Class information for: |
Basic class information |
Class id | #P | Avg. number of references |
Database coverage of references |
---|---|---|---|
18649 | 542 | 33.6 | 89% |
Hierarchy of classes |
The table includes all classes above and classes immediately below the current class. |
Cluster id | Level | Cluster label | #P |
---|---|---|---|
2 | 4 | MATERIALS SCIENCE, MULTIDISCIPLINARY//PHYSICS, APPLIED//PHYSICS, CONDENSED MATTER | 2836879 |
666 | 3 | NANOPORE//ANODIC ALUMINUM OXIDE//POROUS ALUMINA | 10027 |
2114 | 2 | ANODIC ALUMINUM OXIDE//POROUS ANODIC ALUMINA//POROUS ALUMINA | 5114 |
18649 | 1 | SILICA NANOTUBES//NANO TEST TUBE//OID INTER E SCI MOL SCI | 542 |
Terms with highest relevance score |
rank | Term | termType | Chi square | Shr. of publ. in class containing term |
Class's shr. of term's tot. occurrences |
#P with term in class |
---|---|---|---|---|---|---|
1 | SILICA NANOTUBES | authKW | 396788 | 3% | 39% | 18 |
2 | NANO TEST TUBE | authKW | 169011 | 1% | 100% | 3 |
3 | OID INTER E SCI MOL SCI | address | 128767 | 1% | 57% | 4 |
4 | DIFFERENTIAL FUNCTIONALIZATION | authKW | 112674 | 0% | 100% | 2 |
5 | ADV FIBER MAT MODERN TEXT | address | 84503 | 1% | 50% | 3 |
6 | BIONANO INTER E | address | 77444 | 2% | 13% | 11 |
7 | BIOMED MICRO NANOTECHNOL | address | 75115 | 0% | 67% | 2 |
8 | HOLLOW SILICA NANOTUBES | authKW | 75115 | 0% | 67% | 2 |
9 | NANOTUBULAR STRUCT OXIDES | address | 75115 | 0% | 67% | 2 |
10 | NEWCASTLE INNOVAT LTD | address | 75115 | 0% | 67% | 2 |
Web of Science journal categories |
Rank | Term | Chi square | Shr. of publ. in class containing term |
Class's shr. of term's tot. occurrences |
#P with term in class |
---|---|---|---|---|---|
1 | Nanoscience & Nanotechnology | 2899 | 25% | 0% | 136 |
2 | Materials Science, Multidisciplinary | 2468 | 47% | 0% | 257 |
3 | Chemistry, Multidisciplinary | 1689 | 37% | 0% | 200 |
4 | Chemistry, Physical | 888 | 29% | 0% | 155 |
5 | Polymer Science | 754 | 15% | 0% | 81 |
6 | Physics, Applied | 567 | 23% | 0% | 124 |
7 | Physics, Condensed Matter | 302 | 14% | 0% | 77 |
8 | Materials Science, Biomaterials | 126 | 3% | 0% | 15 |
9 | Materials Science, Ceramics | 68 | 3% | 0% | 14 |
10 | Chemistry, Applied | 4 | 2% | 0% | 9 |
Address terms |
Rank | Term | Chi square | Shr. of publ. in class containing term |
Class's shr. of term's tot. occurrences |
#P with term in class |
---|---|---|---|---|---|
1 | OID INTER E SCI MOL SCI | 128767 | 1% | 57% | 4 |
2 | ADV FIBER MAT MODERN TEXT | 84503 | 1% | 50% | 3 |
3 | BIONANO INTER E | 77444 | 2% | 13% | 11 |
4 | BIOMED MICRO NANOTECHNOL | 75115 | 0% | 67% | 2 |
5 | NANOTUBULAR STRUCT OXIDES | 75115 | 0% | 67% | 2 |
6 | NEWCASTLE INNOVAT LTD | 75115 | 0% | 67% | 2 |
7 | SUSTAINABLE CHEM SCI TECHNOL | 75115 | 0% | 67% | 2 |
8 | INT JOINT | 68686 | 2% | 12% | 10 |
9 | BIOMED HUMAN OURCES CHONNAM UNIV | 56337 | 0% | 100% | 1 |
10 | CACHAN ANTENNE BRETAGNE | 56337 | 0% | 100% | 1 |
Journals |
Rank | Term | Chi square | Shr. of publ. in class containing term |
Class's shr. of term's tot. occurrences |
#P with term in class |
---|---|---|---|---|---|
1 | MACROMOLECULAR RAPID COMMUNICATIONS | 2170 | 3% | 0% | 14 |
2 | JOURNAL OF MATERIALS CHEMISTRY | 2096 | 5% | 0% | 25 |
3 | LANGMUIR | 1325 | 6% | 0% | 31 |
4 | NANOMEDICINE | 1147 | 1% | 0% | 5 |
5 | JOURNAL OF NANOSCIENCE AND NANOTECHNOLOGY | 1019 | 3% | 0% | 17 |
6 | ADVANCED MATERIALS | 907 | 3% | 0% | 15 |
7 | CHEMISTRY OF MATERIALS | 900 | 3% | 0% | 17 |
8 | NANOTECHNOLOGY | 803 | 2% | 0% | 13 |
9 | NANO LETTERS | 761 | 2% | 0% | 13 |
10 | ACS MACRO LETTERS | 646 | 1% | 0% | 4 |
Author Key Words |
Core articles |
The table includes core articles in the class. The following variables is taken into account for the relevance score of an article in a cluster c: (1) Number of references referring to publications in the class. (2) Share of total number of active references referring to publications in the class. (3) Age of the article. New articles get higher score than old articles. (4) Citation rate, normalized to year. |
Rank | Reference | # ref. in cl. |
Shr. of ref. in cl. |
Citations |
---|---|---|---|---|
1 | SAGHAZADEH, S , ZHANG, SW , LEFEVRE, D , LE BEULZE, A , JONAS, AM , DEMOUSTIER-CHAMPAGNE, S , (2015) UNIVERSAL METHOD TO TRANSFER MEMBRANE-TEMPLATED NANO-OBJECTS TO AQUEOUS SOLUTIONS.LANGMUIR. VOL. 31. ISSUE 26. P. 7264 -7273 | 30 | 57% | 0 |
2 | CHEN, JT , WEI, TH , CHANG, CW , KO, HW , CHU, CW , CHI, MH , TSAI, CC , (2014) FABRICATION OF POLYMER NANOPEAPODS IN THE NANOPORES OF ANODIC ALUMINUM OXIDE TEMPLATES USING A DOUBLE-SOLUTION WETTING METHOD.MACROMOLECULES. VOL. 47. ISSUE 15. P. 5227 -5235 | 28 | 55% | 13 |
3 | YANG, XF , TANG, H , CAO, KS , SONG, HJ , SHENG, WC , WU, QO , (2011) TEMPLATED-ASSISTED ONE-DIMENSIONAL SILICA NANOTUBES: SYNTHESIS AND APPLICATIONS.JOURNAL OF MATERIALS CHEMISTRY. VOL. 21. ISSUE 17. P. 6122 -6135 | 42 | 35% | 65 |
4 | GARCIA-CALZON, JA , DIAZ-GARCIA, ME , (2012) SYNTHESIS AND ANALYTICAL POTENTIAL OF SILICA NANOTUBES.TRAC-TRENDS IN ANALYTICAL CHEMISTRY. VOL. 35. ISSUE . P. 27-38 | 35 | 45% | 12 |
5 | YANG, C , LI, XR , YANG, SJ , SONG, GJ , (2016) STUDY ON THE GROWTH MECHANISM OF THE POLYMER NANOTUBE ARRAYS BY ITS CONTROLLED GROWTH IN ANODIC ALUMINUM OXIDE TEMPLATE.JOURNAL OF NANOSCIENCE AND NANOTECHNOLOGY. VOL. 16. ISSUE 7. P. 7758 -7763 | 15 | 94% | 0 |
6 | KOMATSU, T , (2012) PROTEIN-BASED NANOTUBES FOR BIOMEDICAL APPLICATIONS.NANOSCALE. VOL. 4. ISSUE 6. P. 1910 -1918 | 26 | 48% | 31 |
7 | KOMATSU, T , TERADA, H , KOBAYASHI, N , (2011) PROTEIN NANOTUBES WITH AN ENZYME INTERIOR SURFACE.CHEMISTRY-A EUROPEAN JOURNAL. VOL. 17. ISSUE 6. P. 1849-1854 | 20 | 67% | 19 |
8 | YUGE, S , AKIYAMA, M , ISHII, M , NAMKOONG, H , YAGI, K , NAKAI, Y , ADACHI, R , KOMATSU, T , (2017) GLYCOPROTEIN NANOTUBE TRAPS INFLUENZA VIRUS.CHEMISTRY LETTERS. VOL. 46. ISSUE 1. P. 95 -97 | 19 | 63% | 0 |
9 | YANG, C , LI, XR , YANG, SJ , ZHAO, QP , ZHANG, W , SONG, GJ , (2016) STUDY ON NANO CAPILLARY IN THE POLYMER NANOTUBE ARRAYS GROWTH BY ANODIC ALUMINUM OXIDE(AAO) TEMPLATE WETTING.INTEGRATED FERROELECTRICS. VOL. 171. ISSUE 1. P. 160 -168 | 13 | 87% | 0 |
10 | ZHANG, SW , DEMOUSTIER-CHAMPAGNE, S , JONAS, AM , (2015) QUANTITATIVE COLLECTION AND ENZYMATIC ACTIVITY OF GLUCOSE OXIDASE NANOTUBES FABRICATED BY TEMPLATED LAYER-BY-LAYER ASSEMBLY.BIOMACROMOLECULES. VOL. 16. ISSUE 8. P. 2382 -2393 | 24 | 43% | 0 |
Classes with closest relation at Level 1 |