Journal of Vacuum Science & Technology (JVST) serial journals are the official publications of American Vacuum Society. We search the nanotechnology-related references on JVST and obtain visual maps through a visual analysis tool, CiteSpace. The visual maps can help us understand the distribution of research institutions and cooperation, high-impact authors, core literatures, research hotspots and fronts of nanotechnology in the field of vacuum.
CiteSpace is used to detect and analyze the emerging trends in the research fronts of subjects, and the relationship of their research fronts, intellectual bases and other research fronts. It can be more intuitive to recognize the evolving paths of subject fronts and classic basal literatures in subject areas by employing the visualized literature information. It is mainly equipped with the following visual features: co-cited articles analysis, co-occurring terms analysis, institution cooperation analysis, author co-citation analysis, authors cooperation analysis and so on. In addition, one of important features of CiteSpace is detection of burst term which relies on the level of frequency and trend of the words, owning high frequency change rates detected from a lot of phrases by examining the time distribution of frequency, to determine the fronts of the evolution of a field. We analyze the nanotechnology-related references on JVST by using CiteSpace to obtain visual maps. The visual maps can help us understand the distribution of research institutions and cooperation, high-impact authors, core literatures, research hotspots and fronts of nanotechnology in the field of vacuum.
This article uses the Science Citation Index Expanded database of online SCI(Thomson. ISI), Web of Science, as a data source. We search 4040 records in total by choosing advanced search as the search method and query is (so = Journal of Vacuum Science & Technology*) and (ts = nano* or ts = graphene). Data Download mode is set to “Record and contain the whole cited references,” and the data download time ends in September 26, 2013.
Citation analysis visualization is an important branch of information visualization, which deals with a flood of citation data at first, and then makes it easier to observe, explore and understand the information to find the hidden data patterns and models by using information visualization technology. Citation analysis visualization tools as used herein are based on CiteSpace 3.7.R5 of JAVA platform. The CiteSpace 3.7.R5 is developed by By Chen Chaomei, a doctor in the College of Information Science and Technology, Drexel University in Philadelphia, USA. He is the international authority in the field of information visualization and devoted to study the information visualization research methods and related algorithms for many years.
CiteSpace is used to detect and analyze the emerging trends in the research fronts of subjects, and the relationship of their research fronts, intellectual bases and other research fronts. It can be more intuitive to recognize the evolving paths of subject fronts and classic basal literatures in subject areas by employing the visualized literature information. It mainly is equipped with the following visual features: co-cited articles analysis, co-occurring terms analysis, institution cooperation analysis, author co-citation analysis, authors cooperation analysis and so on. In addition, one of important features of CiteSpace is detection of burst term which relies on the level of frequency and trend of the words, owning high frequency change rates detected from a lot of phrases by examining the time distribution of frequency, to determine the fronts of the evolution of a field [
Citespace shows immediately the amounts and issued time of articles in every country (region) by the size and color of “Ring” [
As shown in
Use a zero before decimal points: “0.25”, not “.25”. Use “cm3”, not “cc”. As can be seen from
White, the doctor of Drake University in USA, believes that the higher frequency of author’s co-citation, the higher relevance in the academic of authors [
Organization | MIT | IBM CORP | OSAKA UNIV | UNIV ILLINOIS | USN | UNIV WISCONSIN | CHINESE ACAD SCI |
---|---|---|---|---|---|---|---|
No. Articles | 96 | 83 | 68 | 66 | 64 | 63 | 62 |
choose 1985 to 2013 as the time interval, 3 years as the time span, the title, abstract, author keywords and keywords plus in the article as subject terms, authors and cited authors as node type in the network configuration. Criterion selects “Top N per slice” and top 50 mostly cited or occurred items from each slice, and other options remain unchanged. As a result, the analysis map of author co-citation can be obtained by operate this software. The map contains 332 nodes and 887 connections. Namely, these 4040 articles have 332 authors in total whose citations are higher than the threshold value. The co-citation relationships are shown in
Rank | No. Articles | Centrality | The year of the first paper | Author |
---|---|---|---|---|
1 | 277 | 0.35 | 1986 | CHOU SY |
2 | 112 | 0 | 2001 | BONARD JM |
3 | 110 | 0.08 | 1991 | IIJIMA S |
4 | 101 | 0.03 | 1995 | DEHEER WA |
5 | 90 | 0.03 | 1998 | SAITO Y |
6 | 83 | 0.02 | 1986 | BINNIG G |
7 | 82 | 0.03 | 1992 | OLIVER WC |
8 | 79 | 0.03 | 1984 | MATSUI S |
9 | 78 | 0.07 | 1976 | SPINDT CA |
10 | 76 | 0.01 | 1999 | VEPREK S |
Firstly, we discern that the most influent author is CHOU SY in this field due to his articles higher than the threshold value are 277, and centrality is 0.35. Therefore, he should be regarded as the most authoritative expert in this field, and his researches have profound influences. The spatial distribution in
The settings of CiteSpace choose 1985 to 2013 as the time interval, 3 years as the time span, the title, abstract, author keywords and keywords plus in the article as subject terms, cited reference as node type in the network configuration. Criterion selects “Top N per slice”, top 50 most cited or occurred items from each slice, and the key pathfinder algorithm. Other options remain unchanged. In the scientific knowledge map of the co-cited articles creating by CiteSpace, 365 citations and 630 connections between them are selected. As shown in
It can be found that 4 of 8 core node references come from Chou SY by analyzing
Furthermore, we make a map of the annual change distribution of all references for them and co-cited relationships. That is a map depending on the time zone in
First author | Year | Title | Cited times | Co-citations |
---|---|---|---|---|
Chou, SY | 1995 | IMPRINT OF SUB-25 NM VIAS AND TRENCHES IN POLYMERS | 1488 | 131 |
IIJIMA S | 1991 | HELICAL MICROTUBULES OF GRAPHITIC CARBON | 21226 | 95 |
Chou, SY | 1996 | Imprint lithography with 25-nanometer resolution | 1436 | 80 |
DEHEER WA | 1995 | A CARBON NANOTUBE FIELD-EMISSION ELECTRON SOURCE | 2318 | 78 |
OLIVER WC | 1992 | AN IMPROVED TECHNIQUE FOR DETERMINING HARDNESS AND ELASTIC-MODULUS USING LOAD AND DISPLACEMENT SENSING INDENTATION EXPERIMENTS | 8371 | 78 |
FOWLER RH | 1928 | Electron emission in intense electric fields | 2956 | 73 |
Chou, SY | 1997 | Sub-10 nm imprint lithography and applications | 673 | 61 |
Chou, SY | 1996 | Nanoimprint lithography | 818 | 57 |
Co-occurring terms analysis mirrors the hotspots in this field. The node type of the network configuration selects keywords pathfinder algorithm, and other options remain unchanged. We can obtain the hotspots from clustering analysis of the map of co-occurring terms. There are 174 nodes and 255 connections in
As can be seen in
It can get 19 clusters by selecting “Find optimal clusters” and then can get 15 clusters by selecting “Label clusters with title terms” in the keywords map in
The concept of research fronts is proposed firstly by Price, who thinks research fronts can descript the dynamic nature of research fields. Garfield defines research fronts as the set of the core highly cited papers and citing papers, and believes that the name of research fronts can be extracted from the words or phrases which have the highest frequency of occurrence in the these paper titles. Dr. Chen Chaomei defined research fronts as a set of emergent dynamic concepts and potential research questions, and the intellectual base of research fronts was quotations and Co-citation Tracks. Citespace determines the net knowledge map of research fronts by the mutant terms abstracted from the titles, abstracts, index terms and record identifiers of references. Specific methods are selecting Cited Reference as the net node, “Top N per slice” and top 15 most cited or occurred items from each slice as threshold willing, and key pathfinder algorithm. After operating it, we receive 19 clusters by choosing “Find optimal clusters” and the cluster name by selecting “Label clusters with title terms”. The generated knowledge map is shown in
There are 143 nodes, 186 links and 19 clusters. Every cluster has a different area. The larger area cluster contains, the more bibliography entry it has, and this cluster is the more main research directions. In
Co-citations | Centrality | Year | Keywords |
---|---|---|---|
388 | 0.11 | 1991 | fabrication |
356 | 0.21 | 1991 | growth |
354 | 0.07 | 1991 | films |
293 | 0.12 | 1991 | silicon |
253 | 0.19 | 1991 | thin-films |
241 | 0.12 | 1990 | lithography |
206 | 0.15 | 1991 | nanolithography |
169 | 0 | 1997 | chemical-vapor-deposition |
166 | 0 | 2000 | arrays |
163 | 0.22 | 1991 | deposition |
Node | Clusters |
---|---|
#0 | plasma |
#1 | scanning probe microscope instrument |
#2 | coated optical fiber tip |
#3 | fabrication technology |
#4 | graphene |
#5 | molecular property |
#6 | nanobubble |
#7 | emission performance |
#8 | optical property |
#9 | carbon nanotube |
#10 | influence |
#11 | membrane |
#12 | generation |
#13 | electron-beam nanolithography |
#14 | nanolaminate gate dielectric |
It demonstrates the evolutive gradient path of subject knowledge portal by clicking on the button, “Link Walkthrough”, and the color changes of circular node clusters in the map, we get
We summarize the nanotechnology references in JVST, and find the institutions ranking top 10 are MIT, IBM CORP, OSAKA UNIV, UNIV ILLINOIS, USN, UNIV WISCONSIN, and CHINESE ACAD SCI. The most influencing author is CHOU SY due to he has a half of 8 core node articles. The research hotspots are fabrication technology, graphene, molecular property, emission performance, electron-beam nanolithography, nanolaminate gate dielectric et al. The research frontals are scanning tunneling microscopy, bidirectional atomic force microscope, carbon nanotube, ion-beam lithography and so on.
Wang Yi,Mao Di, (2016) The Research Fronts and Hotspots on Nanotechnology Based on Journal of Vacuum Science & Technology. Open Journal of Social Sciences,04,57-65. doi: 10.4236/jss.2016.43010