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Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format
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Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format Example of Advanced Electronic Materials format
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Advanced Electronic Materials — Template for authors

Publisher: Wiley
Guideline source
Categories Rank Trend in last 3 yrs
Electronic, Optical and Magnetic Materials #26 of 246 up up by 7 ranks
journal-quality-icon Journal quality:
High
calendar-icon Last 4 years overview: 1210 Published Papers | 11411 Citations
indexed-in-icon Indexed in: Scopus
last-updated-icon Last updated: 23/02/2023
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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.

9.4

3% from 2019

CiteRatio for Advanced Electronic Materials from 2016 - 2020
Year Value
2020 9.4
2019 9.1
2018 8.3
2017 5.4
2016 2.4
graph view Graph view
table view Table view

2.25

8% from 2019

SJR for Advanced Electronic Materials from 2016 - 2020
Year Value
2020 2.25
2019 2.454
2018 2.26
2017 2.129
2016 2.564
graph view Graph view
table view Table view

1.409

4% from 2019

SNIP for Advanced Electronic Materials from 2016 - 2020
Year Value
2020 1.409
2019 1.355
2018 1.173
2017 1.232
2016 1.023
graph view Graph view
table view Table view

insights Insights

  • CiteRatio of this journal has increased by 3% in last years.
  • This journal’s CiteRatio is in the top 10 percentile category.

insights Insights

  • SJR of this journal has decreased 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 4% in last years.
  • This journal’s SNIP is in the top 10 percentile category.
Advanced Electronic Materials

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Wiley

Advanced Electronic Materials

Approved by publishing and review experts on SciSpace, this template is built as per for Advanced Electronic Materials formatting guidelines as mentioned in Wiley author instructions. The current version was created on 23 Feb 2023 and has been used by 419 authors to write and format their manuscripts to this journal.

Electronic, Optical and Magnetic Materials

Materials Science

i
Last updated on
23 Feb 2023
i
ISSN
2199-160X
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
 Beenakker, C.W.J. (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

open accessOpen access Journal Article DOI: 10.1002/AELM.201600255
Effect of Synthesis on Quality, Electronic Properties and Environmental Stability of Individual Monolayer Ti3C2 MXene Flakes
Alexey Lipatov1, Mohamed Alhabeb2, Maria R. Lukatskaya2, Alex Boson1, Yury Gogotsi2, Alexander Sinitskii1
University of Nebraska–Lincoln1, Drexel University2
01 Dec 2016 - Advanced electronic materials

Abstract:

2D transition metal carbide Ti3C2Tx (T stands for surface termination), the most widely studied MXene, has shown outstanding electrochemical properties and promise for a number of bulk applications. However, electronic properties of individual MXene flakes, which are important for understanding the potential of these material... 2D transition metal carbide Ti3C2Tx (T stands for surface termination), the most widely studied MXene, has shown outstanding electrochemical properties and promise for a number of bulk applications. However, electronic properties of individual MXene flakes, which are important for understanding the potential of these materials, remain largely unexplored. Herein, a modified synthetic method is reported for producing high-quality monolayer Ti3C2Tx flakes. Field-effect transistors (FETs) based on monolayer Ti3C2Tx flakes are fabricated and their electronic properties are measured. Individual Ti3C2Tx flakes exhibit a high conductivity of 4600 ± 1100 S cm−1 and field-effect electron mobility of 2.6 ± 0.7 cm2 V−1 s−1. The resistivity of multilayer Ti3C2Tx films is only one order of magnitude higher than the resistivity of individual flakes, which indicates a surprisingly good electron transport through the surface terminations of different flakes, unlike in many other 2D materials. Finally, the fabricated FETs are used to investigate the environmental stability and kinetics of oxidation of Ti3C2Tx flakes in humid air. The high-quality Ti3C2Tx flakes are reasonably stable and remain highly conductive even after their exposure to air for more than 24 h. It is demonstrated that after the initial exponential decay the conductivity of Ti3C2Tx flakes linearly decreases with time, which is consistent with their edge oxidation. read more read less

Topics:

Monolayer (51%)51% related to the paper
View PDF
981 Citations
open accessOpen access Journal Article DOI: 10.1002/AELM.201600501
Ultrawide-Bandgap Semiconductors: Research Opportunities and Challenges
Jeffrey Y. Tsao1, Srabanti Chowdhury2, Mark A. Hollis3, Debdeep Jena4, N. M. Johnson, Kenneth A. Jones5, Robert Kaplar1, Siddharth Rajan6, C. G. Van de Walle7, Enrico Bellotti8, C. L. Chua, Ramon Collazo9, Michael E. Coltrin1, J. A. Cooper10, Keith R. Evans, Samuel Graham11, Timothy A. Grotjohn12, Eric R. Heller13, Masataka Higashiwaki14, M. S. Islam2, P. W. Juodawlkis3, Muhammad Asif Khan15, Andrew D. Koehler16, Jacob H. Leach, Umesh K. Mishra7, Robert J. Nemanich17, Robert C. N. Pilawa-Podgurski18, Jeffrey B. Shealy, Zlatko Sitar9, Marko J. Tadjer16, Arthur F. Witulski19, Michael Wraback5, Jerry A. Simmons1
Sandia National Laboratories1, University of California, Davis2, Massachusetts Institute of Technology3, Cornell University4, United States Army Research Laboratory5, Ohio State University6, University of California, Santa Barbara7, Boston University8, North Carolina State University9, Purdue University10, Georgia Institute of Technology11, Michigan State University12, Air Force Research Laboratory13, National Institute of Information and Communications Technology14, University of South Carolina15, United States Naval Research Laboratory16, Arizona State University17, University of Illinois at Urbana–Champaign18, Vanderbilt University19
01 Jan 2018 - Advanced electronic materials

Abstract:

J. Y. Tsao,* S. Chowdhury, M. A. Hollis,* D. Jena, N. M. Johnson, K. A. Jones, R. J. Kaplar,* S. Rajan, C. G. Van de Walle, E. Bellotti, C. L. Chua, R. Collazo, M. E. Coltrin, J. A. Cooper, K. R. Evans, S. Graham, T. A. Grotjohn, E. R. Heller, M. Higashiwaki, M. S. Islam, P. W. Juodawlkis, M. A. Khan, A. D. Koehler, J. H. Lea... J. Y. Tsao,* S. Chowdhury, M. A. Hollis,* D. Jena, N. M. Johnson, K. A. Jones, R. J. Kaplar,* S. Rajan, C. G. Van de Walle, E. Bellotti, C. L. Chua, R. Collazo, M. E. Coltrin, J. A. Cooper, K. R. Evans, S. Graham, T. A. Grotjohn, E. R. Heller, M. Higashiwaki, M. S. Islam, P. W. Juodawlkis, M. A. Khan, A. D. Koehler, J. H. Leach, U. K. Mishra, R. J. Nemanich, R. C. N. Pilawa-Podgurski, J. B. Shealy, Z. Sitar, M. J. Tadjer, A. F. Witulski, M. Wraback, and J. A. Simmons read more read less
View PDF
785 Citations
Journal Article DOI: 10.1002/AELM.201500017
Effective Approaches to Improve the Electrical Conductivity of PEDOT:PSS: A Review
Hui Shi1, Congcong Liu1, Qinglin Jiang1, Jingkun Xu1
Jiangxi Science and Technology Normal University1
01 Apr 2015 - Advanced electronic materials

Abstract:

The rapid development of novel organic technologies has led to significant applications of the organic electronic devices such as light-emitting diodes, solar cells, and field-effect transistors. There is a great need for conducting polymers with high conductivity and transparency to act as the charge transport layer or elect... The rapid development of novel organic technologies has led to significant applications of the organic electronic devices such as light-emitting diodes, solar cells, and field-effect transistors. There is a great need for conducting polymers with high conductivity and transparency to act as the charge transport layer or electrical interconnect in organic devices. Poly(3,4-ethylenedioxythiophene): poly(styrenesulfonic acid) (PEDOT:PSS), well-known as the most remarkable conducting polymer, has this role owing to its good film-forming properties, high transparency, tunable conductivity, and excellent thermal stability. In this Review, various of interesting physical and chemical approaches that can effectively improve the electrical conductivity of PEDOT:PSS are summarized, focusing especially on the mechanism of the conductivity enhancement as well as applications of PEDOT:PSS films. Prospects for future research efforts are also provided. It is expected that PEDOT:PSS films with high conductivity and transparency could be the focus of future organic electronic materials breakthroughs. read more read less

Topics:

PEDOT:PSS (63%)63% related to the paper, Conductive polymer (59%)59% related to the paper
751 Citations
open accessOpen access Journal Article DOI: 10.1002/AELM.201600050
Fabrication of Ti3C2Tx MXene Transparent Thin Films with Tunable Optoelectronic Properties
Kanit Hantanasirisakul1, Meng-Qiang Zhao1, Patrick Urbankowski1, Joseph Halim1, Babak Anasori1, Sankalp Kota1, Chang E. Ren1, Michel W. Barsoum1, Yury Gogotsi1
Drexel University1
01 Jun 2016 - Advanced electronic materials

Abstract:

MXenes, a new class of 2D transition metal carbides and carbonitrides, show great promise in supercapacitors, Li-ion batteries, fuel cells, and sensor applications. A unique combination of their metallic conductivity, hydrophilic surface, and excellent mechanical properties renders them attractive for transparent conductive e... MXenes, a new class of 2D transition metal carbides and carbonitrides, show great promise in supercapacitors, Li-ion batteries, fuel cells, and sensor applications. A unique combination of their metallic conductivity, hydrophilic surface, and excellent mechanical properties renders them attractive for transparent conductive electrode application. Here, a simple, scalable method is proposed to fabricate transparent conductive thin films using delaminated Ti3C2 MXene flakes by spray coating. Homogenous films, 5–70 nm thick, are produced at ambient conditions over a large area as shown by scanning electron microscopy and atomic force microscopy. The sheet resistances (Rs) range from 0.5 to 8 kΩ sq−1 at 40% to 90% transmittance, respectively, which corresponds to figures of merit (the ratio of electronic to optical conductivities, σDC/σopt) around 0.5–0.7. Flexible, transparent, and conductive films are also produced and exhibit stable Rs values at up to 5 mm bend radii. Furthermore, the films' optoelectronic properties are tuned by chemical or electrochemical intercalation of cations. The films show reversible changes of transmittance in the UV–visible region during electrochemical intercalation/deintercalation of tetramethylammonium hydroxide. This work shows the potential of MXenes to be used as transparent conductors in electronic, electrochromic, and sensor applications. read more read less

Topics:

Transparent conducting film (61%)61% related to the paper, MXenes (59%)59% related to the paper, Electrochromism (53%)53% related to the paper, Thin film (52%)52% related to the paper, Transmittance (51%)51% related to the paper
529 Citations
open accessOpen access Journal Article DOI: 10.1002/AELM.201800143
Recommended Methods to Study Resistive Switching Devices
Mario Lanza1, H.-S. Philip Wong2, Eric Pop2, Daniele Ielmini3, Dimitri Strukov4, B. C. Regan5, Luca Larcher6, Marco A. Villena2, Jianhua Yang7, Ludovic Goux8, Attilio Belmonte8, Yuchao Yang9, Francesco Maria Puglisi6, Jinfeng Kang9, Blanka Magyari-Köpe2, Eilam Yalon2, Anthony J. Kenyon, Mark Buckwell, Adnan Mehonic, Alexander L. Shluger10, Haitong Li2, Tuo-Hung Hou11, Boris Hudec11, Deji Akinwande12, Ruijing Ge12, Stefano Ambrogio13, Juan Bautista Roldán14, Enrique Miranda15, Jordi Suñé15, Kin Leong Pey16, Xing Wu17, Nagarajan Raghavan16, Ernest Y. Wu13, Wei Lu18, Gabriele Navarro, Weidong Zhang19, Huaqiang Wu20, Run-Wei Li21, Alexander W. Holleitner22, Ursula Wurstbauer22, Max C. Lemme23, Ming Liu21, Shibing Long21, Qi Liu21, Hangbing Lv21, Andrea Padovani, Paolo Pavan6, Ilia Valov23, Xu Jing1, Tingting Han1, Kaichen Zhu1, Shaochuan Chen1, Fei Hui1, Yuanyuan Shi1
Soochow University (Suzhou)1, Stanford University2, Polytechnic University of Milan3, University of California, Santa Barbara4, University of California, Los Angeles5, University of Modena and Reggio Emilia6, University of Massachusetts Amherst7, Katholieke Universiteit Leuven8, Peking University9, University College London10, National Chiao Tung University11, University of Texas at Austin12, IBM13, University of Granada14, Autonomous University of Barcelona15, Singapore University of Technology and Design16, East China Normal University17, University of Michigan18, Liverpool John Moores University19, Tsinghua University20, Chinese Academy of Sciences21, Technische Universität München22, RWTH Aachen University23
01 Jan 2019 - Advanced electronic materials

Abstract:

Resistive switching (RS) is an interesting property shown by some materials systems that, especially during the last decade, has gained a lot of interest for the fabrication of electronic devices, with electronic nonvolatile memories being those that have received the most attention. The presence and quality of the RS phenome... Resistive switching (RS) is an interesting property shown by some materials systems that, especially during the last decade, has gained a lot of interest for the fabrication of electronic devices, with electronic nonvolatile memories being those that have received the most attention. The presence and quality of the RS phenomenon in a materials system can be studied using different prototype cells, performing different experiments, displaying different figures of merit, and developing different computational analyses. Therefore, the real usefulness and impact of the findings presented in each study for the RS technology will be also different. This manuscript describes the most recommendable methodologies for the fabrication, characterization, and simulation of RS devices, as well as the proper methods to display the data obtained. The idea is to help the scientific community to evaluate the real usefulness and impact of an RS study for the development of RS technology. © 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim read more read less
View PDF
441 Citations
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Advanced Electronic Materials format uses apa citation style.

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Frequently asked questions

1. Can I write Advanced Electronic Materials in LaTeX?

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

2. Do you follow the Advanced Electronic Materials guidelines?

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

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 Electronic Materials citation style.

4. Can I use the Advanced Electronic Materials templates for free?

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 Electronic Materials.

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

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

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 Electronic Materials.

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

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 Electronic Materials's guidelines and download the same in Word, PDF and LaTeX formats? Give us a try!.

8. Can I reformat my paper to fit the Advanced Electronic Materials's guidelines?

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.

9. Advanced Electronic Materials an online tool or is there a desktop version?

SciSpace's Advanced Electronic Materials 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.

10. I cannot find my template in your gallery. Can you create it for me like Advanced Electronic Materials?

Sure. You can request any template and we'll have it setup within a few days. You can find the request box in Journal Gallery on the right side bar under the heading, "Couldn't find the format you were looking for like Advanced Electronic Materials?”

11. What is the output that I would get after using Advanced Electronic Materials?

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

12. Is Advanced Electronic Materials'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 Electronic Materials?

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 Electronic Materials. 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 Electronic Materials?

The 5 most common citation types in order of usage for Advanced Electronic Materials 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 Electronic Materials?

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

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