LOW-LOSS, SINGLE-MODE, OPTICAL-PHASE MODULATOR IN SIMOX MATERIAL

被引：82

作者：

TANG, CK ^{[2
]}

REED, GT

WALTON, AJ

RICKMAN, AG

机构：

[1] UNIV EDINBURGH, DEPT ELECTR & ELECT ENGN, EDINBURGH, SCOTLAND

[2] UNIV SURREY, DEPT ELECTR & ELECT ENGN, GUILDFORD GU2 5XH, SURREY, ENGLAND

[3] UNIV SURREY, DEPT PHYS, GUILDFORD GU2 5XH, SURREY, ENGLAND

来源：

JOURNAL OF LIGHTWAVE TECHNOLOGY | 1994年 / 12卷 / 08期

关键词：

D O I：

10.1109/50.317527

中图分类号：

TM [电工技术]; TN [电子技术、通信技术];

学科分类号：

0808 ; 0809 ;

摘要：

This paper reports results of the simulation of an optical phase modulator. The proposed modulator consists of an elongated p-i-n structure fabricated in a silicon-on-insulator material such as SIMOX. It utilizes the free-carrier effect to produce the desired refractive index change in a single-mode optical rib waveguide. The MEDICI two-dimensional semiconductor device simulation package has been employed to optimize the overlap between the injected free carriers and the propagating optical guided mode. Although the device is designed to support a single optical guided mode, it measures several micrometers in cross sectional dimensions, thereby simplifying fabrication and allowing efficient coupling to/from other single-mode devices. Furthermore, the device has an extremely high figure of merit, predicting over 200 degrees of induced phase shift per volt per millimeter, as well as a low drive current of less than 10 mA. This is approximately an order of magnitude lower than most other reported devices in silicon.

引用

页码：1394 / 1400

页数：7

共 50 条

[21] Single-mode optical fiber for high-power, low-loss UV transmission
Colombe, Yves
Slichter, Daniel H.
Wilson, Andrew C.
Leibfried, Dietrich
Wineland, David J.
[J]. OPTICS EXPRESS, 2014, 22 (16): : 19783 - 19793
[22] COMPENSATION OF CHROMATIC DISPERSION IN A SINGLE-MODE FIBER BY OPTICAL-PHASE CONJUGATION
WATANABE, S
NAITO, T
CHIKAMA, T
[J]. IEEE PHOTONICS TECHNOLOGY LETTERS, 1993, 5 (01) : 92 - 95
[23] LOW-LOSS SINGLE-MODE FIBEROPTIC WAVE-GUIDE
GURYANOV, AN
GUSOVSKII, DD
DEVYATYKH, GG
DIANOV, EM
MIRAKYAN, MM
NEUSTRUEV, VB
NIKOLAICHIK, AV
PROKHOROV, AM
KHOPIN, VF
[J]. KVANTOVAYA ELEKTRONIKA, 1980, 7 (08): : 1823 - 1825
[24] Low-loss single-mode terahertz waveguiding using Cytop
Reyes, Glenda de los
Quema, Alex
Ponseca, Carlito, Jr.
Pobre, Romeric
Quiroga, Reuben
Ono, Shingo
Murakami, Hidetoshi
Estacio, Elmer
Sarukura, Nobuhiko
Aosaki, Ko
Sakane, Yoshihiko
Sato, Hideki
[J]. APPLIED PHYSICS LETTERS, 2006, 89 (21)
[25] LOW-LOSS SINGLE-MODE FIBER WITH REDUCED INNER CLADDING
UNGER, HG
YANG, R
ZAMZOW, PE
GLESSNER, B
HOFFART, M
[J]. AEU-ARCHIV FUR ELEKTRONIK UND UBERTRAGUNGSTECHNIK-INTERNATIONAL JOURNAL OF ELECTRONICS AND COMMUNICATIONS, 1987, 41 (03): : 185 - 186
[26] LOW-LOSS SINGLE-MODE FIBER AT MATERIAL DISPERSION-FREE WAVELENGTH OF 1.27 MUM
KAWACHI, M
KAWANA, A
MIYASHITA, T
[J]. ELECTRONICS LETTERS, 1977, 13 (15) : 442 - 443
[27] FABRICATION AND PROPERTIES OF SINGLE-MODE OPTICAL FIBER EXHIBITING LOW DISPERSION, LOW-LOSS, AND TIGHT MODE CONFINEMENT SIMULTANEOUSLY
PEARSON, AD
LAZAY, PD
REED, WA
[J]. BELL SYSTEM TECHNICAL JOURNAL, 1982, 61 (02): : 262 - 266
[28] ANALYSIS OF A SINGLE-MODE OPTICAL FIBER PIEZOCERAMIC PHASE MODULATOR
MARTINI, G
[J]. OPTICAL AND QUANTUM ELECTRONICS, 1987, 19 (03) : 179 - 190
[29] Low-loss optical single-mode waveguide platform in thin glass with wide spectral range
Schroeder, H.
Schwietering, J.
Kirsch, O.
Wachholz, P.
Lewoczko-Adamczyk, W.
[J]. OPTICAL INTERCONNECTS XXII, 2022, 12007
[30] SEGMENTED-CORE SINGLE-MODE FIBERS WITH LOW-LOSS AND LOW DISPERSION
BHAGAVATULA, VA
SPOTZ, MS
LOVE, WF
KECK, DB
[J]. ELECTRONICS LETTERS, 1983, 19 (09) : 317 - 318

← 1 2 3 4 5 →