TY  - CONF
AU  - Ahn, J.K.
AU  - Akamatsu, Y
AU  - Asakawa, M
AU  - Ashikaga, S
AU  - Busch, O
AU  - Chiu, M
AU  - Chujo, T
AU  - Ćirković, Predrag
AU  - Csörgő, T
AU  - David, G
AU  - Devetak, Damir
AU  - Đorđević, Miloš
AU  - Esumi, S
AU  - Fujii, H
AU  - Fukushima, K
AU  - Garg, P
AU  - Gunji, T
AU  - Hachiya, T
AU  - Hamagaki, H
AU  - Harada, H.
AU  - Harada, M
AU  - Hasegawa, S
AU  - Hatsuda, T
AU  - Hirano, T
AU  - Hong, B
AU  - Hotchi, H
AU  - Hwang, Soonwook
AU  - Ichikawa, Y
AU  - Ichisawa, T
AU  - Imai, K
AU  - Inaba, M
AU  - Itakura, K
AU  - Kamiya, J
AU  - Kaneta, M
AU  - Kato, H.
AU  - Kato, S
AU  - Kim, B.C.
AU  - Kim, E.J.
AU  - Kinsho, M
AU  - Kitazawa, M
AU  - Kovalenko, A
AU  - Liu, Y
AU  - Luo, X
AU  - Maruyama, T
AU  - Miake, Y
AU  - Milošević, Jovan
AU  - Mishra, D
AU  - Morita, K
AU  - Murase, K
AU  - Nađđerđ, Laslo
AU  - Nagamiya, S
AU  - Nakamura, A.
AU  - Nakamura, T
AU  - Nara, Y
AU  - Naruki, M
AU  - Nishio, K
AU  - Nonaka, C.
AU  - Nonaka, T
AU  - Ogino, M
AU  - Ohnishi, A
AU  - Oka, M
AU  - Okabe, A
AU  - Okamura, M
AU  - Oyama, K
AU  - Ozawa, K
AU  - Saha, P.K.
AU  - Saito, T
AU  - Sakaguchi, A.
AU  - Sakaguchi, T
AU  - Sakai, S
AU  - Sako, H
AU  - Sato, K.
AU  - Sato, S
AU  - Sawada, S
AU  - Shigaki, K
AU  - Shimansky, S
AU  - Shimomura, M
AU  - Shobuda, Y
AU  - Stojanović, Milan
AU  - Sugimura, H
AU  - Takeuchi, Y
AU  - Tamura, F.
AU  - Tamura, H.
AU  - Tamura, J
AU  - Tanaka, K.H.
AU  - Tanaka, Y
AU  - Tani, N
AU  - Tanida, K
AU  - Watanabe, Y
AU  - Xu, N
AU  - Yamamoto, M
AU  - Yokkaichi, S
AU  - Yoo, I.K.
AU  - Yoshimoto, M
PY  - 2019
UR  - https://linkinghub.elsevier.com/retrieve/pii/S0375947418305074
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/8024
C3  - Nuclear Physics A
T1  - J-PARC-HI Collaboration
VL  - 982
SP  - 1038
EP  - 1039
DO  - 10.1016/S0375-9474(18)30507-4
ER  - 

@conference{
author = "Ahn, J.K. and Akamatsu, Y and Asakawa, M and Ashikaga, S and Busch, O and Chiu, M and Chujo, T and Ćirković, Predrag and Csörgő, T and David, G and Devetak, Damir and Đorđević, Miloš and Esumi, S and Fujii, H and Fukushima, K and Garg, P and Gunji, T and Hachiya, T and Hamagaki, H and Harada, H. and Harada, M and Hasegawa, S and Hatsuda, T and Hirano, T and Hong, B and Hotchi, H and Hwang, Soonwook and Ichikawa, Y and Ichisawa, T and Imai, K and Inaba, M and Itakura, K and Kamiya, J and Kaneta, M and Kato, H. and Kato, S and Kim, B.C. and Kim, E.J. and Kinsho, M and Kitazawa, M and Kovalenko, A and Liu, Y and Luo, X and Maruyama, T and Miake, Y and Milošević, Jovan and Mishra, D and Morita, K and Murase, K and Nađđerđ, Laslo and Nagamiya, S and Nakamura, A. and Nakamura, T and Nara, Y and Naruki, M and Nishio, K and Nonaka, C. and Nonaka, T and Ogino, M and Ohnishi, A and Oka, M and Okabe, A and Okamura, M and Oyama, K and Ozawa, K and Saha, P.K. and Saito, T and Sakaguchi, A. and Sakaguchi, T and Sakai, S and Sako, H and Sato, K. and Sato, S and Sawada, S and Shigaki, K and Shimansky, S and Shimomura, M and Shobuda, Y and Stojanović, Milan and Sugimura, H and Takeuchi, Y and Tamura, F. and Tamura, H. and Tamura, J and Tanaka, K.H. and Tanaka, Y and Tani, N and Tanida, K and Watanabe, Y and Xu, N and Yamamoto, M and Yokkaichi, S and Yoo, I.K. and Yoshimoto, M",
year = "2019",
journal = "Nuclear Physics A",
title = "J-PARC-HI Collaboration",
volume = "982",
pages = "1038-1039",
doi = "10.1016/S0375-9474(18)30507-4"
}

Ahn, J.K., Akamatsu, Y., Asakawa, M., Ashikaga, S., Busch, O., Chiu, M., Chujo, T., Ćirković, P., Csörgő, T., David, G., Devetak, D., Đorđević, M., Esumi, S., Fujii, H., Fukushima, K., Garg, P., Gunji, T., Hachiya, T., Hamagaki, H., Harada, H., Harada, M., Hasegawa, S., Hatsuda, T., Hirano, T., Hong, B., Hotchi, H., Hwang, S., Ichikawa, Y., Ichisawa, T., Imai, K., Inaba, M., Itakura, K., Kamiya, J., Kaneta, M., Kato, H., Kato, S., Kim, B.C., Kim, E.J., Kinsho, M., Kitazawa, M., Kovalenko, A., Liu, Y., Luo, X., Maruyama, T., Miake, Y., Milošević, J., Mishra, D., Morita, K., Murase, K., Nađđerđ, L., Nagamiya, S., Nakamura, A., Nakamura, T., Nara, Y., Naruki, M., Nishio, K., Nonaka, C., Nonaka, T., Ogino, M., Ohnishi, A., Oka, M., Okabe, A., Okamura, M., Oyama, K., Ozawa, K., Saha, P.K., Saito, T., Sakaguchi, A., Sakaguchi, T., Sakai, S., Sako, H., Sato, K., Sato, S., Sawada, S., Shigaki, K., Shimansky, S., Shimomura, M., Shobuda, Y., Stojanović, M., Sugimura, H., Takeuchi, Y., Tamura, F., Tamura, H., Tamura, J., Tanaka, K.H., Tanaka, Y., Tani, N., Tanida, K., Watanabe, Y., Xu, N., Yamamoto, M., Yokkaichi, S., Yoo, I.K.,& Yoshimoto, M.. (2019). J-PARC-HI Collaboration. in Nuclear Physics A, 982, 1038-1039.
https://doi.org/10.1016/S0375-9474(18)30507-4

Ahn J, Akamatsu Y, Asakawa M, Ashikaga S, Busch O, Chiu M, Chujo T, Ćirković P, Csörgő T, David G, Devetak D, Đorđević M, Esumi S, Fujii H, Fukushima K, Garg P, Gunji T, Hachiya T, Hamagaki H, Harada H, Harada M, Hasegawa S, Hatsuda T, Hirano T, Hong B, Hotchi H, Hwang S, Ichikawa Y, Ichisawa T, Imai K, Inaba M, Itakura K, Kamiya J, Kaneta M, Kato H, Kato S, Kim B, Kim E, Kinsho M, Kitazawa M, Kovalenko A, Liu Y, Luo X, Maruyama T, Miake Y, Milošević J, Mishra D, Morita K, Murase K, Nađđerđ L, Nagamiya S, Nakamura A, Nakamura T, Nara Y, Naruki M, Nishio K, Nonaka C, Nonaka T, Ogino M, Ohnishi A, Oka M, Okabe A, Okamura M, Oyama K, Ozawa K, Saha P, Saito T, Sakaguchi A, Sakaguchi T, Sakai S, Sako H, Sato K, Sato S, Sawada S, Shigaki K, Shimansky S, Shimomura M, Shobuda Y, Stojanović M, Sugimura H, Takeuchi Y, Tamura F, Tamura H, Tamura J, Tanaka K, Tanaka Y, Tani N, Tanida K, Watanabe Y, Xu N, Yamamoto M, Yokkaichi S, Yoo I, Yoshimoto M. J-PARC-HI Collaboration. in Nuclear Physics A. 2019;982:1038-1039.
doi:10.1016/S0375-9474(18)30507-4 .

Ahn, J.K., Akamatsu, Y, Asakawa, M, Ashikaga, S, Busch, O, Chiu, M, Chujo, T, Ćirković, Predrag, Csörgő, T, David, G, Devetak, Damir, Đorđević, Miloš, Esumi, S, Fujii, H, Fukushima, K, Garg, P, Gunji, T, Hachiya, T, Hamagaki, H, Harada, H., Harada, M, Hasegawa, S, Hatsuda, T, Hirano, T, Hong, B, Hotchi, H, Hwang, Soonwook, Ichikawa, Y, Ichisawa, T, Imai, K, Inaba, M, Itakura, K, Kamiya, J, Kaneta, M, Kato, H., Kato, S, Kim, B.C., Kim, E.J., Kinsho, M, Kitazawa, M, Kovalenko, A, Liu, Y, Luo, X, Maruyama, T, Miake, Y, Milošević, Jovan, Mishra, D, Morita, K, Murase, K, Nađđerđ, Laslo, Nagamiya, S, Nakamura, A., Nakamura, T, Nara, Y, Naruki, M, Nishio, K, Nonaka, C., Nonaka, T, Ogino, M, Ohnishi, A, Oka, M, Okabe, A, Okamura, M, Oyama, K, Ozawa, K, Saha, P.K., Saito, T, Sakaguchi, A., Sakaguchi, T, Sakai, S, Sako, H, Sato, K., Sato, S, Sawada, S, Shigaki, K, Shimansky, S, Shimomura, M, Shobuda, Y, Stojanović, Milan, Sugimura, H, Takeuchi, Y, Tamura, F., Tamura, H., Tamura, J, Tanaka, K.H., Tanaka, Y, Tani, N, Tanida, K, Watanabe, Y, Xu, N, Yamamoto, M, Yokkaichi, S, Yoo, I.K., Yoshimoto, M, "J-PARC-HI Collaboration" in Nuclear Physics A, 982 (2019):1038-1039,
https://doi.org/10.1016/S0375-9474(18)30507-4 . .

TY  - JOUR
AU  - Baiwen, L
AU  - Ishiguro, Seiji
AU  - Škorić, Miloš M.
AU  - Takamaru, H
AU  - Sato, T
PY  - 2004
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/6484
AB  - The mechanism of electron acceleration by intense laser pulse interacting with an underdense plasma layer is examined by one-dimensional particle-m-cell (1D-PIC) simulations. The standard dephasing limit and the electron acceleration process are discussed briefly. A new phenomenon, of short high-quality, well-collimated return relativistic electron beam with thermal energy spread, is observed in the direction opposite to laser propagation. The process of the electron beam formation, its characteristics, and the time-history in x and p, space for test electrons in the beam, are analyzed and exposed clearly. Finally, an estimate for the maximum electron energy appears in a good agreement with simulation results.
T2  - Laser and Particle Beams
T1  - Acceleration of high-quality, well-collimated return beam of relativistic electrons by intense laser pulse in a low-density plasma
VL  - 22
IS  - 3
SP  - 307
EP  - 314
DO  - 10.1017/S0263034604223151
ER  - 

@article{
author = "Baiwen, L and Ishiguro, Seiji and Škorić, Miloš M. and Takamaru, H and Sato, T",
year = "2004",
abstract = "The mechanism of electron acceleration by intense laser pulse interacting with an underdense plasma layer is examined by one-dimensional particle-m-cell (1D-PIC) simulations. The standard dephasing limit and the electron acceleration process are discussed briefly. A new phenomenon, of short high-quality, well-collimated return relativistic electron beam with thermal energy spread, is observed in the direction opposite to laser propagation. The process of the electron beam formation, its characteristics, and the time-history in x and p, space for test electrons in the beam, are analyzed and exposed clearly. Finally, an estimate for the maximum electron energy appears in a good agreement with simulation results.",
journal = "Laser and Particle Beams",
title = "Acceleration of high-quality, well-collimated return beam of relativistic electrons by intense laser pulse in a low-density plasma",
volume = "22",
number = "3",
pages = "307-314",
doi = "10.1017/S0263034604223151"
}

Baiwen, L., Ishiguro, S., Škorić, M. M., Takamaru, H.,& Sato, T.. (2004). Acceleration of high-quality, well-collimated return beam of relativistic electrons by intense laser pulse in a low-density plasma. in Laser and Particle Beams, 22(3), 307-314.
https://doi.org/10.1017/S0263034604223151

Baiwen L, Ishiguro S, Škorić MM, Takamaru H, Sato T. Acceleration of high-quality, well-collimated return beam of relativistic electrons by intense laser pulse in a low-density plasma. in Laser and Particle Beams. 2004;22(3):307-314.
doi:10.1017/S0263034604223151 .

Baiwen, L, Ishiguro, Seiji, Škorić, Miloš M., Takamaru, H, Sato, T, "Acceleration of high-quality, well-collimated return beam of relativistic electrons by intense laser pulse in a low-density plasma" in Laser and Particle Beams, 22, no. 3 (2004):307-314,
https://doi.org/10.1017/S0263034604223151 . .

TY  - JOUR
AU  - Nikolić, Ljubomir
AU  - Škorić, Miloš M.
AU  - Ishiguro, Seiji
AU  - Sato, Tetsuya
PY  - 2003
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/6361
AB  - Propagation of a laser light through regions of an underdense plasma is an active research topic in laser fusion. In particular, a large effort has been invested in studies of stimulated Raman scattering (SRS) and stimulated Brillouin scattering (SBS), which can reflect laser energy and produce energetic particles to preheat a fusion energy target. Experiments, theory, and simulations agree on a complex interplay between various laser-plasma instabilities. By particle-in-cell simulations of an underdense electron plasma, apart from the standard SRS, a strong backscattering was found near the electron plasma frequency at densities beyond the quarter critical. This novel instability, recognized in recent experiments as stimulated laser scattering on a trapped electron-acoustic mode (SEAS), is absent from a classical theory of laser-parametric instabilities. A parametric excitation of SEAS instability is explained by a three-wave resonant decay of the incident laser light into a standing backscattered wave and a slow trapped electron-acoustic wave (omega LT omega(p)). Large SEAS pulsations, eventually suppressed by relativistic heating of electrons, are observed in these simulations. This phenomenon seems relevant to future hohlraum target and fast ignition experiments.
T2  - Fusion Science and Technology
T1  - On stimulated scattering of laser light in inertial fusion energy targets
VL  - 43
IS  - 3
SP  - 359
EP  - 365
DO  - 10.13182/FST03-A279
ER  - 

@article{
author = "Nikolić, Ljubomir and Škorić, Miloš M. and Ishiguro, Seiji and Sato, Tetsuya",
year = "2003",
abstract = "Propagation of a laser light through regions of an underdense plasma is an active research topic in laser fusion. In particular, a large effort has been invested in studies of stimulated Raman scattering (SRS) and stimulated Brillouin scattering (SBS), which can reflect laser energy and produce energetic particles to preheat a fusion energy target. Experiments, theory, and simulations agree on a complex interplay between various laser-plasma instabilities. By particle-in-cell simulations of an underdense electron plasma, apart from the standard SRS, a strong backscattering was found near the electron plasma frequency at densities beyond the quarter critical. This novel instability, recognized in recent experiments as stimulated laser scattering on a trapped electron-acoustic mode (SEAS), is absent from a classical theory of laser-parametric instabilities. A parametric excitation of SEAS instability is explained by a three-wave resonant decay of the incident laser light into a standing backscattered wave and a slow trapped electron-acoustic wave (omega LT omega(p)). Large SEAS pulsations, eventually suppressed by relativistic heating of electrons, are observed in these simulations. This phenomenon seems relevant to future hohlraum target and fast ignition experiments.",
journal = "Fusion Science and Technology",
title = "On stimulated scattering of laser light in inertial fusion energy targets",
volume = "43",
number = "3",
pages = "359-365",
doi = "10.13182/FST03-A279"
}

Nikolić, L., Škorić, M. M., Ishiguro, S.,& Sato, T.. (2003). On stimulated scattering of laser light in inertial fusion energy targets. in Fusion Science and Technology, 43(3), 359-365.
https://doi.org/10.13182/FST03-A279

Nikolić L, Škorić MM, Ishiguro S, Sato T. On stimulated scattering of laser light in inertial fusion energy targets. in Fusion Science and Technology. 2003;43(3):359-365.
doi:10.13182/FST03-A279 .

Nikolić, Ljubomir, Škorić, Miloš M., Ishiguro, Seiji, Sato, Tetsuya, "On stimulated scattering of laser light in inertial fusion energy targets" in Fusion Science and Technology, 43, no. 3 (2003):359-365,
https://doi.org/10.13182/FST03-A279 . .

TY  - JOUR
AU  - Nikolić, Lj.
AU  - Škorić, Miloš M.
AU  - Ishiguro, Seiji
AU  - Sato, T
PY  - 2002
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/2555
AB  - Intense laser-plasma interaction can be a source of various electronic instabilities. Recently, stimulated backscattering from a trapped electron-acoustic wave (SEAS) [Montgomery , Phys. Rev. Lett. 87, 155001 (2001)] was proposed to reinterpret spectra previously attributed to stimulated Raman scattering (SRS) from unrealistically low densities. By particle simulations in a uniform plasma layer, which is overdense for ordinary SRS, strong reflection by SEAS at the electron plasma frequency is found. Transient SEAS reflectivity pulsations are followed by strong relativistic heating of electrons. Physical conditions are explained by three-wave parametric coupling between laser light, standing backscattered wave and slow electron-acoustic wave. Regions in which SEAS reflection can dominate over SRS are singled out.
T2  - Physical Review E
T1  - Stimulated electron-acoustic-wave scattering in a laser plasma
VL  - 66
IS  - 3
DO  - 10.1103/PhysRevE.66.036404
ER  - 

@article{
author = "Nikolić, Lj. and Škorić, Miloš M. and Ishiguro, Seiji and Sato, T",
year = "2002",
abstract = "Intense laser-plasma interaction can be a source of various electronic instabilities. Recently, stimulated backscattering from a trapped electron-acoustic wave (SEAS) [Montgomery , Phys. Rev. Lett. 87, 155001 (2001)] was proposed to reinterpret spectra previously attributed to stimulated Raman scattering (SRS) from unrealistically low densities. By particle simulations in a uniform plasma layer, which is overdense for ordinary SRS, strong reflection by SEAS at the electron plasma frequency is found. Transient SEAS reflectivity pulsations are followed by strong relativistic heating of electrons. Physical conditions are explained by three-wave parametric coupling between laser light, standing backscattered wave and slow electron-acoustic wave. Regions in which SEAS reflection can dominate over SRS are singled out.",
journal = "Physical Review E",
title = "Stimulated electron-acoustic-wave scattering in a laser plasma",
volume = "66",
number = "3",
doi = "10.1103/PhysRevE.66.036404"
}

Nikolić, Lj., Škorić, M. M., Ishiguro, S.,& Sato, T.. (2002). Stimulated electron-acoustic-wave scattering in a laser plasma. in Physical Review E, 66(3).
https://doi.org/10.1103/PhysRevE.66.036404

Nikolić L, Škorić MM, Ishiguro S, Sato T. Stimulated electron-acoustic-wave scattering in a laser plasma. in Physical Review E. 2002;66(3).
doi:10.1103/PhysRevE.66.036404 .

Nikolić, Lj., Škorić, Miloš M., Ishiguro, Seiji, Sato, T, "Stimulated electron-acoustic-wave scattering in a laser plasma" in Physical Review E, 66, no. 3 (2002),
https://doi.org/10.1103/PhysRevE.66.036404 . .

TY  - JOUR
AU  - Škorić, Miloš M.
AU  - Sato, T
AU  - Maluckov, Aleksandra
AU  - Jovanović, Moma S.
PY  - 1999
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/2309
AB  - A nonlinear three-wave interaction in an open dissipative plasma model of a stimulated Raman backscattering is studied. An anomalous kinetic dissipation due to electron trapping and plasma wave breaking is accounted for in a hybrid kinetic-fluid scheme. We simulate a finite plasma with open boundaries and vary a transport parameter to examine a route to spatio-temporal complexity. An interplay between self-organization at micro (kinetic) and macro (fluid) scales is found through quasi-periodic and intermittent evolution of dynamical variables, dissipative structures and related entropy rates. A consistency with a general scenario of self-organization is claimed. [S1063-651X(99)17011-9].
T2  - Physical Review E
T1  - Self-organization in a dissipative three-wave interaction
VL  - 60
IS  - 6
SP  - 7426
EP  - 7434
DO  - 10.1103/PhysRevE.60.7426
ER  - 

@article{
author = "Škorić, Miloš M. and Sato, T and Maluckov, Aleksandra and Jovanović, Moma S.",
year = "1999",
abstract = "A nonlinear three-wave interaction in an open dissipative plasma model of a stimulated Raman backscattering is studied. An anomalous kinetic dissipation due to electron trapping and plasma wave breaking is accounted for in a hybrid kinetic-fluid scheme. We simulate a finite plasma with open boundaries and vary a transport parameter to examine a route to spatio-temporal complexity. An interplay between self-organization at micro (kinetic) and macro (fluid) scales is found through quasi-periodic and intermittent evolution of dynamical variables, dissipative structures and related entropy rates. A consistency with a general scenario of self-organization is claimed. [S1063-651X(99)17011-9].",
journal = "Physical Review E",
title = "Self-organization in a dissipative three-wave interaction",
volume = "60",
number = "6",
pages = "7426-7434",
doi = "10.1103/PhysRevE.60.7426"
}

Škorić, M. M., Sato, T., Maluckov, A.,& Jovanović, M. S.. (1999). Self-organization in a dissipative three-wave interaction. in Physical Review E, 60(6), 7426-7434.
https://doi.org/10.1103/PhysRevE.60.7426

Škorić MM, Sato T, Maluckov A, Jovanović MS. Self-organization in a dissipative three-wave interaction. in Physical Review E. 1999;60(6):7426-7434.
doi:10.1103/PhysRevE.60.7426 .

Škorić, Miloš M., Sato, T, Maluckov, Aleksandra, Jovanović, Moma S., "Self-organization in a dissipative three-wave interaction" in Physical Review E, 60, no. 6 (1999):7426-7434,
https://doi.org/10.1103/PhysRevE.60.7426 . .

TY  - JOUR
AU  - Hadžievski, Ljupčo
AU  - Škorić, Miloš M.
AU  - Kono, M
AU  - Sato, T
PY  - 1998
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/2203
AB  - The self-similar evolution of weak and strong Langmuir collapse is studied by two-dimensional simulation of a soliton instability. The simulation is based on Zakharovs model of magnetized strong turbulence including ion dynamics. For the parameters considered, consistency with self-similar weak collapse regimes is found with no evidence of a strong Langmuir collapse. (C) 1998 Elsevier Science B.V.
T2  - Physics Letters A
T1  - Simulation of weak and strong Langmuir collapse regimes
VL  - 248
IS  - 2-4
SP  - 247
EP  - 251
DO  - 10.1016/S0375-9601(98)00656-2
ER  - 

@article{
author = "Hadžievski, Ljupčo and Škorić, Miloš M. and Kono, M and Sato, T",
year = "1998",
abstract = "The self-similar evolution of weak and strong Langmuir collapse is studied by two-dimensional simulation of a soliton instability. The simulation is based on Zakharovs model of magnetized strong turbulence including ion dynamics. For the parameters considered, consistency with self-similar weak collapse regimes is found with no evidence of a strong Langmuir collapse. (C) 1998 Elsevier Science B.V.",
journal = "Physics Letters A",
title = "Simulation of weak and strong Langmuir collapse regimes",
volume = "248",
number = "2-4",
pages = "247-251",
doi = "10.1016/S0375-9601(98)00656-2"
}

Hadžievski, L., Škorić, M. M., Kono, M.,& Sato, T.. (1998). Simulation of weak and strong Langmuir collapse regimes. in Physics Letters A, 248(2-4), 247-251.
https://doi.org/10.1016/S0375-9601(98)00656-2

Hadžievski L, Škorić MM, Kono M, Sato T. Simulation of weak and strong Langmuir collapse regimes. in Physics Letters A. 1998;248(2-4):247-251.
doi:10.1016/S0375-9601(98)00656-2 .

Hadžievski, Ljupčo, Škorić, Miloš M., Kono, M, Sato, T, "Simulation of weak and strong Langmuir collapse regimes" in Physics Letters A, 248, no. 2-4 (1998):247-251,
https://doi.org/10.1016/S0375-9601(98)00656-2 . .