Strength of the Lewis–Brønsted superacids containing In, Sn, and Sb and the electron binding energies of their corresponding superhalogen anions M Czapla, P Skurski The Journal of Physical Chemistry A 119 (51), 12868-12875, 2015 | 66 | 2015 |
The existence and gas phase acidity of the HAlnF3n+ 1 superacids (n= 1–4) M Czapla, P Skurski Chemical Physics Letters 630, 1-5, 2015 | 57 | 2015 |
Does the protonation of superhalogen anions always lead to superacids? M Czapla, I Anusiewicz, P Skurski Chemical Physics 465, 46-51, 2016 | 33 | 2016 |
Ionizing benzene with superhalogens M Czapla, S Freza, P Skurski Chemical Physics Letters 619, 32-35, 2015 | 27 | 2015 |
Oxidizing CO 2 with superhalogens M Czapla, P Skurski Physical Chemistry Chemical Physics 19 (7), 5435-5440, 2017 | 23 | 2017 |
Toward the preparation of the HAuF6, HAu2F11, and HAu3F16 superacids: Theoretical study M Czapla, P Skurski International Journal of Quantum Chemistry 118 (4), e25494, 2018 | 22 | 2018 |
Mechanisms of carbon monoxide hydrogenation yielding formaldehyde catalyzed by the representative strong mineral acid, H 2 SO 4, and Lewis–Brønsted superacid, HF/AlF 3 O Rybacka, M Czapla, P Skurski Physical Chemistry Chemical Physics 19 (27), 18047-18054, 2017 | 22 | 2017 |
The saturation of the gas phase acidity of n HF/AlF 3 and n HF/GeF 4 (n= 1–6) superacids caused by increasing the number of surrounding HF molecules M Czapla, I Anusiewicz, P Skurski RSC advances 6 (35), 29314-29325, 2016 | 19 | 2016 |
Formation of enormously strongly bound anionic clusters predicted in binary superacids M Czapla, O Ciepła, J Brzeski, P Skurski The Journal of Physical Chemistry A 122 (43), 8539-8548, 2018 | 15 | 2018 |
The formation of formaldehyde via the carbon monoxide hydrogenation catalyzed by the HSbF6 superacid O Rybacka, M Czapla, P Skurski Theoretical Chemistry Accounts 136 (12), 140, 2017 | 11 | 2017 |
The HAlF 4 superacid fragmentation induced by an excess electron attachment M Czapla, P Skurski Physical Chemistry Chemical Physics 17 (29), 19194-19201, 2015 | 11 | 2015 |
Dissociative electron attachment to HGaF 4 Lewis–Brønsted superacid M Czapla, J Simons, P Skurski Physical Chemistry Chemical Physics 20 (33), 21739-21745, 2018 | 6 | 2018 |
Uncatalyzed peptide bond formation between two double amino acid molecules in the gas phase M Czapla, S Freza International Journal of Quantum Chemistry 117 (21), e25435, 2017 | 6 | 2017 |
Dinuclear superhalogen anions containing two different central atoms M Czapla Journal of Fluorine Chemistry 199, 97-102, 2017 | 6 | 2017 |
Icosahedral carborane superacids and their conjugate bases comprising H, F, Cl, and CN substituents: A theoretical investigation of monomeric and dimeric cages J Brzeski, M Czapla, P Skurski ChemPlusChem 85 (2), 312-318, 2020 | 5 | 2020 |
The presence of two different central atoms increases the strength of Lewis-Brønsted superacids A Cyraniak, P Skurski, M Czapla Chemical Physics Letters 717, 77-81, 2019 | 5 | 2019 |
Selected boron, aluminum, and gallium trihalide and trihydride anions J Brzeski, M Czapla, P Skurski, J Simons Chemical Physics 482, 387-392, 2017 | 5 | 2017 |
Polynuclear Li12F13 − anion as a steric shielding agent with respect to selected metal ions M Czapla Theoretical Chemistry Accounts 135, 1-8, 2016 | 4 | 2016 |
Tripodal podand ligand with a superhalogen nature as an effective molecular trap A Cyraniak, M Czapla Symmetry 12 (9), 1441, 2020 | 3 | 2020 |
Application of nonmetallic frustrated cations in the activation of small molecules K Kaniewska-Laskowska, M Czapla, J Chojnacki, R Grubba Dalton Transactions 52 (24), 8311-8315, 2023 | 2 | 2023 |