In this article, the propagation of ion-acoustic shock and periodic waves along with their dynamical analysis around the supercritical values is studied in a (1 + 1)-dimensional collisionless negative ions plasma system comprising of inertia SF 6 with mass m i and temperature T i, inertia K+ with mass m + i and temperature T + i and inertialess non-extensive distributed electrons. By considering the appropriate starching coordinates and expansion of perturbation quantities, the Burgers-type equation with quartic nonlinearity is derived. Using the traveling wave transformation, a planar dynamical system is formed. The phase portrait is drawn and the associated nonlinear waves are analyzed. The research presented could be beneficial for understanding and forecasting localized electrostatic disturbances in the F- and D-layers of Earth's ionosphere as well as for guiding future experimental investigations in plasma laboratories.

1.
A.
Wellbrock
,
A. J.
Coates
,
G. H.
Jones
,
G. R.
Lewis
, and
J. H.
Waite
, “
Cassini CAPS‐ELS observations of negative ions in Titan's ionosphere: Trends of density with altitude
,”
Geophys. Res. Lett.
40
,
4481
4485
, https://doi.org/10.1002/grl.50751 (
2013
).
2.
A.
Coates
,
G.
Jones
,
G.
Lewis
,
A.
Wellbrock
,
D.
Young
,
F.
Crary
,
R.
Johnson
,
T.
Cassidy
, and
T.
Hill
, “
Negative ions in the Enceladus plume
,”
Icarus
206
,
618
622
(
2010
).
3.
R.
Sabry
,
W. M.
Moslem
, and
P. K.
Shukla
, “
Fully nonlinear ion-acoustic solitary waves in a plasma with positive-negative ions and nonthermal electrons
,”
Phys. Plasmas
16
,
032302
(
2009
).
4.
P.
Chaizy
,
H.
Rème
,
J. A.
Sauvaud
,
C.
d'Uston
,
R. P.
Lin
,
D. E.
Larson
,
D. L.
Mitchell
,
K. A.
Anderson
,
C. W.
Carlson
,
A.
Korth
, and
D. A.
Mendis
, “
Negative ions in the coma of comet Halley
,”
Nature
349
,
393
396
(
1991
).
5.
Encyclopedia of Plasma Technology
, edited by
J.
Leon Shohet
(
CRC Press
,
2016
), pp.
906
943
.
6.
B.
Song
,
N.
D'Angelo
, and
R. L.
Merlino
, “
Ion-acoustic waves in a plasma with negative ions
,”
Phys. Fluids B
3
,
284
287
(
1991
).
7.
A. J.
Coates
,
F. J.
Crary
,
G. R.
Lewis
,
D. T.
Young
,
J. H.
Waite
, and
E. C.
Sittler
, “
Discovery of heavy negative ions in Titan's ionosphere
,”
Geophys. Res. Lett.
34
,
L22103
, https://doi.org/10.1029/2007GL030978 (
2007
).
8.
J.
Jacquinot
,
B. D.
McVey
, and
J. E.
Scharer
, “
Mode conversion of the fast magnetosonic wave in a deuterium-hydrogen tokamak plasma
,”
Phys. Rev. Lett.
39
,
88
91
(
1977
).
9.
F.
Verheest
,
M. A.
Hellberg
, and
I.
Kourakis
, “
Acoustic solitary waves in dusty and/or multi-ion plasmas with cold, adiabatic, and hot constituents
,”
Phys. Plasmas
15
,
112309
(
2008
).
10.
S. K.
El-Labany
,
R.
Sabry
,
E. F.
El-Shamy
, and
D. M.
Khedr
, “
Nonlinear wave propagation of large amplitude ion-acoustic solitary waves in negative ion plasmas with superthermal electrons
,”
J. Plasma Phys.
79
,
613
621
(
2013
).
11.
K.
Kumar
and
M. K.
Mishra
, “
Large amplitude ion-acoustic solitons in warm negative ion plasmas with superthermal electrons
,”
AIP Adv.
7
,
115114
(
2017
).
12.
X.
Mushinzimana
,
F.
Nsengiyumva
, and
L. L.
Yadav
, “
Large amplitude slow ion-acoustic solitons, supersolitons, and double layers in a warm negative ion plasma with superthermal electrons
,”
AIP Adv.
11
,
025325
(
2021
).
13.
P.
Akter
and
M. G.
Hafez
, “
Dust‐ion‐acoustic shock wave excitations at super‐critical points with quartic nonlinearity
,”
Contrib. Plasma Phys.
63
,
e202300048
(
2023
).
14.
M. G.
Hafez
,
P.
Akter
, and
S.
Ariffin Abdul Karim
, “
Overtaking collisions of ion acoustic n-shocks in a collisionless plasma with pair-ion and ( α,q) distribution function for electrons
,”
Appl. Sci.
10
,
6115
(
2020
).
15.
P.
Akter
,
M. G.
Hafez
,
M. N.
Islam
, and
M. S.
Alam
, “
Ion acoustic shock wave excitations around the critical values in an unmagnetized pair–ion plasma
,”
Braz. J. Phys.
51
,
1355
1363
(
2021
).
16.
G. O.
Ludwig
,
J. L.
Ferreira
, and
Y.
Nakamura
, “
Observation of ion-acoustic rarefaction solitons in a multicomponent plasma with negative ions
,”
Phys. Rev. Lett.
52
,
275
278
(
1984
).
17.
A. Y.
Wong
,
D. L.
Mamas
, and
D.
Arnush
, “
Negative ion plasmas
,”
Phys. Fluids
18
,
1489
1493
(
1975
).
18.
R.
Ichiki
,
S.
Yoshimura
,
T.
Watanabe
,
Y.
Nakamura
, and
Y.
Kawai
, “
Experimental observation of dominant propagation of the ion-acoustic slow mode in a negative ion plasma and its application
,”
Phys. Plasmas
9
,
4481
4487
(
2002
).
19.
H.
Bailung
,
D.
Boruah
,
A. R.
Pal
, and
J.
Chutia
, “
Sheath characteristics in multi-component plasma with negative ions
,”
Pramana
62
,
1091
1098
(
2004
).
20.
V. M.
Vasyliunas
, “
A survey of low-energy electrons in the evening sector of the magnetosphere with OGO 1 and OGO 3
,”
J. Geophys. Res.
73
,
2839
2884
, https://doi.org/10.1029/JA073i009p02839 (
1968
).
21.
M.
Maksimovic
,
V.
Pierrard
, and
P.
Riley
, “
Ulysses electron distributions fitted with Kappa functions
,”
Geophys. Res. Lett.
24
,
1151
1154
, https://doi.org/10.1029/97GL00992 (
1997
).
22.
V.
De La Haye
,
J. H.
Waite
,
R. E.
Johnson
,
R. V.
Yelle
,
T. E.
Cravens
,
J. G.
Luhmann
,
W. T.
Kasprzak
,
D. A.
Gell
,
B.
Magee
,
F.
Leblanc
,
M.
Michael
,
S.
Jurac
, and
I. P.
Robertson
, “
Cassini Ion and Neutral Mass Spectrometer data in Titan's upper atmosphere and exosphere: Observation of a suprathermal corona
,”
J. Geophys. Res.
112
,
A07309
, https://doi.org/10.1029/2006JA012222 (
2007
).
23.
P.
Schippers
,
M.
Blanc
,
N.
André
,
I.
Dandouras
,
G. R.
Lewis
,
L. K.
Gilbert
,
A. M.
Persoon
,
N.
Krupp
,
D. A.
Gurnett
,
A. J.
Coates
,
S. M.
Krimigis
,
D. T.
Young
, and
M. K.
Dougherty
, “
Multi‐instrument analysis of electron populations in Saturn's magnetosphere
,”
J. Geophys. Res.
113
,
A07208
, https://doi.org/10.1029/2008JA013098 (
2008
).
24.
C.
Tsallis
, “
Possible generalization of Boltzmann-Gibbs statistics
,”
J. Stat. Phys.
52
,
479
487
(
1988
).
25.
M. G.
Hafez
, “
Nonlinear Schamel Korteweg-de Vries–Burgers equation to report ion-acoustic waves in the relativistic plasmas
,”
IEEE Trans. Plasma Sci.
47
,
5314
5323
(
2019
).
26.
M. G.
Hafez
,
N. C.
Roy
,
M. R.
Talukder
, and
M.
Hossain Ali
, “
Ion acoustic shock and periodic waves through burgers equation in weakly and highly relativistic plasmas with nonextensivity
,”
Plasma Sci. Technol.
19
,
015002
(
2016
).
27.
S.
Hussain
,
N.
Akhtar
, and
S.
Mahmood
, “
Propagation of ion acoustic shock waves in negative ion plasmas with nonextensive electrons
,”
Phys. Plasmas
20
,
092303
(
2013
).
28.
M. E.
Dieckmann
,
G.
Sarri
,
D.
Doria
,
H.
Ahmed
, and
M.
Borghesi
, “
Evolution of slow electrostatic shock into a plasma shock mediated by electrostatic turbulence
,”
New J. Phys.
16
,
073001
(
2014
).
29.
M. G.
Hafez
,
N. C.
Roy
,
M. R.
Talukder
, and
M.
Hossain Ali
, “
Oblique propagation of ion acoustic shock waves in weakly and highly relativistic plasmas with nonthermal electrons and positrons
,”
Astrophys. Space Sci.
361
,
312
(
2016
).
30.
A. A.
Mamun
,
P. K.
Shukla
, and
B.
Eliasson
, “
Arbitrary amplitude dust ion-acoustic shock waves in a dusty plasma with positive and negative ions
,”
Phys. Plasmas
16
,
114503
(
2009
).
31.
S.
Hussain
and
N.
Akhtar
, “
Korteweg de Vries Burgers equation in multi-ion and pair-ion plasmas with Lorentzian electrons
,”
Phys. Plasmas
20
,
012305
(
2013
).
32.
A.
Sarma
and
Y.
Nakamura
, “
Ion-acoustic shock waves with negative ions in presence of dust particulates
,”
Phys. Lett. A
373
,
4174
4177
(
2009
).
33.
J.
Sarkar
and
A.
Saha
, “
Role of polarized force on dust-acoustic structures in the presence of suprathermal electrons
,”
Phys. Fluids
36
,
044108
(
2024
).
34.
H. M.
Yin
,
Q.
Pan
, and
K. W.
Chow
, “
Modeling ‘crossing sea state’ wave patterns in layered and stratified fluids
,”
Phys. Rev. Fluids
8
,
014802
(
2023
).
35.
H. M.
Yin
and
K. W.
Chow
, “
Fermi-Pasta-Ulam-Tsingou recurrence and cascading mechanism for resonant three-wave interactions
,”
Phys. Rev. E
107
,
064215
(
2023
).
36.
V. Y. Y.
Cheung
,
H. M.
Yin
,
J. H.
Li
, and
K. W.
Chow
, “
An envelope system with third order dispersion: ‘Unconventional’ modulation instability and Floquet analysis
,”
Phys. Lett. A
476
,
128877
(
2023
).
37.
M. Q.
Tran
, “
Ion acoustic solitons in a plasma: A review of their experimental properties and related theories
,”
Phys. Scr.
20
,
317
327
(
1979
).
38.
M. K.
Deka
,
A. N.
Dev
,
A. P.
Misra
, and
N. C.
Adhikary
, “
Characteristics of solitary waves in a relativistic degenerate ion beam driven magneto plasma
,”
Phys. Plasmas
25
,
012102
(
2018
).
39.
Y.
Nakamura
, “
Experiments on ion-acoustic shock waves in a dusty plasma
,”
Phys. Plasmas
9
,
440
445
(
2002
).
40.
A. A.
Mamun
, “
On stretching of plasma parameters and related open issues for the study of dust-ion-acoustic and dust-acoustic shock waves in dusty plasmas
,”
Phys. Plasmas
26
,
084501
(
2019
).
41.
N.
Mann
,
S.
Rani
,
S.
Kumar
, and
R.
Kumar
, “
Novel closed-form analytical solutions and modulation instability spectrum induced by the Salerno equation describing nonlinear discrete electrical lattice via symbolic computation
,”
Math. Comput. Simul.
219
,
473
490
(
2024
).
42.
S.
Kumar
,
N.
Mann
,
H.
Kharbanda
, and
M.
Inc
, “
Dynamical behavior of analytical soliton solutions, bifurcation analysis, and quasi-periodic solution to the (2 + 1)-dimensional Konopelchenko–Dubrovsky (KD) system
,”
Anal. Math. Phys.
13
,
40
(
2023
).
43.
J.
Tamang
,
A.
Abdikian
, and
A.
Saha
, “
Phase plane analysis of small amplitude electron-acoustic supernonlinear and nonlinear waves in magnetized plasmas
,”
Phys. Scr.
95
,
105604
(
2020
).
44.
S. H.
Strogatz
,
Nonlinear Dynamics and Chaos: With Applications to Physics, Biology, Chemistry, and Engineering
(
Chapman and Hall/CRC
,
2024
).
45.
U. K.
Samanta
,
A.
Saha
, and
P.
Chatterjee
, “
Bifurcations of dust ion acoustic travelling waves in a magnetized quantum dusty plasma
,”
Astrophys. Space Sci.
347
,
293
298
(
2013
).
46.
S. Y.
El-Monier
and
A.
Atteya
, “
Bifurcation analysis for dust-acoustic waves in a four-component plasma including warm ions
,”
IEEE Trans. Plasma Sci.
46
,
815
824
(
2018
).
47.
A.
Saha
,
B.
Pradhan
, and
S.
Banerjee
, “
Bifurcation analysis of quantum ion-acoustic kink, anti-kink and periodic waves of the Burgers equation in a dense quantum plasma
,”
Eur. Phys. J. Plus
135
,
216
(
2020
).
48.
M. M.
Selim
,
A.
El-Depsy
, and
E. F.
El-Shamy
, “
Bifurcations of nonlinear ion-acoustic travelling waves in a multicomponent magnetoplasma with superthermal electrons
,”
Astrophys. Space Sci.
360
,
66
(
2015
).
49.
R. A.
Shahein
and
A. R.
Seadawy
, “
Bifurcation analysis of KP and modified KP equations in an unmagnetized dust plasma with nonthermal distributed multi-temperatures ions
,”
Indian J. Phys.
93
,
941
949
(
2019
).
50.
P. K.
Prasad
and
A.
Saha
, “
Dynamical behavior and multistability of ion-acoustic waves in a magnetized auroral zone plasma
,”
J. Astrophys. Astron.
42
,
9
(
2021
).
51.
U.
Kumar Samanta
,
A.
Saha
, and
P.
Chatterjee
, “
Bifurcations of dust ion acoustic travelling waves in a magnetized dusty plasma with a q-nonextensive electron velocity distribution
,”
Phys. Plasmas
20
,
022111
(
2013
).
52.
J.
Tamang
and
A.
Saha
, “
Phase plane analysis of the dust-acoustic waves for the burgers equation in a strongly coupled dusty plasma
,”
Indian J. Phys.
95
,
749
757
(
2020
).
53.
H.
Demiray
and
A.
Abdikian
, “
Modulational instability of acoustic waves in a dusty plasma with nonthermal electrons and trapped ions
,”
Chaos, Solitons Fractals
121
,
50
58
(
2019
).
54.
S.
Kumar
,
B.
Mohan
, and
A.
Kumar
, “
Generalized fifth-order nonlinear evolution equation for the Sawada-Kotera, Lax, and Caudrey-Dodd-Gibbon equations in plasma physics: Painlevé analysis and multi-soliton solutions
,”
Phys. Scr.
97
,
035201
(
2022
).
55.
S.
Kumar
,
B.
Mohan
, and
R.
Kumar
, “
Lump, soliton, and interaction solutions to a generalized two-mode higher-order nonlinear evolution equation in plasma physics
,”
Nonlinear Dyn.
110
,
693
704
(
2022
).
56.
B.
Mohan
,
S.
Kumar
, and
R.
Kumar
, “
Higher-order rogue waves and dispersive solitons of a novel p-type (3 + 1)-D evolution equation in soliton theory and nonlinear waves
,”
Nonlinear Dyn.
111
,
20275
20288
(
2023
).
57.
M. Y.
Yu
and
H.
Luo
, “
A note on the multispecies model for identical particles
,”
Phys. Plasmas
15
,
024504
(
2008
).
58.
C.
Tsallis
, “
Nonadditive entropy and nonextensive statistical mechanics—An overview after 20 years
,”
Braz. J. Phys.
39
,
337
356
(
2009
).
59.
J.
Tamang
,
K.
Sarkar
, and
A.
Saha
, “
Solitary wave solution and dynamic transition of dust ion acoustic waves in a collisional nonextensive dusty plasma with ionization effect
,”
Physica A
505
,
18
34
(
2018
).
60.
D. P.
Chapagai
,
J.
Tamang
, and
A.
Saha
, “
Bifurcation analysis for small-amplitude nonlinear and supernonlinear ion-acoustic waves in a superthermal plasma
,”
Z. Naturforsch., A
75
,
183
191
(
2019
).
61.
A.
Saha
and
S.
Banerjee
,
Dynamical Systems and Nonlinear Waves in Plasmas
(
CRC Press
,
2021
).
62.
S.
Rani
,
S.
Kumar
, and
N.
Mann
, “
On the dynamics of optical soliton solutions, modulation stability, and various wave structures of a (2 + 1)-dimensional complex modified Korteweg-de-Vries equation using two integration mathematical methods
,”
Opt. Quantum Electron.
55
,
731
(
2023
).
63.
S.
Kumar
and
B.
Mohan
, “
A novel analysis of Cole–Hopf transformations in different dimensions, solitons, and rogue waves for a (2 + 1)-dimensional shallow water wave equation of ion-acoustic waves in plasmas
,”
Phys. Fluids
35
,
127128
(
2023
).
64.
T.
Takeuchi
,
S.
Iizuka
, and
N.
Sato
, “
Ion acoustic shocks formed in a collisionless plasma with negative ions
,”
Phys. Rev. Lett.
80
,
77
80
(
1998
).
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