Loading [MathJax]/extensions/MathMenu.js

The Application of Metal Deposition in Optical Sensor Technique. The Microscale Cu Deposition as “Electrochemical Welding” | IEEE Journals & Magazine | IEEE Xplore

- Donate
- Personal Sign In

ADVANCED SEARCH

Journals & Magazines >IEEE Sensors Journal >Volume: 15 Issue: 2

The Application of Metal Deposition in Optical Sensor Technique. The Microscale Cu Deposition as “Electrochemical Welding”

Download PDF
Download References
Request Permissions
Save to
Alerts

Abstract:

The problem of how to attach an optical glass fiber to a copper plate was solved with the use of microscale electrolyser of special design. The respective laboratory scal...Show More

Metadata

Abstract:

The problem of how to attach an optical glass fiber to a copper plate was solved with the use of microscale electrolyser of special design. The respective laboratory scale technology was presented. The results were documented by photos of ready elements. The matter of relation between deposition by means of constant current electrolysis without potential control and the process realized with the use of cyclic voltammetry and chronopotentiometry techniques was raised and discussed.

Published in: IEEE Sensors Journal ( Volume: 15, Issue: 2, February 2015)

Page(s): 1275 - 1279

Date of Publication: 07 August 2014

ISSN Information:

DOI: 10.1109/JSEN.2014.2345731

Funding Agency:

References is not available for this document.

I. Introduction

The development of optical fiber sensors for a wide range of industrial applications is still a matter of interest ([1]–[14] and literature therein). The flat diaphragm with two glass optical fibers attached is an important part of the optical fiber sensor construction. Pressure signal on the flat diaphragm allows to detect pressure differences within a wide range of pressure (60Pa – 75KPa) and frequency (0.5 Hz – 5KHz) [9]. Fig. 1 presents a part of interferometer fiber optic sensor configuration [1]. The complete sensor construction is presented in relevant literature [10]. Fig. 1.

Interferometer fiber optic sensor configuration: metal flat diaphragm (plate) with two glass fibers attached on both sides: awers (left) and rewers (right).

Select All

1.

M. D. Giovanni, Flat and Corrugated Diaphragm Design Handbook, New York, NY, USA:Marcel Dekker, pp. 130-155, 1982.

2.

T. Yoshino, K. Kurosawa, K. Itoh and T. Ose, "Fiber-optic Fabry–Pérot interferometer and its sensor applications", IEEE J. Quantum Electron., vol. 18, no. 10, pp. 1624-1633, Oct. 1982.

3.

Optical Fiber Sensor Technology, London, U.K.:Chapman Hall, 1995.

CrossRef Google Scholar

4.

Optical Fiber Sensor Technology: Volume 2. Devices and Technology, Berlin, Germany:Springer-Verlag, 1998.

CrossRef Google Scholar

5.

B. Lee, "Review of the present status of optical fiber sensors", Opt. Fiber Technol., vol. 9, no. 2, pp. 57-79, 2003.

CrossRef Google Scholar

6.

A. Saran, D. C. Abeysinghe, P. Deshmukh, R. Flenniken and J. T. Boyd, "Anodic bonding of optical fibers to silicon for integrating MEMS based optical pressure and temperature sensors onto optical fibers", Proc. 12th Int. Conf. Solid-State Sensors Actuat. Microsyst. (TRANSDUCERS), vol. 1, pp. 564-567, Jun. 2003.

7.

"Lightguides and their applications III", Proc. SPIE TAL Technol. Appl. Lightguides, vol. 6608, Oct. 4–7, 2007.

8.

H. Krisch, M. Lau and S. Tournillon, "Optical fibre sensor for measurement the large range of strain and frequency vibrations of flat diaphragm", Proc. SPIE 4th Eur. Workshop Opt. Fiber Sens., vol. 7653, pp. 765316, Sep. 2010.

CrossRef Google Scholar

9.

N. Fernandes, K. Gossner and H. Krisch, "Low power signal processing for demodulation of wide dynamic range of interferometric optical fibre sensor signals", Proc. SPIE 4th Eur. Workshop Opt. Fiber Sens., vol. 7653, pp. 765328, Sep. 2010.

CrossRef Google Scholar

10.

H. Krisch et al., "Analysis of optical fiber interferometer sensor bonded to flat diaphragm for dynamic stress measurement at high temperature", Proc. SPIE 21st Int. Conf. Opt. Fiber Sensors (OFS-21), vol. 7753, pp. 77531O-1-77531O-4, May 2011.

CrossRef Google Scholar

11.

V. G. M. Annamdas, "Review on developments in fiber optical sensors and applications", Int. J. Mater. Eng., vol. 1, no. 1, pp. 1-16, 2011.

CrossRef Google Scholar

12.

H. Guo, G. Xiao, N. Mrad and J. Yao, "Fiber optic sensors for structural health monitoring of air platforms", Sensors, vol. 11, no. 4, pp. 3687-3705, 2011.

CrossRef Google Scholar

13.

K. Bremer, E. Lewis, G. Leen, B. Mossa, S. Lochmann and I. Mueller, "Fabrication of a miniature all-glass fibre optic pressure and temperature sensor", Procedia Eng., vol. 25, pp. 503-506, Jan. 2011.

CrossRef Google Scholar

14.

H. Krisch, N. Hernandes, K. Gossner, M. Lau and S. Tournillon, "High-temperature fiber-optic sensor for low-power measurement of wide dynamic strain using interferometric techniques and analog/DSP methods", IEEE Sensors J., vol. 12, no. 1, pp. 33-38, Jan. 2012.

15.

"Vortex flowmeter pressure sensor for a vortex flowmeter and method for producing such a pressure sensor", Jan. 2013, [online] Available: http://www.faqs.org/patents/app/20130014591#ixzz2rbDiWGXE.

16.

S. J. Figueroa-Ramirez and M. Miranda-Hernandez, "Copper electrodeposition on carbon film electrodes", ECS Trans., vol. 15, no. 1, pp. 181-189, 2008.

CrossRef Google Scholar

17.

P. T. Sanecki, P. M. Skital and K. Kaczmarski, "The mathematical models of the stripping voltammetry metal deposition/dissolution process", Electrochim. Acta, vol. 55, no. 5, pp. 1598-1604, 2010.

CrossRef Google Scholar

18.

P. M. Skital and P. T. Sanecki, "The experimental verification of mathematical two-plate model describing the metal deposition/dissolution process", Russian J. Electrochem., vol. 48, no. 8, pp. 797-803, Aug. 2012.

CrossRef Google Scholar

19.

A. C. West, C.-C. Cheng and B. C. Baker, "Pulse reverse copper electrodeposition in high aspect ratio trenches and vias", J. Electrochem. Soc., vol. 145, no. 9, pp. 3070-3074, 1998.

CrossRef Google Scholar

20.

C.-C. Hu and C.-M. Wu, "Effects of deposition modes on the microstructure of copper deposits from an acidic sulfate bath", Surf. Coatings Technol., vol. 176, no. 1, pp. 75-83, 2003.

CrossRef Google Scholar

21.

S.-C. Chang, J.-M. Shieh, B.-T. Dai, M.-S. Feng and Y.-H. Li, "The effect of plating current densities on self-annealing behaviors of electroplated copper films", J. Electrochem. Soc., vol. 149, no. 9, pp. G535-G538, 2002.

CrossRef Google Scholar

22.

R. Greef, R. Peat, L. M. Peter, D. Pletcher and J. Robinson, Instrumental Methods in Electrochemistry, Chichester, U.K.:Wiley, pp. 211, 1985.

23.

Technique of Electroorganic Synthesis, New York, NY, USA:Wiley, vol. 5, 1974.

24.

D. J. Pickett, Electrochemical Reactor Design, Amsterdam, The Netherlands:Elsevier, 1977.

25.

P. C. Andricacos, "Copper on-chip interconnections. A breakthrough in electrodeposition to make better chips", Electrochem. Soc. Interf., vol. 8, no. 1, pp. 32-37, 1999.

CrossRef Google Scholar

26.

P. C. Andricacos, C. Uzoh, J. O. Dukovic, J. Horkans and H. Deligianni, "Damascene copper electroplating for chip interconnections", IBM J. Res. Develop., vol. 42, no. 5, pp. 567-574, 1998.

References is not available for this document.