Diameter-selective Raman scattering from vibrational modes in carbon nanotubes

被引：1965

作者：

Rao, AM

Richter, E

Bandow, S

Chase, B

Eklund, PC

Williams, KA

Fang, S

Subbaswamy, KR

Menon, M

Thess, A

Smalley, RE

Dresselhaus, G

Dresselhaus, MS

机构：

[1] UNIV KENTUCKY,DEPT PHYS & ASTRON,LEXINGTON,KY 40506

[2] UNIV KENTUCKY,CTR APPL ENERGY RES,LEXINGTON,KY 40506

[3] INST MOL SCI,INSTRUMENT CTR,OKAZAKI,AICHI 444,JAPAN

[4] DUPONT CO INC,EXPT STN,WILMINGTON,DE 19880

[5] UNIV KENTUCKY,CTR COMPUTAT SCI,LEXINGTON,KY 40506

[6] RICE UNIV,DEPT CHEM,HOUSTON,TX 77005

[7] MIT,FRANCIS BITTER NATL MAGNET LAB,CAMBRIDGE,MA 02139

[8] MIT,DEPT PHYS,CAMBRIDGE,MA 02139

[9] MIT,DEPT ELECT ENGN & COMP SCI,CAMBRIDGE,MA 02139

来源：

SCIENCE | 1997年 / 275卷 / 5297期

关键词：

D O I：

10.1126/science.275.5297.187

中图分类号：

O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];

学科分类号：

07 ; 0710 ; 09 ;

摘要：

Single wall carbon nanotubes (SWNTs) that are found as close-packed arrays in crystalline ropes have been studied by using Raman scattering techniques with laser excitation wavelengths in the range from 514.5 to 1320 nanometers. Numerous Raman peaks were observed and identified with vibrational modes of armchair symmetry (n, n) SWNTs. The Raman spectra are in good agreement with lattice dynamics calculations based on C-C force constants used to fit the two-dimensional, experimental phonon dispersion of a single graphene sheet. Calculated intensities from a nonresonant, bond polarizability model optimized for sp(2) carbon are also in qualitative agreement with the Raman data, although a resonant Raman scattering process is also taking place. This resonance results from the one-dimensional quantum confinement of the electrons in the nanotube.

引用

页码：187 / 191

页数：5

共 19 条

[1] COBALT-CATALYZED GROWTH OF CARBON NANOTUBES WITH SINGLE-ATOMIC-LAYERWALLS
BETHUNE, DS
KIANG, CH
DEVRIES, MS
GORMAN, G
SAVOY, R
VAZQUEZ, J
BEYERS, R
[J]. NATURE, 1993, 363 (6430) : 605 - 607
[2] STRUCTURE AND VIBRATIONAL PROPERTIES OF CARBON TUBULES
CHANDRABHAS, N
SOOD, AK
SUNDARARAMAN, D
RAJU, S
RAGHUNATHAN, VS
RAO, GVN
SASTRY, VS
RADHAKRISHNAN, TSR
HARIHARAN, Y
BHARATHI, A
SUNDAR, CS
[J]. PRAMANA-JOURNAL OF PHYSICS, 1994, 42 (05): : 375 - 385
[3] COWLEY JM, PREPRINT
[4] Dresselhaus M. S., 1996, SCI FULLERENES CARBO
[5] VIBRATIONAL-MODES OF CARBON NANOTUBES - SPECTROSCOPY AND THEORY
EKLUND, PC
HOLDEN, JM
JISHI, RA
[J]. CARBON, 1995, 33 (07) : 959 - 972
[6] Hayes W., 1978, LIGHT SCATTERING CRY
[7] RAMAN STUDIES OF CARBON NANOTUBES
HIURA, H
EBBESEN, TW
TANIGAKI, K
TAKAHASHI, H
[J]. CHEMICAL PHYSICS LETTERS, 1993, 202 (06) : 509 - 512
[8] RAMAN-SCATTERING FROM NANOSCALE CARBONS GENERATED IN A COBALT-CATALYZED CARBON PLASMA
HOLDEN, JM
PING, Z
BI, XX
EKLUND, PC
BANDOW, SJ
JISHI, RA
DASCHOWDHURY, K
DRESSELHAUS, G
DRESSELHAUS, MS
[J]. CHEMICAL PHYSICS LETTERS, 1994, 220 (3-5) : 186 - 191
[9] SINGLE-SHELL CARBON NANOTUBES OF 1-NM DIAMETER
IIJIMA, S
ICHIHASHI, T
[J]. NATURE, 1993, 363 (6430) : 603 - 605
[10] PHONON MODES IN CARBON NANOTUBULES
JISHI, RA
VENKATARAMAN, L
DRESSELHAUS, MS
DRESSELHAUS, G
[J]. CHEMICAL PHYSICS LETTERS, 1993, 209 (1-2) : 77 - 82

← 1 2 →