Class information for: |
Basic class information |
| Class id | #P | Avg. number of references |
Database coverage of references |
|---|---|---|---|
| 4410 | 1790 | 21.4 | 76% |
Hierarchy of classes |
The table includes all classes above and classes immediately below the current class. |
| Cluster id | Level | Cluster label | #P |
|---|---|---|---|
| 10 | 4 | OPTICS//PHYSICS, PARTICLES & FIELDS//PHYSICS, MULTIDISCIPLINARY | 1131262 |
| 245 | 3 | PHOTONIC CRYSTAL//OPTICS//INTEGRATED OPTICS | 46930 |
| 297 | 2 | PHOTONIC CRYSTAL//PHOTONIC BAND GAP//PHOTONIC CRYSTAL WAVEGUIDE | 18652 |
| 4410 | 1 | PHOTONIC CRYSTAL//PHOTONIC BAND GAP//AUTOCLONING | 1790 |
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 | PHOTONIC CRYSTAL | authKW | 487233 | 20% | 8% | 355 |
| 2 | PHOTONIC BAND GAP | authKW | 292983 | 7% | 14% | 125 |
| 3 | AUTOCLONING | authKW | 208946 | 1% | 88% | 14 |
| 4 | PHOTONIC BAND | authKW | 123218 | 1% | 43% | 17 |
| 5 | PLANE WAVE EXPANSION METHOD | authKW | 121524 | 2% | 25% | 29 |
| 6 | ABSOLUTE BAND GAP | authKW | 102343 | 0% | 100% | 6 |
| 7 | ANISOTROPIC TELLURIUM | authKW | 102343 | 0% | 100% | 6 |
| 8 | METALLIC PHOTONIC CRYSTAL | authKW | 98388 | 1% | 38% | 15 |
| 9 | PHOTONIC BAND STRUCTURE | authKW | 94906 | 1% | 35% | 16 |
| 10 | R ID PROTOTYPING ENGN | address | 85286 | 0% | 100% | 5 |
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 | Optics | 10434 | 32% | 0% | 577 |
| 2 | Physics, Condensed Matter | 3138 | 23% | 0% | 417 |
| 3 | Physics, Applied | 2613 | 26% | 0% | 472 |
| 4 | Physics, Multidisciplinary | 1048 | 13% | 0% | 225 |
| 5 | Engineering, Electrical & Electronic | 855 | 15% | 0% | 269 |
| 6 | Physics, Mathematical | 330 | 4% | 0% | 80 |
| 7 | Nanoscience & Nanotechnology | 185 | 4% | 0% | 79 |
| 8 | Physics, Fluids & Plasmas | 151 | 3% | 0% | 50 |
| 9 | Materials Science, Ceramics | 115 | 2% | 0% | 35 |
| 10 | Telecommunications | 95 | 3% | 0% | 46 |
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 | R ID PROTOTYPING ENGN | 85286 | 0% | 100% | 5 |
| 2 | PHOTON LATTICE INC | 68228 | 0% | 100% | 4 |
| 3 | SMART PROC | 60639 | 0% | 44% | 8 |
| 4 | SCI MATH PHYS BUNKYO KU | 51171 | 0% | 100% | 3 |
| 5 | GRP ELE OMAGNETISME PL | 35530 | 0% | 42% | 5 |
| 6 | DISPOSITIVI ELETTRON | 34114 | 0% | 100% | 2 |
| 7 | ELECT DEVICE SYST RELIABIL | 34114 | 0% | 100% | 2 |
| 8 | MILLIMETRE WAVE TECHNOL GRP | 30453 | 0% | 36% | 5 |
| 9 | ELE OMAGNET THEORY | 29002 | 1% | 7% | 25 |
| 10 | OPT ELE OMAGNET | 23542 | 2% | 4% | 38 |
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 | JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B-OPTICAL PHYSICS | 7350 | 4% | 1% | 69 |
| 2 | PHYSICAL REVIEW B | 4648 | 12% | 0% | 218 |
| 3 | PHOTONICS AND NANOSTRUCTURES-FUNDAMENTALS AND APPLICATIONS | 4074 | 1% | 2% | 11 |
| 4 | ACTA PHYSICA SINICA | 3658 | 4% | 0% | 66 |
| 5 | OPTICS COMMUNICATIONS | 2118 | 3% | 0% | 58 |
| 6 | OPTICS EXPRESS | 2094 | 4% | 0% | 66 |
| 7 | JOURNAL OF OPTICS A-PURE AND APPLIED OPTICS | 1760 | 1% | 1% | 15 |
| 8 | OPTICAL AND QUANTUM ELECTRONICS | 1683 | 1% | 1% | 20 |
| 9 | APPLIED PHYSICS LETTERS | 1654 | 6% | 0% | 108 |
| 10 | JOURNAL OF MODERN OPTICS | 1647 | 1% | 0% | 25 |
Author Key Words |
| Rank | Term | Chi square | Shr. of publ. in class containing term |
Class's shr. of term's tot. occurrences |
#P with term in class |
LCSH search | Wikipedia search |
|---|---|---|---|---|---|---|---|
| 1 | PHOTONIC CRYSTAL | 487233 | 20% | 8% | 355 | Search PHOTONIC+CRYSTAL | Search PHOTONIC+CRYSTAL |
| 2 | PHOTONIC BAND GAP | 292983 | 7% | 14% | 125 | Search PHOTONIC+BAND+GAP | Search PHOTONIC+BAND+GAP |
| 3 | AUTOCLONING | 208946 | 1% | 88% | 14 | Search AUTOCLONING | Search AUTOCLONING |
| 4 | PHOTONIC BAND | 123218 | 1% | 43% | 17 | Search PHOTONIC+BAND | Search PHOTONIC+BAND |
| 5 | PLANE WAVE EXPANSION METHOD | 121524 | 2% | 25% | 29 | Search PLANE+WAVE+EXPANSION+METHOD | Search PLANE+WAVE+EXPANSION+METHOD |
| 6 | ABSOLUTE BAND GAP | 102343 | 0% | 100% | 6 | Search ABSOLUTE+BAND+GAP | Search ABSOLUTE+BAND+GAP |
| 7 | ANISOTROPIC TELLURIUM | 102343 | 0% | 100% | 6 | Search ANISOTROPIC+TELLURIUM | Search ANISOTROPIC+TELLURIUM |
| 8 | METALLIC PHOTONIC CRYSTAL | 98388 | 1% | 38% | 15 | Search METALLIC+PHOTONIC+CRYSTAL | Search METALLIC+PHOTONIC+CRYSTAL |
| 9 | PHOTONIC BAND STRUCTURE | 94906 | 1% | 35% | 16 | Search PHOTONIC+BAND+STRUCTURE | Search PHOTONIC+BAND+STRUCTURE |
| 10 | DIAMOND STRUCTURED | 68228 | 0% | 100% | 4 | Search DIAMOND+STRUCTURED | Search DIAMOND+STRUCTURED |
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 | SEDGHI, AA , KALAFI, M , VALA, AS , REZAEI, B , (2010) THE INFLUENCE OF SHAPE AND ORIENTATION OF SCATTERERS ON THE PHOTONIC BAND GAP IN 2D METALLIC PHOTONIC CRYSTALS.OPTICS COMMUNICATIONS. VOL. 283. ISSUE 11. P. 2356 -2362 | 29 | 91% | 11 |
| 2 | CASSAGNE, D , (1998) PHOTONIC BAND GAP MATERIALS.ANNALES DE PHYSIQUE. VOL. 23. ISSUE 4. P. 1 -+ | 42 | 82% | 9 |
| 3 | DEGIRMENCI, E , LANDAIS, P , (2013) FINITE ELEMENT METHOD ANALYSIS OF BAND GAP AND TRANSMISSION OF TWO-DIMENSIONAL METALLIC PHOTONIC CRYSTALS AT TERAHERTZ FREQUENCIES.APPLIED OPTICS. VOL. 52. ISSUE 30. P. 7367 -7375 | 32 | 67% | 4 |
| 4 | ZHAO, YG , GRISCHKOWSKY, DR , (2007) 2-D TERAHERTZ METALLIC PHOTONIC CRYSTALS IN PARALLEL-PLATE WAVEGUIDES.IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES. VOL. 55. ISSUE 4. P. 656 -663 | 35 | 64% | 35 |
| 5 | SEDGHI, A , REZAEI, B , (2016) EFFECT OF BACKGROUND DIELECTRIC ON TE-POLARIZED PHOTONIC BANDGAP OF METALLODIELECTRIC PHOTONIC CRYSTALS USING DIRICHLET-TO-NEUMANN MAP METHOD.APPLIED OPTICS. VOL. 55. ISSUE 33. P. 9417 -9421 | 26 | 74% | 0 |
| 6 | SUZUKI, T , YU, PKL , (1999) EXISTENCE OF PHOTONIC BAND GAPS IN TWO-DIMENSIONAL METALLODIELECTRIC PHOTONIC CRYSTALS.ELECTROMAGNETICS. VOL. 19. ISSUE 3. P. 321 -335 | 32 | 94% | 2 |
| 7 | KUZMIAK, V , MARADUDIN, AA , MCGURN, AR , (1997) PHOTONIC BAND STRUCTURES OF TWO-DIMENSIONAL SYSTEMS FABRICATED FROM RODS OF A CUBIC POLAR CRYSTAL.PHYSICAL REVIEW B. VOL. 55. ISSUE 7. P. 4298 -4311 | 31 | 91% | 61 |
| 8 | ZAREI, S , SHAHABADI, M , MOHAJERZADEH, S , (2008) SYMMETRY REDUCTION FOR MAXIMIZATION OF HIGHER-ORDER STOP-BANDS IN TWO-DIMENSIONAL PHOTONIC CRYSTALS.JOURNAL OF MODERN OPTICS. VOL. 55. ISSUE 18. P. 2971 -2980 | 23 | 92% | 3 |
| 9 | MORENO, E , ERNI, D , HAFNER, C , (2002) BAND STRUCTURE COMPUTATIONS OF METALLIC PHOTONIC CRYSTALS WITH THE MULTIPLE MULTIPOLE METHOD.PHYSICAL REVIEW B. VOL. 65. ISSUE 15. P. - | 30 | 70% | 95 |
| 10 | BERGER, V , (1999) FROM PHOTONIC BAND GAPS TO REFRACTIVE INDEX ENGINEERING.OPTICAL MATERIALS. VOL. 11. ISSUE 2-3. P. 131 -142 | 43 | 57% | 26 |
Classes with closest relation at Level 1 |