Improvement of Photoluminescence Uniformity of Porous Silicon by using Stirring Anodization Process
The electrolyte stirring method of anodization etching
process for manufacturing porous silicon (PS) is reported in this work.
Two experimental setups of nature air stirring (PS-ASM) and
electrolyte stirring (PS-ESM) are employed to clarify the influence of
stirring mechanisms on electrochemical etching process. Compared to
traditional fabrication without any stirring apparatus (PS-TM), a large
plateau region of PS surface structure is obtained from samples with
both stirring methods by the 3D-profiler measurement. Moreover, the
light emission response is also improved by both proposed electrolyte
stirring methods due to the cycling force in electrolyte could
effectively enhance etch-carrier distribution while the electrochemical
etching process is made. According to the analysis of statistical
calculation of photoluminescence (PL) intensity, lower standard
deviations are obtained from PS-samples with studied stirring methods,
i.e. the uniformity of PL-intensity is effectively improved. The
calculated deviations of PL-intensity are 93.2, 74.5 and 64,
respectively, for PS-TM, PS-ASM and PS-ESM.
[1] L. T. Canham, "Silicon quantum wire array fabrication by
electrochemical and chemical dissolution of wafers," Appl. Phys. Lett.,
vol. 57, pp. 1046-1048, July 1990.
[2] P. McCord, S. L. Yau and A. J. Bard, "Chemiluminescence of anodized
and etched silicon: evidence for a luminescent siloxene-like layer on
porous silicon," Science, vol. 257, pp. 68-69, Jul. 1992.
[3] P. Fauchet, "Photoluminescence and electroluminescence from porous
silicon," J. Lumin., vol. 257, pp. 294-309, Oct. 1996.
[4] A. G. Cullis, L. T. Canham and P. D. J. Calcott, "The structural and
luminescence properties of porous silicon," J. Appl. Phys., vol. 82, pp.
909-965, Apr. 1997.
[5] O. Bisi, S. Ossicine and L. Pavesi, "Porous silicon: a quantum sponge
structure for silicon based optoelectronics," Surf. Sci. Rep., vol. 38, pp.
1-126, Apr. 2000.
[6] F. P. Mathew and E. C. Alocilja, "Porous silicon-based biosensor for
pathogen detection," Biosens. Bioelectron., vol. 20, pp. 1656-1661, Feb.
2005.
[7] M. J. Schoning, A. Kurowski, M.Thust, P. Kordos, J. W. Schultze and H.
Luth, "Capacitive microsensors for biochemical sensing based on porous
silicon technology," Sensor. Actuat. B Chem., vol. 64, pp. 59-64, Jun.
2000.
[8] V. Polishchuk, E. Souteyrand, J. R. Martin, V. I. Strikha and V. A.
Skrysheveky, "A study of hydrogen detection with palladium modified
porous silicon," Anal. Chim. Acta., vol. 375, pp. 205-210, Nov. 1998.
[9] K. Luongo, A. Sine and S. Bhansali, "Development of a highly sensitive
porous Si-based hydrogen sensor using Pd nano-structures," Sensor.
Actuat. B Chem., vol. 111-112, pp. 125-129, Nov. 2005.
[10] C. Tsamis, A. G. Nassiopoulou and A. Tserepi, "Thermal properties of
suspended porous silicon micro-hotplates for sensor applications," Sensor.
Actuat. B Chem., vol. 95, pp. 78-82, Oct. 2003.
[11] P. Y. Y. Kan and T. G. Finstad, "Oxidation of macroporous silicon for
thick thermal insulation," Mat. Sci. Eng. B-Adv., vol. 118, pp. 289-292,
Apr. 2005.
[12] M. Bjorkqvist, J. Salonen, J. Paski, E. Laine, " Characterization of
thermally carbonized porous silicon humidity sensor," Sensor. Actuat. A
Phys., vol. 112, pp. 244-247, May 2004.
[13] H. Contopanagos and A. G. Nassiopoulou, "Design and simulation of
integrated inductors on porous silicon in CMOS-compatible processes,"
Solid State Electron., vol. 50, pp. 1283-1290, Aug. 2006.
[14] C. Li, H. Liao, L. Yang and R. Huang, "High-performance integrated
inductor and effective crosstalk isolation using post-CMOS selective
grown porous silicon (SGPS) technique for RFIC applications," Solid
State Electron., vol. 51, pp. 989-994, Jun. 2007.
[15] L. T. Canham, W. Y. Leong, T. I. Cox and L. Taylor, "Efficient visible
electroluminescence from highly porous silicon under cathodic bias,"
Appl. Phys. Lett., vol. 61, pp. 2563-2565, Sep. 1992.
[16] J. C. Lin, P. W. Lee and W. C. Tsai, "Manufacturing method for n-type
porous silicon based on Hall effect without illumination," Appl. Phys.
Lett., vol. 89, pp. 12119-1-3, Sep. 2006.
[17] A. Richter, P. Steiner, F. Kozlowski and W. Lang, "Current-induced light
emission from a porous silicon device," IEEE Electron Device Lett., vol.
12, pp. 691-692, Dec. 1991.
[18] J. Sarahy, S. Shih, K. Jung, C. Tsai, K. H. Li, D. L. Kwong, J. C.
Campbell, S. L. Yau and A. J. Bard, "Demonstration of
photoluminescence in nonanodized silicon," Appl. Phys. Lett., vol. 60, pp.
1532-1535, Jan. 1992.
[19] A. Ksendzov, R. W. Fathauer, T. George, W. T. Pike, R. P. Vasquez, and
A. P. Taylor, "Visible photoluminescence of porous Si1−xGex obtained
by stain etching," Appl. Phys. Lett., vol. 63, pp. 200-202, Apr. 1993.
[20] N. V. Gaponenko, "Sol-gel derived films in meso-porous matrices:
porous silicon, anodic alumina and artificial opals," Synth. Met., vol. 124,
pp. 125-130, Oct. 2001.
[21] S. Kalem and O. Yavuzcetin, "Possibility of fabricating light-emitting
porous silicon from gas phase etchants," Opt. Exp., vol. 6, pp. 7-11, Jan.
2000.
[22] M. Saadoun, N. Mliki, H. Kaabi, K. Daoudi, B. Bessais, H. Ezzaouia and
R. Bennaceur, "Vapour-etching-based porous silicon: a new approach,"
Thin Solid Films, vol. 405, pp. 29-34, Feb. 2002.
[23] T. Unagami, "Formation Mechanism of Porous Silicon Layer by
Anodization in HF Solution," J. Electrochem. Soc., vol.127, pp. 476-486,
Feb. 1980.
[24] J. C. Lin, W. C. Tsai and W. L. Chen, "Light emission and negative
differential conductance of n-type nanoporous silicon with buried p-layer
assistance," Appl. Phys. Lett., vol. 90, pp. 09117 (1-3), Mar. 2007.
[1] L. T. Canham, "Silicon quantum wire array fabrication by
electrochemical and chemical dissolution of wafers," Appl. Phys. Lett.,
vol. 57, pp. 1046-1048, July 1990.
[2] P. McCord, S. L. Yau and A. J. Bard, "Chemiluminescence of anodized
and etched silicon: evidence for a luminescent siloxene-like layer on
porous silicon," Science, vol. 257, pp. 68-69, Jul. 1992.
[3] P. Fauchet, "Photoluminescence and electroluminescence from porous
silicon," J. Lumin., vol. 257, pp. 294-309, Oct. 1996.
[4] A. G. Cullis, L. T. Canham and P. D. J. Calcott, "The structural and
luminescence properties of porous silicon," J. Appl. Phys., vol. 82, pp.
909-965, Apr. 1997.
[5] O. Bisi, S. Ossicine and L. Pavesi, "Porous silicon: a quantum sponge
structure for silicon based optoelectronics," Surf. Sci. Rep., vol. 38, pp.
1-126, Apr. 2000.
[6] F. P. Mathew and E. C. Alocilja, "Porous silicon-based biosensor for
pathogen detection," Biosens. Bioelectron., vol. 20, pp. 1656-1661, Feb.
2005.
[7] M. J. Schoning, A. Kurowski, M.Thust, P. Kordos, J. W. Schultze and H.
Luth, "Capacitive microsensors for biochemical sensing based on porous
silicon technology," Sensor. Actuat. B Chem., vol. 64, pp. 59-64, Jun.
2000.
[8] V. Polishchuk, E. Souteyrand, J. R. Martin, V. I. Strikha and V. A.
Skrysheveky, "A study of hydrogen detection with palladium modified
porous silicon," Anal. Chim. Acta., vol. 375, pp. 205-210, Nov. 1998.
[9] K. Luongo, A. Sine and S. Bhansali, "Development of a highly sensitive
porous Si-based hydrogen sensor using Pd nano-structures," Sensor.
Actuat. B Chem., vol. 111-112, pp. 125-129, Nov. 2005.
[10] C. Tsamis, A. G. Nassiopoulou and A. Tserepi, "Thermal properties of
suspended porous silicon micro-hotplates for sensor applications," Sensor.
Actuat. B Chem., vol. 95, pp. 78-82, Oct. 2003.
[11] P. Y. Y. Kan and T. G. Finstad, "Oxidation of macroporous silicon for
thick thermal insulation," Mat. Sci. Eng. B-Adv., vol. 118, pp. 289-292,
Apr. 2005.
[12] M. Bjorkqvist, J. Salonen, J. Paski, E. Laine, " Characterization of
thermally carbonized porous silicon humidity sensor," Sensor. Actuat. A
Phys., vol. 112, pp. 244-247, May 2004.
[13] H. Contopanagos and A. G. Nassiopoulou, "Design and simulation of
integrated inductors on porous silicon in CMOS-compatible processes,"
Solid State Electron., vol. 50, pp. 1283-1290, Aug. 2006.
[14] C. Li, H. Liao, L. Yang and R. Huang, "High-performance integrated
inductor and effective crosstalk isolation using post-CMOS selective
grown porous silicon (SGPS) technique for RFIC applications," Solid
State Electron., vol. 51, pp. 989-994, Jun. 2007.
[15] L. T. Canham, W. Y. Leong, T. I. Cox and L. Taylor, "Efficient visible
electroluminescence from highly porous silicon under cathodic bias,"
Appl. Phys. Lett., vol. 61, pp. 2563-2565, Sep. 1992.
[16] J. C. Lin, P. W. Lee and W. C. Tsai, "Manufacturing method for n-type
porous silicon based on Hall effect without illumination," Appl. Phys.
Lett., vol. 89, pp. 12119-1-3, Sep. 2006.
[17] A. Richter, P. Steiner, F. Kozlowski and W. Lang, "Current-induced light
emission from a porous silicon device," IEEE Electron Device Lett., vol.
12, pp. 691-692, Dec. 1991.
[18] J. Sarahy, S. Shih, K. Jung, C. Tsai, K. H. Li, D. L. Kwong, J. C.
Campbell, S. L. Yau and A. J. Bard, "Demonstration of
photoluminescence in nonanodized silicon," Appl. Phys. Lett., vol. 60, pp.
1532-1535, Jan. 1992.
[19] A. Ksendzov, R. W. Fathauer, T. George, W. T. Pike, R. P. Vasquez, and
A. P. Taylor, "Visible photoluminescence of porous Si1−xGex obtained
by stain etching," Appl. Phys. Lett., vol. 63, pp. 200-202, Apr. 1993.
[20] N. V. Gaponenko, "Sol-gel derived films in meso-porous matrices:
porous silicon, anodic alumina and artificial opals," Synth. Met., vol. 124,
pp. 125-130, Oct. 2001.
[21] S. Kalem and O. Yavuzcetin, "Possibility of fabricating light-emitting
porous silicon from gas phase etchants," Opt. Exp., vol. 6, pp. 7-11, Jan.
2000.
[22] M. Saadoun, N. Mliki, H. Kaabi, K. Daoudi, B. Bessais, H. Ezzaouia and
R. Bennaceur, "Vapour-etching-based porous silicon: a new approach,"
Thin Solid Films, vol. 405, pp. 29-34, Feb. 2002.
[23] T. Unagami, "Formation Mechanism of Porous Silicon Layer by
Anodization in HF Solution," J. Electrochem. Soc., vol.127, pp. 476-486,
Feb. 1980.
[24] J. C. Lin, W. C. Tsai and W. L. Chen, "Light emission and negative
differential conductance of n-type nanoporous silicon with buried p-layer
assistance," Appl. Phys. Lett., vol. 90, pp. 09117 (1-3), Mar. 2007.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:59543", author = "Jia-Chuan Lin and Meng-Kai Hsu and Hsi-Ting Hou and Sin-Hong Liu", title = "Improvement of Photoluminescence Uniformity of Porous Silicon by using Stirring Anodization Process", abstract = "The electrolyte stirring method of anodization etching
process for manufacturing porous silicon (PS) is reported in this work.
Two experimental setups of nature air stirring (PS-ASM) and
electrolyte stirring (PS-ESM) are employed to clarify the influence of
stirring mechanisms on electrochemical etching process. Compared to
traditional fabrication without any stirring apparatus (PS-TM), a large
plateau region of PS surface structure is obtained from samples with
both stirring methods by the 3D-profiler measurement. Moreover, the
light emission response is also improved by both proposed electrolyte
stirring methods due to the cycling force in electrolyte could
effectively enhance etch-carrier distribution while the electrochemical
etching process is made. According to the analysis of statistical
calculation of photoluminescence (PL) intensity, lower standard
deviations are obtained from PS-samples with studied stirring methods,
i.e. the uniformity of PL-intensity is effectively improved. The
calculated deviations of PL-intensity are 93.2, 74.5 and 64,
respectively, for PS-TM, PS-ASM and PS-ESM.", keywords = "Porous Silicon, Photoluminescence, Uniformity
Carrier Stirring Method", volume = "6", number = "1", pages = "74-4", }
