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Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format
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Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format Example of Physics of Metals and Metallography format
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Physics of Metals and Metallography — Template for authors

Publisher: Springer
Guideline source
Categories Rank Trend in last 3 yrs
Materials Chemistry #169 of 292 down down by 17 ranks
Condensed Matter Physics #275 of 411 down down by 17 ranks
journal-quality-icon Journal quality:
Medium
calendar-icon Last 4 years overview: 726 Published Papers | 1387 Citations
indexed-in-icon Indexed in: Scopus
last-updated-icon Last updated: 08/07/2020
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Journal Performance & Insights

CiteRatio

SCImago Journal Rank (SJR)

Source Normalized Impact per Paper (SNIP)

A measure of average citations received per peer-reviewed paper published in the journal.

Measures weighted citations received by the journal. Citation weighting depends on the categories and prestige of the citing journal.

Measures actual citations received relative to citations expected for the journal's category.

1.9

12% from 2019

CiteRatio for Physics of Metals and Metallography from 2016 - 2020
Year Value
2020 1.9
2019 1.7
2018 1.8
2017 1.5
2016 1.4
graph view Graph view
table view Table view

0.36

25% from 2019

SJR for Physics of Metals and Metallography from 2016 - 2020
Year Value
2020 0.36
2019 0.481
2018 0.515
2017 0.427
2016 0.504
graph view Graph view
table view Table view

0.949

22% from 2019

SNIP for Physics of Metals and Metallography from 2016 - 2020
Year Value
2020 0.949
2019 1.221
2018 1.204
2017 0.954
2016 1.152
graph view Graph view
table view Table view

insights Insights

  • CiteRatio of this journal has increased by 12% in last years.
  • This journal’s CiteRatio is in the top 10 percentile category.

insights Insights

  • SJR of this journal has decreased by 25% in last years.
  • This journal’s SJR is in the top 10 percentile category.

insights Insights

  • SNIP of this journal has decreased by 22% in last years.
  • This journal’s SNIP is in the top 10 percentile category.

Physics of Metals and Metallography

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Springer

Physics of Metals and Metallography

The Physics of Metals and Metallography (Fizika metallov i metallovedenie) was founded in 1955 by the USSR Academy of Sciences. Its scientific profile covers the theory of metals and metal alloys, their electrical and magnetic properties, as well as their structure, phase tran...... Read More

Materials Chemistry

Condensed Matter Physics

Materials Science

i
Last updated on
08 Jul 2020
i
ISSN
0031-918X
i
Impact Factor
High - 1.032
i
Open Access
No
i
Sherpa RoMEO Archiving Policy
Blue faq
i
Plagiarism Check
Available via Turnitin
i
Endnote Style
Download Available
i
Bibliography Name
SPBASIC
i
Citation Type
Author Year
(Blonder et al, 1982)
i
Bibliography Example
 Beenakker CWJ (2006) Specular andreev reflection in graphene. Phys Rev Lett 97(6):067,007, URL 10.1103/PhysRevLett.97.067007

Top papers written in this journal

Journal Article DOI: 10.1134/S0031918X11070052
Magnetocaloric effect in Ni-Mn-X (X = Ga, In, Sn, Sb) Heusler alloys
Vasiliy D. Buchelnikov1, Vladimir V. Sokolovskiy1
Chelyabinsk State University1
01 Dec 2011 - Physics of Metals and Metallography

Abstract:

A review is given of experimental and theoretical works concerning the investigation of magnetic and structural phase transitions and of the magnetocaloric effect in Ni-Mn-X (X = Ga, In, Sn, Sb) Heusler alloys possessing unique properties, such as the existence of coupled magnetostructural and metamagneto-structural phase tra... A review is given of experimental and theoretical works concerning the investigation of magnetic and structural phase transitions and of the magnetocaloric effect in Ni-Mn-X (X = Ga, In, Sn, Sb) Heusler alloys possessing unique properties, such as the existence of coupled magnetostructural and metamagneto-structural phase transitions, giant magnetocaloric effect, shape-memory effect in the ferromagnetic state, giant magnetodeformation and magnetoresistance, exchange anisotropy. A conclusion is made that the Heusler alloys, because of their unique properties, are promising for the application in various engineering devices, including technology of magnetic refrigeration. read more read less

Topics:

Magnetic refrigeration (59%)59% related to the paper, Exchange bias (56%)56% related to the paper, Ferromagnetism (55%)55% related to the paper, Magnetoresistance (53%)53% related to the paper, Phase transition (52%)52% related to the paper
130 Citations
Journal Article DOI: 10.1134/S0031918X10020110
New Martensitic Steels for Fossil Power Plant: Creep Resistance
R. O. Kaybyshev1, V. N. Skorobogatykh, I. A. Shchenkova
Belgorod State University1
01 Mar 2010 - Physics of Metals and Metallography

Abstract:

In this paper, we consider the origin of high-temperature strength of heat-resistant steels belonging to martensitic class developed on the basis of the Fe—9%Cr alloy for the boiler pipes and steam pipelines of power plants at steam temperatures of up to 620°C and pressures to 300 atm. In addition, we give a brief information... In this paper, we consider the origin of high-temperature strength of heat-resistant steels belonging to martensitic class developed on the basis of the Fe—9%Cr alloy for the boiler pipes and steam pipelines of power plants at steam temperatures of up to 620°C and pressures to 300 atm. In addition, we give a brief information on the physical processes that determine the creep strength and consider the alloying philosophy of traditional heat-resistant steels. The effect of the chemical and phase composition of heat-resistant steels and their structure on creep strength is analyzed in detail. It is shown that the combination of the solid-solution alloying by elements such as W and Mo, as well as the introduction of carbides of the MX type into the matrix with the formation of a dislocation structure of tempered martensite, ensures a significant increase in creep resistance. The steels of the martensitic class withstand creep until an extensive polygonization starts in the dislocation structure of the tempered martensite(“troostomartensite”), which is suppressed by V(C,N) and Nb(C,N) dispersoids. Correspondingly, the service life of these steels is determined by the time during which the dispersed nanocarbonitrides withstand coalescence, while tungsten and molybdenum remain in the solid solution. The precipitation of the Laves phases Fe2(W,Mo) and the coalescence of carbides lead to the development of migration of low-angle boundaries, and the steel loses its ability to resist creep. read more read less

Topics:

Creep (58%)58% related to the paper, Martensite (52%)52% related to the paper
94 Citations
Journal Article DOI: 10.1134/S0031918X12130030
Ferromagnetism of nanostructured zinc oxide films
Boris B. Straumal1, Andrei A. Mazilkin2, Svetlana G. Protasova2, P. B. Straumal, A. A. Myatiev3, Gisela Schütz2, Eberhard Goering2, Brigitte Baretzky1
Karlsruhe Institute of Technology1, Max Planck Society2, National University of Science and Technology3
19 Dec 2012 - Physics of Metals and Metallography

Abstract:

The paper presents a review of the causes of the occurrence of ferromagnetic properties in zinc oxide. It is shown that ferromagnetism only occurs in polycrystals at a fairly high density of grain boundaries. The critical grain size is about 20 nm for pure ZnO and over 1000 nm for zinc oxide doped with manganese. The solubili... The paper presents a review of the causes of the occurrence of ferromagnetic properties in zinc oxide. It is shown that ferromagnetism only occurs in polycrystals at a fairly high density of grain boundaries. The critical grain size is about 20 nm for pure ZnO and over 1000 nm for zinc oxide doped with manganese. The solubility of manganese and cobalt in zinc oxide increases considerably with diminishing grain size. Even at the critical grain size, the ferromagnetic properties depend significantly on the film texture and the struc� ture of intercrystalline amorphous layers. read more read less

Topics:

Grain boundary (58%)58% related to the paper, Zinc (57%)57% related to the paper, Ferromagnetic material properties (57%)57% related to the paper, Grain size (55%)55% related to the paper, Texture (crystalline) (52%)52% related to the paper
82 Citations
Journal Article DOI: 10.1134/S0031918X08120065
Effect of disperse Ti3N4 particles on the martensitic transformations in titanium nickelide single crystals
E. Yu. Panchenko1, Yu. I. Chumlyakov1, Irina Kireeva1, A. V. Ovsyannikov1, Huseyin Sehitoglu2, Ibrahim Karaman3, Y. H. J. Maier4
Tomsk State University1, University of Illinois at Urbana–Champaign2, Texas A&M University3, University of Paderborn4
18 Dec 2008 - Physics of Metals and Metallography

Abstract:

The effect of the size and volume fraction of Ti 3 N 4 particles in Ti-(50.3-51.5) at % Ni single crys- tals on their martensitic transformation temperatures and temperature hysteresis is studied. Aging at T = 673- 823 K leads to a nonmonotonic change in the martensitic transformation temperatures and temperature hyster- esis... The effect of the size and volume fraction of Ti 3 N 4 particles in Ti-(50.3-51.5) at % Ni single crys- tals on their martensitic transformation temperatures and temperature hysteresis is studied. Aging at T = 673- 823 K leads to a nonmonotonic change in the martensitic transformation temperatures and temperature hyster- esis, which is related to a change in the Ni concentration in the matrix, the hardening of the high-temperature phase, a change in the elastic and surface energies generated upon the martensitic transformations, and the inter- nal stresses that appear because of the difference in the lattice parameters of the particles and the matrix. As a result of the high strength of the B 2 phase and the high elastic and surface energies that are generated upon the martensitic transformations due to the precipitation of particles of size d < 40 nm at an interparticle distance λ < 50 nm, the martensitic transformation temperatures decrease down to the suppression of the R - B 19' transi- tions upon cooling to 77 K. A thermodynamic description for the martensitic transformations in heterophase crystals is proposed, and an analogy between the martensitic transformations in heterophase Ti-Ni single crys- tals with nanoparticles of size d = 20-100 nm and those in single-phase Ti-Ni polycrystals with a grain size of 50-200 nm is found. read more read less

Topics:

Diffusionless transformation (58%)58% related to the paper, Grain size (51%)51% related to the paper
70 Citations
Journal Article DOI: 10.1134/S0031918X07050122
Influence of the pearlite fineness on the mechanical properties, deformation behavior, and fracture characteristics of carbon steel
V. I. Izotov, V. A. Pozdnyakov, E. V. Luk’yanenko, O. Yu. Usanova, G. A. Filippov
01 May 2007 - Physics of Metals and Metallography

Abstract:

Specific features of plastic deformation and tensile failure of a plain carbon (C = 0.62%) pearlitic-ferritic steel with various pearlite fineness have been investigated. It is shown that the steels with coarse lamellar pearlite and fine lamellar pearlite have similar strain-hardening coefficients, but the relative elongation... Specific features of plastic deformation and tensile failure of a plain carbon (C = 0.62%) pearlitic-ferritic steel with various pearlite fineness have been investigated. It is shown that the steels with coarse lamellar pearlite and fine lamellar pearlite have similar strain-hardening coefficients, but the relative elongation of the former steel is higher. Deformation results in a uniform dislocation distribution in the fine pearlite and in the formation of a cellular substructure in the coarse pearlite. It is established that the fine pearlite undergoes plastic deformation and ductile failure as a single structure, while the coarse pearlite exhibits a structure discontinuity upon deformation. A model of microplastic pearlite deformation and the initial stage of macroplastic pearlite deformation is proposed. It is established that the strain-hardening coefficient of pearlite at the initial deformation stage does not depend on its dispersity. A size effect, which manifests itself in the dependence of the dislocation structure formed in the ferrite interlayers on their thickness, is shown to be characteristic of pearlite deformation. read more read less

Topics:

Pearlite (73%)73% related to the paper, Ferrite (iron) (55%)55% related to the paper, Deformation (engineering) (55%)55% related to the paper, Carbon steel (54%)54% related to the paper
65 Citations
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SHERPA/RoMEO Database

We extracted this data from Sherpa Romeo to help researchers understand the access level of this journal in accordance with the Sherpa Romeo Archiving Policy for Physics of Metals and Metallography. The table below indicates the level of access a journal has as per Sherpa Romeo's archiving policy.

RoMEO Colour Archiving policy
Green Can archive pre-print and post-print or publisher's version/PDF
Blue Can archive post-print (ie final draft post-refereeing) or publisher's version/PDF
Yellow Can archive pre-print (ie pre-refereeing)
White Archiving not formally supported
FYI:
  1. Pre-prints as being the version of the paper before peer review and
  2. Post-prints as being the version of the paper after peer-review, with revisions having been made.

14. What are the most common citation types In Physics of Metals and Metallography?

The 5 most common citation types in order of usage for Physics of Metals and Metallography are:.

S. No. Citation Style Type
1. Author Year
2. Numbered
3. Numbered (Superscripted)
4. Author Year (Cited Pages)
5. Footnote

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