{\text{2p1h}} \end{equation*}

\begin{equation*} (\boldsymbol{V}^{\text{2h1p}} )^{T} + \boldsymbol{C}^{\text{2h1p}} \cdot \boldsymbol{T}^{\text{2h1p}} - \boldsymbol{T}^{\text{2h1p}} \cdot \boldsymbol{\epsilon} - \boldsymbol{T}^{\text{2h1p}} \cdot \boldsymbol{V}^{\text{2h1p}} \cdot \boldsymbol{T}^{\text{2h1p}} - \boldsymbol{T}^{\text{2h1p}} \cdot \boldsymbol{V}^{\text{2p1h}}\cdot \boldsymbol{T}^{\text{2p1h}} = \boldsymbol{0} \end{equation*}

\begin{equation*} (\boldsymbol{V}^{\text{2p1h}})^{T} + \boldsymbol{C}^{\text{2p1h}}\cdot \boldsymbol{T}^{\text{2p1h}} - \boldsymbol{T}^{\text{2p1h}} \cdot \boldsymbol{\epsilon} - \boldsymbol{T}^{\text{2p1h}} \cdot \boldsymbol{V}^{\text{2h1p}} \cdot \boldsymbol{T}^{\text{2h1p}} - \boldsymbol{T}^{\text{2p1h}} \cdot \boldsymbol{V}^{\text{2p1h}} \cdot \boldsymbol{T}^{\text{2p1h}} = \boldsymbol{0} \end{equation*}

4. Real space Mott-Anderson electron localization with long-range interactions: exact and approximate descriptions (pdf/si)

A. Marie, D. P. Kooi, J. Grossi, M. Seidl, Z. H. Musslimani, K. Giesbertz and P. Gori-Giorgi.

Physical Review Research (Open Access) 4, 043192 (2022). Editors' suggestion | arXiv

3. Variational coupled cluster for ground and excited states (pdf)

A. Marie, F. Kossoski, and P.-F. Loos.

J. Chem. Phys. (Open Access) 155, 104105 (2021). | arXiv

2. Excited states from state-specific orbital-optimized pair coupled-cluster (pdf/si)

F. Kossoski, A. Marie, A. Scemama, M. Caffarel, and P.-F. Loos.

J. Chem. Theory Comput. (Open Access) 17, 4756 (2021). | arXiv

1. Perturbation theory in the complex plane: exceptional points and where to find them (pdf)

A. Marie, H. G. A. Burton, and P.-F. Loos.

J. Phys.: Condens. Matter (Open Access) 33, 283001 (2021). | arXiv