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2-years impact-factor Math-Net.Ru of «Teoreticheskaya i Matematicheskaya Fizika» journal, 2011
2-years impact-factor Math-Net.Ru of the journal in 2011 is calculated
as the number of citations in 2011 to the scientific papers published during
2009–2010.
The table below contains the list of citations in 2011 to the papers
published in 2009–2010. We take into account all citing publications
we found from different sources, mostly from references lists available
on Math-Net.Ru. Both original and translation versions are taken into account.
The impact factor Math-Net.Ru may change when new citations to a year
given are found.
Year |
2-years impact-factor Math-Net.Ru |
Scientific papers |
Citations |
Citated papers |
Journal Self-citations |
2011 |
0.714 |
283 |
202 |
112 |
14.4% |
|
|
N |
Citing pulication |
|
Cited paper |
|
1. |
Dzh. Kharnad, I. V. van de Ler, A. Yu. Orlov, “Kratnye summy i integraly kak tau-funktsii neitralnoi ierarkhii Kadomtseva–Petviashvili”, TMF, 168:1 (2011), 112–124  |
→ |
Fermionic approach for evaluating integrals of rational symmetric functions J. Harnad, A. Yu. Orlov TMF, 158:1 (2009), 23–48
|
|
2. |
V. M. Zhuravlev, K. S. Obrubov, “Metod obobschennykh podstanovok Koula–Khopfa v teorii konechnomernykh nelineinykh dinamicheskikh sistem”, Vestn. Sam. gos. tekhn. un-ta. Ser. Fiz.-mat. nauki, 1(22) (2011), 83–89  |
→ |
The method of generalized Cole–Hopf substitutions and new examples of linearizable nonlinear evolution equations V. M. Zhuravlev TMF, 158:1 (2009), 58–71
|
3. |
Zhuravlev V.M., Zinov'ev D.A., “Nonlinear waves in self-gravitating compressible fluid and generalized Cole-Hopf substitutions”, Physics of Wave Phenomena, 19:4 (2011), 313–317  |
→ |
The method of generalized Cole–Hopf substitutions and new examples of linearizable nonlinear evolution equations V. M. Zhuravlev TMF, 158:1 (2009), 58–71
|
|
4. |
Banerjee R., Mukherjee P., Paul B., “Gauge symmetry and W-algebra in higher derivative systems”, Journal of High Energy Physics, 2011, no. 8, 085  |
→ |
Geometric Hamiltonian formalism for reparameterization-invariant theories with higher derivatives P. I. Dunin-Barkovskii, A. V. Sleptsov TMF, 158:1 (2009), 72–97
|
|
5. |
Liu Yu., Chen D., “The exact solutions to a Ragnisco-Tu hierarchy with self-consistent sources”, Nonlinear Analysis-Theory Methods & Applications, 74:16 (2011), 5223–5237  |
→ |
The Kadomtsev–Petviashvili equation with self-consistent sources in nonuniform media Hao Hong-hai, Zhang Da-jun, Deng Shu-fang TMF, 158:2 (2009), 181–199
|
6. |
Sun Y.-P., Tam H.-W., “New Type of Nonisospectral KP Equation With Self-Consistent Sources and its Bilinear Backlund Transformation”, J Nonlinear Math Phys, 18:2 (2011), 323–336  |
→ |
The Kadomtsev–Petviashvili equation with self-consistent sources in nonuniform media Hao Hong-hai, Zhang Da-jun, Deng Shu-fang TMF, 158:2 (2009), 181–199
|
7. |
Zhu Xiao-Ming, Zhang Da-Jun, Li Chun-Xia, “Quasideterminant Solutions of a Noncommutative Nonisospectral Kadomtsev-Petviashvili Equation”, Commun Theor Phys (Beijing), 55:5 (2011), 753–759  |
→ |
The Kadomtsev–Petviashvili equation with self-consistent sources in nonuniform media Hao Hong-hai, Zhang Da-jun, Deng Shu-fang TMF, 158:2 (2009), 181–199
|
|
8. |
Komarova M.V., Kremnev I.S., Nalimov M.Yu., “Convergence of perturbation series for renormalization constants in Kraichnan model with “frozen” velocity field”, Eur Phys J C Part Fields, 71:5 (2011), 1646  |
→ |
Family of instantons of the Kraichnan model with a frozen velocity field M. V. Komarova, I. S. Kremnev, M. Yu. Nalimov TMF, 158:2 (2009), 200–213
|
|
9. |
Sirin H., Buyukkilic F., Ertik H., Demirhan D., “The effect of time fractality on the transition coefficients: Historical Stern-Gerlach experiment revisited”, Chaos Solitons & Fractals, 44:1–3 (2011), 43–47  |
→ |
Fractional generalization of the quantum Markovian master equation V. E. Tarasov TMF, 158:2 (2009), 214–233
|
|
10. |
Chuprikov N.L., “From a 1D Completed Scattering and Double Slit Diffraction to the Quantum-Classical Problem for Isolated Systems”, Found Phys, 41:9 (2011), 1502–1520  |
→ |
The correlation Bell inequalities V. A. Andreev TMF, 158:2 (2009), 234–249
|
|
11. |
Khalilov V.R., Lee K.E., “Bound Fermion States in a Vector 1/R and Aharonov-Bohm Potential in (2+1) Dimensions”, Modern Phys Lett A, 26:12 (2011), 865–883  |
→ |
Spontaneous fermion creation in the Coulomb field and Aharonov–Bohm potential in $2+1$ dimensions V. R. Khalilov TMF, 158:2 (2009), 250–262
|
12. |
V. R. Khalilov, Ki Yn Li, “Diskretnye spektry dirakovskogo gamiltoniana v kulonovskikh potentsialakh i potentsialakh Aaronova–Boma v $2+1$ izmereniyakh”, TMF, 169:3 (2011), 368–390  |
→ |
Spontaneous fermion creation in the Coulomb field and Aharonov–Bohm potential in $2+1$ dimensions V. R. Khalilov TMF, 158:2 (2009), 250–262
|
|
13. |
M. Yu. Kovalevskii, “$SU(3)$-Simmetriya i makroskopicheskaya dinamika magnetikov so spinom $s=1$”, TMF, 168:2 (2011), 245–260  |
→ |
Universality of the relaxation structure of equations for the dynamics of continuous media and dissipative Poisson brackets M. Yu. Kovalevsky, V. T. Matskevich, A. Ya. Razumnyi TMF, 158:2 (2009), 277–291
|
|
14. |
Aminov G., Arthamonov S., “Reduction of the elliptic SL(N, C) top”, Journal of Physics A-Mathematical and Theoretical, 44:7 (2011), 075201  |
→ |
Integrable $sl(N,\mathbb C)$ tops as Calogero–Moser systems A. V. Smirnov TMF, 158:3 (2009), 355–369
|
|
15. |
I. Ya. Arefeva, “Kogomologii v polevoi teorii superstrun i svoistva D-bran”, Problemy sovremennoi teoreticheskoi i matematicheskoi fiziki. Kalibrovochnye teorii i superstruny, Sbornik statei. K 70-letiyu so dnya rozhdeniya akademika Andreya Alekseevicha Slavnova, Tr. MIAN, 272, MAIK «Nauka/Interperiodika», M., 2011, 20–28  |
→ |
Tachyon solution in a cubic Neveu–Schwarz string field theory I. Ya. Aref'eva, R. V. Gorbachev, P. B. Medvedev TMF, 158:3 (2009), 378–390
|
16. |
Kroyter M., “Democratic superstring field theory: gauge fixing”, J. High Energy Phys., 2011, no. 3, 081  |
→ |
Tachyon solution in a cubic Neveu–Schwarz string field theory I. Ya. Aref'eva, R. V. Gorbachev, P. B. Medvedev TMF, 158:3 (2009), 378–390
|
17. |
Kiermaier M., Okawa Yu., Soler P., “Solutions from boundary condition changing operators in open string field theory”, J. High Energy Phys., 2011, no. 3, 122  |
→ |
Tachyon solution in a cubic Neveu–Schwarz string field theory I. Ya. Aref'eva, R. V. Gorbachev, P. B. Medvedev TMF, 158:3 (2009), 378–390
|
18. |
Noumi T., Okawa Yu., “Solutions from boundary condition changing operators in open superstring field theory”, Journal of High Energy Physics, 2011, no. 12, 034  |
→ |
Tachyon solution in a cubic Neveu–Schwarz string field theory I. Ya. Aref'eva, R. V. Gorbachev, P. B. Medvedev TMF, 158:3 (2009), 378–390
|
19. |
Bonora L., Maccaferri C., Tolla D.D., “Relevant deformations in open string field theory: a simple solution for lumps”, Journal of High Energy Physics, 2011, no. 11, 107  |
→ |
Tachyon solution in a cubic Neveu–Schwarz string field theory I. Ya. Aref'eva, R. V. Gorbachev, P. B. Medvedev TMF, 158:3 (2009), 378–390
|
20. |
Aref'eva I., “Puzzles with Tachyon in SSFT and Cosmological Applications”, Progr Theoret Phys Suppl, 2011, no. 188, 29–40  |
→ |
Tachyon solution in a cubic Neveu–Schwarz string field theory I. Ya. Aref'eva, R. V. Gorbachev, P. B. Medvedev TMF, 158:3 (2009), 378–390
|
|
|
Total publications: |
7880 |
Scientific articles: |
7742 |
Authors: |
4591 |
Citations: |
30094 |
Cited articles: |
5319 |
 |
Impact Factor Web of Science |
|
for 2019:
0.854 |
|
for 2018:
0.901 |
|
for 2017:
0.851 |
|
for 2016:
0.984 |
|
for 2015:
0.831 |
|
for 2014:
0.801 |
|
for 2013:
0.700 |
|
for 2012:
0.669 |
|
for 2011:
0.650 |
|
for 2010:
0.748 |
|
for 2009:
0.796 |
|
for 2008:
0.721 |
|
for 2007:
0.622 |
|
for 2006:
0.626 |
|
for 2005:
0.569 |
|
for 2004:
0.651 |
|
for 2003:
0.729 |
 |
Scopus Metrics |
|
2019 |
SJR |
0.299 |
|
2018 |
CiteScore |
0.810 |
|
2018 |
SJR |
0.386 |
|
2017 |
CiteScore |
0.800 |
|
2017 |
SNIP |
0.865 |
|
2017 |
SJR |
0.409 |
|
2016 |
CiteScore |
0.740 |
|
2016 |
SNIP |
0.970 |
|
2016 |
SJR |
0.425 |
|
2015 |
CiteScore |
0.650 |
|
2015 |
SNIP |
0.805 |
|
2015 |
IPP |
0.658 |
|
2015 |
SJR |
0.481 |
|
2014 |
CiteScore |
0.650 |
|
2014 |
SNIP |
0.899 |
|
2014 |
IPP |
0.678 |
|
2014 |
SJR |
0.492 |
|
2013 |
SNIP |
0.800 |
|
2013 |
IPP |
0.573 |
|
2013 |
SJR |
0.494 |
|
2012 |
SNIP |
0.764 |
|
2012 |
IPP |
0.555 |
|
2012 |
SJR |
0.294 |
|