1. Jindal, A; Vasudevan, S; JOURNAL OF PHYSICAL CHEMISTRY B; Volume: 124 Issue: 17 Pages: 3548-3555 Special Issue: SI; Published: APR 30 2020; DOI: 10.1021/acs.jpcb.0c01199 sum=3556
Mendez-Bermudez JG; Dominguez H; Temleitner L; Pusztai L; phys. stat. sol (b); 255, 1800215/1-8 (2018) 1. Klinov, A.; Anashkin, I.; Processes; 7(12), 947 (2019); https://doi.org/10.3390/pr7120947
2. Jindal, A; Vasudevan, S; JOURNAL OF PHYSICAL CHEMISTRY B; Volume: 124 Issue: 17 Pages: 3548-3555 Special Issue: SI; Published: APR 30 2020; DOI: 10.1021/acs.jpcb.0c01199 3. Garcia Perez, E; Gonzalez-Salgado, D; Lomba, E; FLUID PHASE EQUILIBRIA; Volume: 528;
Article Number: 112840; Published: JAN 15 2021; DOI: 10.1016/j.fluid.2020.112840 sum=3559. 1551
Bakó I; Mayer I; Hamza A; Pusztai L; Journal of Molecular Liquids, 285, 171-177 (2019)
1. Nagy, PR; Kallay, M; JOURNAL OF CHEMICAL THEORY AND COMPUTATION; Volume: 15 Issue: 10 Pages: 5275-5298; Published: OCT 2019; DOI: 10.1021/acs.jctc.9b00511
2. Herbert, JM; JOURNAL OF CHEMICAL PHYSICS; Volume: 151 Issue: 17; Article Number:
170901; Published: NOV 7 2019; DOI: 10.1063/1.5126216
3. Kallay, M; Nagy, PR; Mester, D; Rolik, Z; Samu, G; Csontos, J; Csoka, J; Szabo, PB; Gyevi-Nagy, L; Hegely, B; Ladjanszki, I; Szegedy, L; Ladoczki, B; Petrov, K; Farkas, M; Mezei, PD; Ganyecz, A;
JOURNAL OF CHEMICAL PHYSICS; Volume: 152 Issue: 7; Article Number: 074107; Published:
FEB 21 2020; DOI: 10.1063/1.5142048
sum=3562. 1552
Pothoczki, Sz; Pusztai, L; Bakó, I; J. Phys Chem. B; 123, 7599-7610 (2019)
1. Klinov, A.; Anashkin, I.; Processes; 7(12), 947 (2019); https://doi.org/10.3390/pr7120947 2. Garcia Perez, E; Gonzalez-Salgado, D; Lomba, E; FLUID PHASE EQUILIBRIA; Volume:
528; Article Number: 112840; Published: JAN 15 2021; DOI: 10.1016/j.fluid.2020.112840 sum=3564
Bakó, I; Daru, J; Pothoczki, Sz; Pusztai, L; Hermansson, K; Journal of Molecular Liquids, 293, 111579;
(2019)
1. Onawole, AT; Hussein, IA; Ahmed, MEM; Saad, MA; Aparicio, S; JOURNAL OF MOLECULAR LIQUIDS; Volume: 302; Article Number: 112500; Published: MAR 15 2020; DOI: 10.1016/j.molliq.2020.112500
sum=3565
Bakó I; Pethes I; Pothoczki Sz; Pusztai L; J. Mol Liq.; 273, 670-675 (2019)
1. Choi, S; Parameswaran, S; Choi, JH; PHYSICAL CHEMISTRY CHEMICAL PHYSICS; Volume:
22 Issue: 30 Pages: 17181-17195; Published: AUG 14 2020; DOI: 10.1039/d0cp01991g sum=3566
Hosokawa, …. Pusztai, L …… Phys Rev B. (2019)
1. Davani, FA; Hilke, S; Rosner, H; Geissler, D; Gebert, A; Wilde, G; JOURNAL OF APPLIED PHYSICS; Volume: 128 Issue: 1; Published: JUL 7 2020; DOI: 10.1063/5.0007564
2. Kimura, K; Kiuchi, H; Hayashi, K; Nakata, A; Fujisaki, F; Nishio, K; Fukunaga, T; Matsubara, E;
ANALYTICAL CHEMISTRY; Volume: 92 Issue: 14 Pages: 9956-9962; Published: JUL 21 2020;
DOI: 10.1021/acs.analchem.0c01525
3. Sorensen, SS; Biscio, CAN; Bauchy, M; Fajstrup, L; Smedskjaer, MM; SCIENCE ADVANCES;
Volume: 6 Issue: 37; Article Number: eabc2320; Published: SEP 2020; DOI:
10.1126/sciadv.abc2320
4. Hassanpour, A; Hilke, S; Rosner, H; Divinski, SV; Wilde, G; JOURNAL OF APPLIED PHYSICS;
Volume: 128 Issue: 15; Article Number: 155107; Published: OCT 21 2020; DOI:
10.1063/5.0026950
5. Zhu, H; Huang, YL; Ren, JC; Zhang, BH; Ke, YB; Jen, AKY; Zhang, Q; Wang, XL; Liu, Q;
ADVANCED SCIENCE; Article Number: 2003534; Early access iconEarly Access: JAN 2021;
DOI: 10.1002/advs.202003534 sum=3571
Cerar, J; Jamnik, A; Pethes, I; Temleitner, L; Pusztai, L; Tomšič, M; J. Coll. Interf. Sci., 560, pp. 730-742 (2020)
1. Klinov, A.; Anashkin, I.; Processes; 7(12), 947 (2019); https://doi.org/10.3390/pr7120947
2. Patil, MR; Ganorkar, SB; Patil, AS; Shirkhedkar, AA; Surana, SJ; CRITICAL REVIEWS IN ANALYTICAL CHEMISTRY; Early Access: JAN 2020; DOI: 10.1080/10408347.2020.1718484 3. Monje-Galvan, V; Klauda, JB; FLUID PHASE EQUILIBRIA; Volume: 513; Article Number:
112551; Published: JUN 1 2020; DOI: 10.1016/j.fluid.2020.112551
4. Jukic, I; Pozar, M; Lovrincevic, B; PHYSICAL CHEMISTRY CHEMICAL PHYSICS; Volume: 22 Issue: 41; Pages: 23856-23868; Published: NOV 7 2020; DOI: 10.1039/d0cp03160g
5. ((**Non-SCI-295**)) Domino, K., Bełdowski, D., Mazurkiewicz, A., Musiał, J., Słomion, M., &
Dobosz, R. (2019). Analysis of protein intramolecular and solvent bonding on example of major synovial fluid component. Preprints (www.preprints.org, https://doi.org/10.20944/preprints201911.0339.v1)
6. ((**NON-SCI-296, Diss-260**)) Warren, M., UNDERSTANDING SPECIFIC ION EFFECTS AND INTERFACIALLY ACTIVE SOLUTES USING THE COLLIGATIVE PROPERTIES OF MICROEMULSIONS. PhD dissertation, University of Oklahoma (2020). (Dowloaded from:
https://shareok.org/bitstream/handle/11244/325155/2020_Warren_Michael_Dissertation.pdf?sequenc e=1&isAllowed=y)
sum=3577 (NON-SCI: 296 , Diss: 260 ). 1553
Pethes, I; Bakó, I; Pusztai, L; Physical Chemistry Chemical Physics (PCCP), 22, pp. 11038-11044. (2020) 1. Agieienko, V; Buchner, R; PHYSICAL CHEMISTRY CHEMICAL PHYSICS; Volume: 22 Issue:
36 Pages: 20466-20476; Published: SEP 28 2020; DOI: 10.1039/d0cp03334k sum=3578
Pethes, I; Pusztai, L; Ohara, K; Kohara, S; Darpentigny, J; Temleitner, L; Journal of Molecular Liquids, 314, Paper: 113664, 10 p. (2020)
1. Dubey, V; Daschakraborty, S; JOURNAL OF PHYSICAL CHEMISTRY B; Volume: 124 Issue:
46 Pages: 10398-10408; Published: NOV 19 2020; DOI: 10.1021/acs.jpcb.0c07318 sum=3579
Pothoczki, Sz; Pethes, I; Pusztai, L; Temleitner, L; Csókás, D; Kohara, S; Ohara, K; Bakó, I; J. Mol. Liq.
329 Paper:115592, 10 p. (2021)
1. Al-Mutabagani, LA; Alshabanah, LA; Naoum, MM; Hagar, M; Ahmed, HA; FRONTIERS IN CHEMISTRY; Volume: 8; Article Number: 571120; Published: NOV 2 2020; DOI:
10.3389/fchem.2020.571120. (az ‘ArXiV-os verzióra hivatkozik) sum= 3580
R.L. Mcgreevy L. Pusztai Clarendon Laboratory Report Ref. No. 19/88 (Clarendon Laboratory, Oxford, UK, 1988)
1. A. Soper in: Static and Dynamic Properties of Liquids (Springer Proceedings in Physics Vol. 40., p.
189 (Springer-Verlag, Berlin, 1989)
2. F.J. Bermejo, J. Santoro, M. Alvarez, Nucl. Instr. Meth. B, 42, 281 (1989) sum=3582
L. Pusztai, Proc. 6th Int. Conf. on Non-Cryst. Mat., 1994
1. G. Kreuch, J. Hafner, J. Non-Cryst. Sol., 189, 227 (1995) sum=3583
L. Pusztai, O. Gereben, J. Non-Cryst. Sol., in press, (1995) 1. G. Kreuch, J. Hafner, J. Non-Cryst. Sol., 189, 227 (1995) 2. R.L. McGreevy, Nucl. Inst. Meth. A, 354, 1 (1995)
sum=3585
M.A. Howe, R.L. McGreevy, L. Pusztai, MCGR Manual, version 2.17, (Studsvik NFL, 1996); also at http://www.studsvik.uu.se
1. G. Tóth, Chem. Phys. Letters, 269, 413 (1997) 2. V. Petkov, R. Danev, J. Appl. Cryst., 31, 609 (1998)
3. I. Bakó, G. Pálinkás, J.C. Dore, H. Fischer, Molec. Phys., 96, 743 (1999)
4. ((**NON-SCI-297, Diss-261**)) Carlsson P, „Neutron scattering experiments and computer simulation studies of a polymer electrolyte”, PhD Theses (Chalmers University of Technolody, Göteborg, Sweden, 1999); Doktorsavhandlingar vid Chalmers tekniska högskola, Ny serie nr 1532, ISSN 0346-718X 5. S.A. van der Aart, V.W.J. Verhoven, P. Verkerk, W. van der Lugt, J. Chem. Phys., 112, 857 (2000) 6. Ahlstrom P, Borodin O, Wahnstrom G, Wensink EJW, Carlsson P, Smith GD, J. Chem. Phys. 112,
10669 (2000)
7. Masson O, Thomas P, Durand O, Hansen T, Champarnaud JC, Mercurio D, JOURNAL OF SOLID STATE CHEMISTRY 177: 2168-2176 (2004)
8. ((**NON-SCI-298, Diss-262**)) Durand O; Propriétés structurales et vibraconelles des phases désordonnées dans le systéme TeO2-Bi2O3 ; Universite de Limoges, Faculte des Sciences et Techniques de Limoges, These No. 30, 2006; retrieved from:
http://epublications.unilim.fr/theses/2006/durand-olivier/durand-olivier.pdf
sum=3593 (NON-SCI: 298 , Diss: 262 )
M. A. Howe, R. L. McGreevy, L. Pusztai, P. Zetterstrom, and A. Mellergard, MCGR Version 3.1, Internal Report, NFL Studsvik, Sweden, 2000.
1. Jonathan C. Wasse, Chris A. Howard, Helen Thompson, Neal T. Skipper, Robert G. Delaplane , Anders Wannberg; J. Chem. Phys. 121, 996 (2004); doi: 10.1063/1.1755663
sum=3594
O. Gereben, G. Evrard, L. Pusztai, RMC++ version 2 (2006); available at http://www.szfki.hu/~nphys/rmc++/opening.html
1. Kaban, W. Hoyer, T. Petkova, P. Petkov, B. Beuneu, A. Schöps, M.A. Webb, Journal Ovonic Research Vol. 3, No. 4, August 2007, p. 67 – 70
2. Kaban I, Hoyer W, Petkova T, Petkov P, Beuneu B, Schops A, Webb MA, JOURNAL OF OPTOELECTRONICS AND ADVANCED MATERIALS 9 (9): 2750-2753 SEP 2007 3. ((**NON-SCI-299, Diss-263**)) Hruszkewycz SO, 'THE EFFECT OF FLUCTUATION
MICROSCOPY CONSTRAINTS ON REVERSE MONTE CARLO MODELS OF METALLIC GLASS STRUCTURE', PhD dissertation, Johns Hopkins University (Baltimore, Maryland, USA), 2008 (UMI number: 3339883)
4. Muller CR, Kathriarachchi V, Schuch M, Maass P, Petkov VG, PHYSICAL CHEMISTRY CHEMICAL PHYSICS Volume: 12 Issue: 35 Pages: 10444-10451 Published: 2010 5. M Fábián , Th Proffen , U Ruett , E Veress and E Sváb , J. Phys.: Condens. Matter 22 404206
(2010)
6. I Kaban , P Jóvári , M Stoica , N Mattern , J Eckert , W Hoyer and B Beuneu , J. Phys.: Condens.
Matter 22 404208 (2010)
7. ((**NON_SCI-300, Diss-264**)) Mile V, „Structural studies of aqueous cesium halide solutions”, PhD dissertation (L. Eötvös University, Budapest, Hungary, 2010)
8. Kaban, I., Jóvári, P., Petkova, T., Petkov, P., Stoilova, A., Beuneu, B., Hoyer, W., Mattern, N., Eckert, J.; (2011) NATO Science for Peace and Security Series B: Physics and Biophysics, pp. 195-202.; DOI: 10.1007/978-94-007-0903-4-20
9. Odusote, YE; Mustapha, LO; American Journal of Condensed Matter Physics (p-ISSN: 2163-1115 e-ISSN: 2163-1123); vol. 7(2); pp. 33-40; 2017; doi:10.5923/j.ajcmp.20170702.01
10. Fábián, M., Araczki, C.; (2017) Materials Science Forum, 885, pp. 48-54.; DOI:
10.4028/www.scientific.net/MSF.885.48
11. B. D. KLEE; J. R. STELLHORN; M. KRBAL; N. BOUDET; G. A. CHAHINE; N. BLANC; W. C.
PILGRIM; T. WAGNER; S. HOSOKAWA; Chalcogenide Letters Vol. 15, No. 1, January 2018, p.
1 - 6
Sum=3605 (NON-SCI: 300, Diss: 264)
L. Pusztai, R.L. McGreevy, Studsvik NFL Annual Report for 1996, OTH:21 (1997) 1. P. Jóvári, Molec. Phys., 97, 1149 (1999)
2. ((**NON-SCI-301, Diss-265**)) Harsányi I, „Structural studies of electrolyte solutions by computer simulation methods”, PhD dissertation (L. Eötvös University, Budapest, 2005)
3. ((**NON-SCI-302, Diss-266**)) Pothoczki Sz, „Investigations concerning the structure of molecular liquids by diffraction and computer simulation methods”, MSc dissertation/diploma work (Budapest University of Technology and Economy, 2006)
4. ((**NON-SCI-303, Diss-267**)) Pothoczki Sz, „Structural studies of molecular liquids by diffraction and computer simulation methods”, PhD dissertation (Budapest University of Technology and
Economy, 2009)
5. H. Shimakura, N. Ogata, Y. Kawakita, K. Ohara, S. Takeda; Molec. Phys. Volume 111, Pages: 1015-1022; 2013.
sum=3610 (NON-SCI: 303, Diss: 267)
L. Pusztai, Candidate’s (Ph.D.) Thesis L. Eötvös University, Budapest (1991) 1. R.L. McGreevy, Nucl. Inst. A, 354, 1 (1995)
2. ((**NON-SCI-304, Diss-268**)) Szakály-Gereben O, „Structural studies of disordered materials by Reverse Monte Carlo simulation”, PhD dissertation (L. Eötvös University, Budapest, Hungary, 1995) 3. ((**NON-SCI-305, Diss-269 **)) Temleitner L, „Structural investigations of molecular liquids by
neutron diffraction and computer simulation”, MSc dissertation/diploma work (Budapest University of Technology and Economy, 2003)
4. ((**NON-SCI-306, Diss-270**)) Pothoczki Sz, „Investigations concerning the structure of molecular liquids by diffraction and computer simulation methods”, MSc dissertation/diploma work (Budapest University of Technology and Economy, 2006)
5. ((**NON-SCI-307, Diss-271**)) Temleitner L, „Investigations of structural disorder by neutron diffraction and computer simulation”, PhD dissertation (Budapest University of Technology and Economy, 2006)
6. ((**NON-SCI-308, Diss-272**)) Steinczinger, Zs. Computer modelling investigations concerning structural studies of pure water: The issue of consistency between measured diffraction data and interaction potentials,; PhD Dissertation; Chemistry Doctoral School, Eötvös University, Budapest, Hungary (2017); (See at: https://doktori.hu/index.php?menuid=193&lang=EN&vid=17013)
sum= 3616 (NON-SCI: 308, Diss: 272)
L. Pusztai, D.Sc. Theses, Hungarian Academy of Sciences (2000)
1. ((**NON-SCI-309, Diss-273**)) Temleitner L, „Structural investigations of molecular liquids by neutron diffraction and computer simulation”, MSc dissertation/diploma work (Budapest University of Technology and Economy, 2003)
2. ((**NON-SCI-310, Diss-274**)) Steinczinger, Zs. Computer modelling investigations concerning structural studies of pure water: The issue of consistency between measured diffraction data and interaction potentials,; PhD Dissertation; Chemistry Doctoral School, Eötvös University, Budapest, Hungary (2017); (See at: https://doktori.hu/index.php?menuid=193&lang=EN&vid=17013)
sum=3618 (NON-SCI: 310, Diss: 274)
L. Pusztai, R.L. McGreevy, Separation of the partial radial distribution functions of amorphous Fe80B20 on the basis of a single measurement, unpublished (1990)
1. ((**NON-SCI-311, Diss-275**)) Szakály-Gereben O, „Structural studies of disordered materials by Reverse Monte Carlo simulation”, PhD dissertation (L. Eötvös University, Budapest, Hungary, 1995)
sum=3619 (NON-SCI: 311, Diss: 275) Communications, unpublished L. Pusztai
1. HOWE MA, MCGREEVY RL, PHILOSOPHICAL MAGAZINE B-PHYSICS OF CONDENSED MATTER STATISTICAL MECHANICS ELECTRONIC OPTICAL AND MAGNETIC PROPERTIES, 58: 485-495 (1988)
2. R.L. McGreevy, IOP Conf. Ser., 101, 41 (1990)
3. MASAT M; JOURNAL OF SOCIAL POLITICAL AND ECONOMIC STUDIES Volume: 15 Issue: 4 Pages: 423-434 Published: WIN 1990
4. R.L. McGreevy, J. Non-Cryst. Sol., 156-158, 949 (1993) 5. R.L. McGreevy, J. Non-Cryst. Sol. 156-158, 949 (1993) 6. R.L. McGreevy, Int. J. Mod. Phys. B, 7, 2965 (1993)
7. J. Sietsma, P.A. Duine, A. van den Beukel, Phil. Mag. B 68, 913 (1993) 8. T. Arai, R.L. McGreevy, J. Phys.: Cond. Matter 10, 9221 (1998) 9. Tóth G, Baranyai A, J. Chem. Phys. 114, 2027 (2001)
10. McGreevy RL, JOURNAL DE PHYSIQUE IV 111, 347-371 (2003) 11. Oberdisse J, Hine P, Pyckhout-Hintzen W, Soft Matter 3, pp. 476-485 (2007) sum=3630 (NON-SCI: 311, Diss: 275)