POBERZNIK, MATIC

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POBERZNIK, MATIC

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Istituto Officina dei Materiali - IOM -

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Risultati 1 - 4 di 4 (tempo di esecuzione: 0.011 secondi).

Nonconductive ferrofluids from permanently magnetic nanoplatelets hybridized with polar phosphonic ligands

2025 Tufani, A.; Popov, N.; Kovac, J.; Campelj, S.; Mavric, A.; Landovsky, T.; Cigl, M.; Vankatova, P.; Loula, M.; Novotna, V.; Poberznik, M.; Herrero-Saboya, G.; Martin Samos Colomer, L.; Mertelj, A.; Lisjak, D.

Exploring potential energy surfaces to reach saddle points above convex regions

2024 Gunde, M.; Jay, A.; Poberznik, M.; Salles, N.; Richard, N.; Landa, G.; Mousseau, N.; Martin Samos Colomer, L.; Hemeryck, A.

pARTn: A plugin implementation of the Activation Relaxation Technique nouveau that takes over the FIRE minimisation algorithm

2024 Poberznik, M.; Gunde, M.; Salles, N.; Jay, A.; Hemeryck, A.; Richard, N.; Mousseau, N.; Martin-Samos, L.

Activation–Relaxation Technique: An efficient way to find minima and saddle points of potential energy surfaces

2022 Jay, A.; Gunde, M.; Salles, N.; Poberznik, M.; Martin Samos Colomer, L.; Richard, N.; Gironcoli, S. D.; Mousseau, N.; Hemeryck, A.

Titolo	Data di pubblicazione	Autore(i)
Nonconductive ferrofluids from permanently magnetic nanoplatelets hybridized with polar phosphonic ligands	1-gen-2025	Tufani, A.; Popov, N.; Kovac, J.; Campelj, S.; Mavric, A.; Landovsky, T.; Cigl, M.; Vankatova, P.; Loula, M.; Novotna, V.; Poberznik, M.; Herrero-Saboya, G.; Martin Samos Colomer, L.; Mertelj, A.; Lisjak, D.
Exploring potential energy surfaces to reach saddle points above convex regions	1-gen-2024	Gunde, M.; Jay, A.; Poberznik, M.; Salles, N.; Richard, N.; Landa, G.; Mousseau, N.; Martin Samos Colomer, L.; Hemeryck, A.
pARTn: A plugin implementation of the Activation Relaxation Technique nouveau that takes over the FIRE minimisation algorithm	1-gen-2024	Poberznik, M.; Gunde, M.; Salles, N.; Jay, A.; Hemeryck, A.; Richard, N.; Mousseau, N.; Martin-Samos, L.
Activation–Relaxation Technique: An efficient way to find minima and saddle points of potential energy surfaces	1-gen-2022	Jay, A.; Gunde, M.; Salles, N.; Poberznik, M.; Martin Samos Colomer, L.; Richard, N.; Gironcoli, S. D.; Mousseau, N.; Hemeryck, A.

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POBERZNIK, MATIC

Nonconductive ferrofluids from permanently magnetic nanoplatelets hybridized with polar phosphonic ligands

Exploring potential energy surfaces to reach saddle points above convex regions

pARTn: A plugin implementation of the Activation Relaxation Technique nouveau that takes over the FIRE minimisation algorithm

Activation–Relaxation Technique: An efficient way to find minima and saddle points of potential energy surfaces