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Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format
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Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format Example of Progress in Materials Science format
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open access Open Access
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Progress in Materials Science — Template for authors

Publisher: Elsevier
Guideline source
Categories Rank Trend in last 3 yrs
Materials Science (all) #1 of 455 up up by 3 ranks
journal-quality-icon Journal quality:
High
calendar-icon Last 4 years overview: 196 Published Papers | 12098 Citations
indexed-in-icon Indexed in: Scopus
last-updated-icon Last updated: 17/07/2020
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Journal Performance & Insights

Impact Factor

CiteRatio

Determines the importance of a journal by taking a measure of frequency with which the average article in a journal has been cited in a particular year.

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

31.56

33% from 2018

Impact factor for Progress in Materials Science from 2016 - 2019
Year Value
2019 31.56
2018 23.725
2017 23.75
2016 31.14
graph view Graph view
table view Table view

61.7

31% from 2019

CiteRatio for Progress in Materials Science from 2016 - 2020
Year Value
2020 61.7
2019 47.1
2018 39.6
2017 45.6
2016 44.2
graph view Graph view
table view Table view

insights Insights

  • Impact factor of this journal has increased by 33% in last year.
  • This journal’s impact factor is in the top 10 percentile category.

insights Insights

  • CiteRatio of this journal has increased by 31% in last years.
  • This journal’s CiteRatio is in the top 10 percentile category.

SCImago Journal Rank (SJR)

Source Normalized Impact per Paper (SNIP)

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.

9.172

13% from 2019

SJR for Progress in Materials Science from 2016 - 2020
Year Value
2020 9.172
2019 8.137
2018 7.649
2017 9.148
2016 9.256
graph view Graph view
table view Table view

10.558

2% from 2019

SNIP for Progress in Materials Science from 2016 - 2020
Year Value
2020 10.558
2019 10.389
2018 9.57
2017 11.655
2016 13.345
graph view Graph view
table view Table view

insights Insights

  • SJR of this journal has increased by 13% in last years.
  • This journal’s SJR is in the top 10 percentile category.

insights Insights

  • SNIP of this journal has increased by 2% in last years.
  • This journal’s SNIP is in the top 10 percentile category.

Progress in Materials Science

Guideline source: View

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Elsevier

Progress in Materials Science

Progress in Materials Science publishes authoritative reviews of recent advances in the science of materials and their exploitation in engineering. Emphasis is placed on the fundamental aspects of the subject, particularly those concerning microstructure and its relationship t...... Read More

Materials Science

i
Last updated on
16 Jul 2020
i
ISSN
0079-6425
i
Impact Factor
Maximum - 12.916
i
Open Access
No
i
Sherpa RoMEO Archiving Policy
Green faq
i
Plagiarism Check
Available via Turnitin
i
Endnote Style
Download Available
i
Bibliography Name
elsarticle-num
i
Citation Type
Numbered
[25]
i
Bibliography Example
 G. E. Blonder, M. Tinkham, T. M. Klapwijk, Transition from metallic to tunneling regimes in superconducting microconstrictions: Excess current, charge imbalance, and supercurrent conversion, Phys. Rev. B 25 (7) (1982) 4515–4532. URL 10.1103/PhysRevB.25.4515

Top papers written in this journal

Journal Article DOI: 10.1016/S0079-6425(99)00007-9
Bulk nanostructured materials from severe plastic deformation
Ruslan Z. Valiev1, Rinat K. Islamgaliev1, Igor V. Alexandrov1
Ufa State Aviation Technical University1
01 Mar 2000 - Progress in Materials Science

Abstract:

2. Methods of severe plastic deformation and formation of nanostructures . . . . . . . 105 2.1. SPD techniques and regimes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 2.1.1. Torsion straining under high pressure . . . . . . . . . . . . . . . . . . . . . 106 2.1.2. ECA pressing . . . . . . . . . . . ... 2. Methods of severe plastic deformation and formation of nanostructures . . . . . . . 105 2.1. SPD techniques and regimes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 2.1.1. Torsion straining under high pressure . . . . . . . . . . . . . . . . . . . . . 106 2.1.2. ECA pressing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108 2.1.3. Multiple forging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112 2.2. Typical nanostructures and their formation . . . . . . . . . . . . . . . . . . . . . . . 115 read more read less

Topics:

Accumulative roll bonding (56%)56% related to the paper, Severe plastic deformation (55%)55% related to the paper
5,763 Citations
Journal Article DOI: 10.1016/J.PMATSCI.2013.10.001
Microstructures and properties of high-entropy alloys
Yong Zhang1, Ting Ting Zuo1, Z. Tang2, Michael C. Gao3, Karin A. Dahmen4, Peter K. Liaw2, Zhaoping Lu1
University of Science and Technology Beijing1, University of Tennessee2, URS Corporation3, University of Illinois at Urbana–Champaign4
01 Apr 2014 - Progress in Materials Science

Abstract:

This paper reviews the recent research and development of high-entropy alloys (HEAs) HEAs are loosely defined as solid solution alloys that contain more than five principal elements in equal or near equal atomic percent (at%) The concept of high entropy introduces a new path of developing advanced materials with unique proper... This paper reviews the recent research and development of high-entropy alloys (HEAs) HEAs are loosely defined as solid solution alloys that contain more than five principal elements in equal or near equal atomic percent (at%) The concept of high entropy introduces a new path of developing advanced materials with unique properties, which cannot be achieved by the conventional micro-alloying approach based on only one dominant element Up to date, many HEAs with promising properties have been reported, eg, high wear-resistant HEAs, Co15CrFeNi15Ti and Al02Co15CrFeNi15Ti alloys; high-strength body-centered-cubic (BCC) AlCoCrFeNi HEAs at room temperature, and NbMoTaV HEA at elevated temperatures Furthermore, the general corrosion resistance of the Cu05NiAlCoCrFeSi HEA is much better than that of the conventional 304-stainless steel This paper first reviews HEA formation in relation to thermodynamics, kinetics, and processing Physical, magnetic, chemical, and mechanical properties are then discussed Great details are provided on the plastic deformation, fracture, and magnetization from the perspectives of crackling noise and Barkhausen noise measurements, and the analysis of serrations on stress–strain curves at specific strain rates or testing temperatures, as well as the serrations of the magnetization hysteresis loops The comparison between conventional and high-entropy bulk metallic glasses is analyzed from the viewpoints of eutectic composition, dense atomic packing, and entropy of mixing Glass forming ability and plastic properties of high-entropy bulk metallic glasses are also discussed Modeling techniques applicable to HEAs are introduced and discussed, such as ab initio molecular dynamics simulations and CALPHAD modeling Finally, future developments and potential new research directions for HEAs are proposed read more read less

Topics:

High entropy alloys (59%)59% related to the paper
4,394 Citations
Journal Article DOI: 10.1016/J.PMATSCI.2017.10.001
Additive manufacturing of metallic components – Process, structure and properties
Tarasankar Debroy1, Huiliang Wei1, J.S. Zuback1, T. Mukherjee1, John W. Elmer2, John O. Milewski, Allison M. Beese1, Alexander E. Wilson-Heid1, Amitava De3, Wei Zhang4
Pennsylvania State University1, Lawrence Livermore National Laboratory2, Indian Institute of Technology Bombay3, Ohio State University4
01 Mar 2018 - Progress in Materials Science

Abstract:

Since its inception, significant progress has been made in understanding additive manufacturing (AM) processes and the structure and properties of the fabricated metallic components. Because the field is rapidly evolving, a periodic critical assessment of our understanding is useful and this paper seeks to address this need. ... Since its inception, significant progress has been made in understanding additive manufacturing (AM) processes and the structure and properties of the fabricated metallic components. Because the field is rapidly evolving, a periodic critical assessment of our understanding is useful and this paper seeks to address this need. It covers the emerging research on AM of metallic materials and provides a comprehensive overview of the physical processes and the underlying science of metallurgical structure and properties of the deposited parts. The uniqueness of this review includes substantive discussions on refractory alloys, precious metals and compositionally graded alloys, a succinct comparison of AM with welding and a critical examination of the printability of various engineering alloys based on experiments and theory. An assessment of the status of the field, the gaps in the scientific understanding and the research needs for the expansion of AM of metallic components are provided. read more read less
4,192 Citations
Journal Article DOI: 10.1016/J.PMATSCI.2008.06.004
Ti based biomaterials, the ultimate choice for orthopaedic implants – A review
M. Geetha1, Anil Kumar Singh2, R. Asokamani1, A.K. Gogia
VIT University1, Defence Metallurgical Research Laboratory2
01 May 2009 - Progress in Materials Science

Abstract:

The field of biomaterials has become a vital area, as these materials can enhance the quality and longevity of human life and the science and technology associated with this field has now led to multi-million dollar business. The paper focuses its attention mainly on titanium-based alloys, even though there exists biomaterial... The field of biomaterials has become a vital area, as these materials can enhance the quality and longevity of human life and the science and technology associated with this field has now led to multi-million dollar business. The paper focuses its attention mainly on titanium-based alloys, even though there exists biomaterials made up of ceramics, polymers and composite materials. The paper discusses the biomechanical compatibility of many metallic materials and it brings out the overall superiority of Ti based alloys, even though it is costlier. As it is well known that a good biomaterial should possess the fundamental properties such as better mechanical and biological compatibility and enhanced wear and corrosion resistance in biological environment, the paper discusses the influence of alloy chemistry, thermomechanical processing and surface condition on these properties. In addition, this paper also discusses in detail the various surface modification techniques to achieve superior biocompatibility, higher wear and corrosion resistance. Overall, an attempt has been made to bring out the current scenario of Ti based materials for biomedical applications. read more read less

Topics:

Biomaterial (52%)52% related to the paper
View PDF
4,113 Citations
Journal Article DOI: 10.1016/J.PMATSCI.2005.08.003
Mechanical properties of nanocrystalline materials
Marc A. Meyers1, A. Mishra1, David J. Benson1
University of California, San Diego1
01 May 2006 - Progress in Materials Science

Abstract:

The mechanical properties of nanocrystalline materials are reviewed, with emphasis on their constitutive response and on the fundamental physical mechanisms. In a brief introduction, the most important synthesis methods are presented. A number of aspects of mechanical behavior are discussed, including the deviation from the H... The mechanical properties of nanocrystalline materials are reviewed, with emphasis on their constitutive response and on the fundamental physical mechanisms. In a brief introduction, the most important synthesis methods are presented. A number of aspects of mechanical behavior are discussed, including the deviation from the Hall–Petch slope and possible negative slope, the effect of porosity, the difference between tensile and compressive strength, the limited ductility, the tendency for shear localization, the fatigue and creep responses. The strain-rate sensitivity of FCC metals is increased due to the decrease in activation volume in the nanocrystalline regime; for BCC metals this trend is not observed, since the activation volume is already low in the conventional polycrystalline regime. In fatigue, it seems that the S–N curves show improvement due to the increase in strength, whereas the da/dN curve shows increased growth velocity (possibly due to the smoother fracture requiring less energy to propagate). The creep results are conflicting: while some results indicate a decreased creep resistance consistent with the small grain size, other experimental results show that the creep resistance is not negatively affected. Several mechanisms that quantitatively predict the strength of nanocrystalline metals in terms of basic defects (dislocations, stacking faults, etc.) are discussed: break-up of dislocation pile-ups, core-and-mantle, grain-boundary sliding, grain-boundary dislocation emission and annihilation, grain coalescence, and gradient approach. Although this classification is broad, it incorporates the major mechanisms proposed to this date. The increased tendency for twinning, a direct consequence of the increased separation between partial dislocations, is discussed. The fracture of nanocrystalline metals consists of a mixture of ductile dimples and shear regions; the dimple size, while much smaller than that of conventional polycrystalline metals, is several times larger than the grain size. The shear regions are a direct consequence of the increased tendency of the nanocrystalline metals to undergo shear localization. The major computational approaches to the modeling of the mechanical processes in nanocrystalline metals are reviewed with emphasis on molecular dynamics simulations, which are revealing the emission of partial dislocations at grain boundaries and their annihilation after crossing them. read more read less

Topics:

Grain boundary (61%)61% related to the paper, Grain boundary strengthening (59%)59% related to the paper, Creep (58%)58% related to the paper, Dislocation (55%)55% related to the paper, Partial dislocations (55%)55% related to the paper
3,828 Citations
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Frequently asked questions

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Yes, the template is compliant with the Progress in Materials Science guidelines. Our experts at SciSpace ensure that. If there are any changes to the journal's guidelines, we'll change our algorithm accordingly.

3. Can I cite my article in multiple styles in Progress in Materials Science?

Of course! We support all the top citation styles, such as APA style, MLA style, Vancouver style, Harvard style, and Chicago style. For example, when you write your paper and hit autoformat, our system will automatically update your article as per the Progress in Materials Science citation style.

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Sign up for our free trial, and you'll be able to use all our features for seven days. You'll see how helpful they are and how inexpensive they are compared to other options, Especially for Progress in Materials Science.

5. Can I use a manuscript in Progress in Materials Science that I have written in MS Word?

Yes. You can choose the right template, copy-paste the contents from the word document, and click on auto-format. Once you're done, you'll have a publish-ready paper Progress in Materials Science that you can download at the end.

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Of course! You can do this using our intuitive editor. It's very easy. If you need help, our support team is always ready to assist you.

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SciSpace's Progress in Materials Science is currently available as an online tool. We're developing a desktop version, too. You can request (or upvote) any features that you think would be helpful for you and other researchers in the "feature request" section of your account once you've signed up with us.

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After writing your paper autoformatting in Progress in Materials Science, you can download it in multiple formats, viz., PDF, Docx, and LaTeX.

12. Is Progress in Materials Science's impact factor high enough that I should try publishing my article there?

To be honest, the answer is no. The impact factor is one of the many elements that determine the quality of a journal. Few of these factors include review board, rejection rates, frequency of inclusion in indexes, and Eigenfactor. You need to assess all these factors before you make your final call.

13. What is Sherpa RoMEO Archiving Policy for Progress in Materials Science?

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 Progress in Materials Science. 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 Progress in Materials Science?

The 5 most common citation types in order of usage for Progress in Materials Science 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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16. Can I download Progress in Materials Science in Endnote format?

Yes, SciSpace provides this functionality. After signing up, you would need to import your existing references from Word or Bib file to SciSpace. Then SciSpace would allow you to download your references in Progress in Materials Science Endnote style according to Elsevier guidelines.

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