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Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format
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Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format Example of Advanced Materials Interfaces format
Sample paper formatted on SciSpace - SciSpace
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Advanced Materials Interfaces — Template for authors

Publisher: Wiley
Guideline source
Categories Rank Trend in last 3 yrs
Mechanical Engineering #44 of 596 down down by 5 ranks
Mechanics of Materials #31 of 377 down down by 6 ranks
journal-quality-icon Journal quality:
High
calendar-icon Last 4 years overview: 2085 Published Papers | 16445 Citations
indexed-in-icon Indexed in: Scopus
last-updated-icon Last updated: 16/05/2022
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Related Journals

open access Open Access

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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.

7.9

10% from 2019

CiteRatio for Advanced Materials Interfaces from 2016 - 2020
Year Value
2020 7.9
2019 7.2
2018 6.4
2017 5.9
2016 3.7
graph view Graph view
table view Table view

1.671

8% from 2019

SJR for Advanced Materials Interfaces from 2016 - 2020
Year Value
2020 1.671
2019 1.55
2018 1.57
2017 1.796
2016 1.545
graph view Graph view
table view Table view

1.006

10% from 2019

SNIP for Advanced Materials Interfaces from 2016 - 2020
Year Value
2020 1.006
2019 0.916
2018 0.849
2017 0.841
2016 0.909
graph view Graph view
table view Table view

insights Insights

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

insights Insights

  • SJR of this journal has increased by 8% in last years.
  • This journal’s SJR is in the top 10 percentile category.

insights Insights

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

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Wiley

Advanced Materials Interfaces

Approved by publishing and review experts on SciSpace, this template is built as per for Advanced Materials Interfaces formatting guidelines as mentioned in Wiley author instructions. The current version was created on 16 May 2022 and has been used by 231 authors to write and format their manuscripts to this journal.

Engineering

i
Last updated on
16 May 2022
i
ISSN
2196-7350
i
Sherpa RoMEO Archiving Policy
Yellow faq
i
Plagiarism Check
Available via Turnitin
i
Endnote Style
Download Available
i
Bibliography Name
apa
i
Citation Type
Numbered
[25]
i
Bibliography Example
 G. E. Blonder, Phys. Rev. Lett., 2006, 97, 067007.

Top papers written in this journal

open accessOpen access Journal Article DOI: 10.1002/ADMI.201500195
Silver Iodide Formation in Methyl Ammonium Lead Iodide Perovskite Solar Cells with Silver Top Electrodes
Yuichi Kato1, Luis K. Ono1, Michael V. Lee1, Shenghao Wang1, Sonia R. Raga1, Yabing Qi1
Okinawa Institute of Science and Technology1
01 Sep 2015 - Advanced Materials Interfaces

Abstract:

Silver is a low-cost candidate electrode material for perovskite solar cells. However, in such cells the silver electrodes turn yellow within days of device fabrication. The color change is also accompanied by a dramatic decrease in the power conversion efficiency when compared to otherwise identical devices using gold electr... Silver is a low-cost candidate electrode material for perovskite solar cells. However, in such cells the silver electrodes turn yellow within days of device fabrication. The color change is also accompanied by a dramatic decrease in the power conversion efficiency when compared to otherwise identical devices using gold electrodes. Here, it is shown that the color change results from silver oxidation to silver iodide, due to a reaction with iodine in methyl ammonium lead perovskite. The change in X-ray diffraction and X-ray photo­electron spectroscopy is discussed. Exposure to air accelerates corrosion of the Ag electrodes when compared to dry nitrogen gas exposure. However, iodine not reacted with silver is observed by X-ray photoelectron spectroscopy even for the perovskite solar cell kept in dry nitrogen gas. It is proposed that silver iodide is formed when methyl ammonium iodide migration is facilitated by the small pinholes in the hole transport layer spiro-MeOTAD. read more read less

Topics:

Silver iodide (68%)68% related to the paper, Iodide (64%)64% related to the paper, Ammonium iodide (59%)59% related to the paper, Perovskite solar cell (57%)57% related to the paper, Iodine (54%)54% related to the paper
View PDF
613 Citations
Journal Article DOI: 10.1002/ADMI.201800848
Ultrathin Surface Coating Enables Stabilized Zinc Metal Anode
Kangning Zhao1, Kangning Zhao2, Chenxu Wang1, Yanhao Yu2, Mengyu Yan1, Qiulong Wei1, Pan He1, Yifan Dong1, Ziyi Zhang2, Xudong Wang2, Liqiang Mai1
Wuhan University of Technology1, University of Wisconsin-Madison2
01 Aug 2018 - Advanced Materials Interfaces

Abstract:

DOI: 10.1002/admi.201800848 electrolyte-based batteries can provide structural robustness and cost advantages over competing lithium-ion batteries. Among those aqueous batteries, zinc metal batteries with zinc as anode including zinc-air battery and Zn–MnO2 battery has been investigated intensively due to its high theoretical... DOI: 10.1002/admi.201800848 electrolyte-based batteries can provide structural robustness and cost advantages over competing lithium-ion batteries. Among those aqueous batteries, zinc metal batteries with zinc as anode including zinc-air battery and Zn–MnO2 battery has been investigated intensively due to its high theoretical capacity (820 mAh g−1), low negative potential (−0.762 V vs SHE), abundance, low toxicity, and the intrinsic safety advantages.[18–30] In this regard, aqueous zinc ion batteries are expected to make substantial impacts toward advanced energy storage technologies, especially in stationary grid storage. Despite the current success in exploration of cathode (including air cathode, MnO2, and so on),[20,21,23,31–35] an important barrier of the Zn-based batteries is the poor cycle life, which mainly derives from the drawbacks of the Zn metal anode and the electrolyte. The zinc corrosion behavior in the alkaline electrolyte has been studied long time ago. Several successful strategies have been adopted to address the issue through the use of soluble additives in the alkaline electrolyte,[36] the redesign of zinc anode into three dimensional zinc foam[37] and so on. However, to date, there are few reports concerning the zinc anode protection in neutral or mild acidic aqueous electrolytes. Compared with the alkaline electrolyte where the charge carrier is Zn(OH)4 read more read less

Topics:

Surface coating (63%)63% related to the paper, Anode (62%)62% related to the paper
423 Citations
open accessOpen access Journal Article DOI: 10.1002/ADMI.201800074
A review of self-healing concrete for damage management of structures
Nele De Belie1, Elke Gruyaert2, Abir Al-Tabbaa3, Paola Antonaci4, Cornelia Baera, Diana Bajare5, Aveline Darquennes6, Robert Davies7, Liberato Ferrara8, Tony Jefferson7, Chrysoula Litina3, Bojan Miljević9, Anna Otlewska10, Jonjaua Ranogajec9, Marta Roig-Flores, Kevin Paine11, Pawel Lukowski12, Pedro Serna13, Jean Marc Christian Tulliani4, Snezana Vucetic9, Jianyun Wang1, Henk M. Jonkers14
Ghent University1, Katholieke Universiteit Leuven2, University of Cambridge3, Polytechnic University of Turin4, Riga Technical University5, Institut national des sciences appliquées de Rennes6, Cardiff University7, Polytechnic University of Milan8, University of Novi Sad9, Lodz University of Technology10, University of Bath11, Warsaw University of Technology12, Polytechnic University of Valencia13, Delft University of Technology14
01 Sep 2018 - Advanced Materials Interfaces

Abstract:

The increasing concern for safety and sustainability of structures is calling for the development of smart self-healing materials and preventive repair methods. The appearance of small cracks (<300 µm in width) in concrete is almost unavoidable, not necessarily causing a risk of collapse for the structure, but surely impairin... The increasing concern for safety and sustainability of structures is calling for the development of smart self-healing materials and preventive repair methods. The appearance of small cracks (<300 µm in width) in concrete is almost unavoidable, not necessarily causing a risk of collapse for the structure, but surely impairing its functionality, accelerating its degradation, and diminishing its service life and sustainability. This review provides the state-of-the-art of recent developments of self-healing concrete, covering autogenous or intrinsic healing of traditional concrete followed by stimulated autogenous healing via use of mineral additives, crystalline admixtures or (superabsorbent) polymers, and subsequently autonomous self-healing mechanisms, i.e. via, application of micro-, macro-, or vascular encapsulated polymers, minerals, or bacteria. The (stimulated) autogenous mechanisms are generally limited to healing crack widths of about 100–150 µm. In contrast, most autonomous self-healing mechanisms can heal cracks of 300 µm, even sometimes up to more than 1 mm, and usually act faster. After explaining the basic concept for each self-healing technique, the most recent advances are collected, explaining the progress and current limitations, to provide insights toward the future developments. This review addresses the research needs required to remove hindrances that limit market penetration of self-healing concrete technologies. read more read less
View PDF
355 Citations
Journal Article DOI: 10.1002/ADMI.201400227
Strongly Coupled Interfaces between a Heterogeneous Carbon Host and a Sulfur-Containing Guest for Highly Stable Lithium-Sulfur Batteries: Mechanistic Insight into Capacity Degradation
Hong-Jie Peng1, Ting-Zheng Hou1, Qiang Zhang1, Jia-Qi Huang1, Xin-Bing Cheng1, Mengqing Guo1, Zhe Yuan1, Lian-Yuan He1, Fei Wei1
Tsinghua University1
01 Oct 2014 - Advanced Materials Interfaces

Abstract:

The use of conductive frameworks as the host scaffold to obtain nanostructured sulfur cathodes is an efficient way to increase the sulfur utilization for redox reaction in Li-S batteries with large discharge capacity and high energy density. However, due to dynamical interfaces driven by phase evolution between the conductive... The use of conductive frameworks as the host scaffold to obtain nanostructured sulfur cathodes is an efficient way to increase the sulfur utilization for redox reaction in Li-S batteries with large discharge capacity and high energy density. However, due to dynamical interfaces driven by phase evolution between the conductive hosts and S-containing guests during cycling, the cathode still faces poor stability. Herein, the use of O-/N-containing nanocarbon as the conductive host sheds a light on the role of the dynamic interface between the carbon host and S-containing guest for a stable Li-S cell. The outstanding reversibility and stability of N-doped C/S cathodes are attributed to the favorable guest-host interaction at the electron-modified interface, manifesting as (i) a chemical gradient to adsorb polar polysulfides and (ii) ameliorative deposition and recharging of Li2S on the region of electron-rich pyridinic N and a graphene domain surrounding quaternary N. Highly reversible, efficient and stable Li storage properties such as mitigated polarization and charge barrier, high capacity of 1370 and 964 mAh g−1 at 0.1 and 1.0 C, respectively, and 70% of capacity retention after 200 cycles are achieved. Mechanistic insight into the capacity fading inspires the rational design on electrodes for high-performance electrochemical systems. read more read less

Topics:

Sulfur utilization (61%)61% related to the paper
343 Citations
Journal Article DOI: 10.1002/ADMI.201500309
Recent Advancements in All-Vanadium Redox Flow Batteries
Mani Ulaganathan1, Vanchiappan Aravindan1, Qingyu Yan1, Srinivasan Madhavi1, Maria Skyllas-Kazacos2, Tuti Mariana Lim1
Nanyang Technological University1, University of New South Wales2
01 Jan 2016 - Advanced Materials Interfaces

Abstract:

Over the past three decades, intensive research activities have focused on the development of electrochemical energy storage devices, particularly exploiting the concept of flow batteries. Amongst these, vanadium redox flow batteries (VRFB) are an attractive option, which have been studied extensively and are now being commer... Over the past three decades, intensive research activities have focused on the development of electrochemical energy storage devices, particularly exploiting the concept of flow batteries. Amongst these, vanadium redox flow batteries (VRFB) are an attractive option, which have been studied extensively and are now being commercialized around the world. The performance of the VRFB system is governed by several critical components namely the electrolyte, the electrode, the ion-exchange membrane and the flow field design. Here, the focus is mainly on recent research activities relating to the development and modification of electrode materials and new ion-exchange membranes. The feasibility of novel flow field designs for high energy density VRFB systems and their future prospects are also discussed in detail. read more read less
334 Citations
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Frequently asked questions

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Absolutely not! Our tool has been designed to help you focus on writing. You can write your entire paper as per the Advanced Materials Interfaces guidelines and auto format it.

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Yes, the template is compliant with the Advanced Materials Interfaces 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 Advanced Materials Interfaces?

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 Advanced Materials Interfaces 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 Advanced Materials Interfaces.

5. Can I use a manuscript in Advanced Materials Interfaces 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 Advanced Materials Interfaces that you can download at the end.

6. How long does it usually take you to format my papers in Advanced Materials Interfaces?

It only takes a matter of seconds to edit your manuscript. Besides that, our intuitive editor saves you from writing and formatting it in Advanced Materials Interfaces.

7. Where can I find the template for the Advanced Materials Interfaces?

It is possible to find the Word template for any journal on Google. However, why use a template when you can write your entire manuscript on SciSpace , auto format it as per Advanced Materials Interfaces's guidelines and download the same in Word, PDF and LaTeX formats? Give us a try!.

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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 Advanced Materials Interfaces 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 Advanced Materials Interfaces, you can download it in multiple formats, viz., PDF, Docx, and LaTeX.

12. Is Advanced Materials Interfaces'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 Advanced Materials Interfaces?

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 Advanced Materials Interfaces. 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 Advanced Materials Interfaces?

The 5 most common citation types in order of usage for Advanced Materials Interfaces are:.

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

15. How do I submit my article to the Advanced Materials Interfaces?

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16. Can I download Advanced Materials Interfaces 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 Advanced Materials Interfaces Endnote style according to Elsevier guidelines.

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