18 April 2012 Fabrication of porous silicon-based silicon-on-insulator photonic crystal by electrochemical etching method
Author Affiliations +
We present a fast, novel method for building porous silicon-based silicon-on-insulator photonic crystals in which a periodic modulation of the refractive index is built by alternating different electrochemical etching currents. The morphology and reflectance spectra of the photonic crystals, prepared by the proposed method, are investigated. The scanning electron micrograph and atomic force microscopy images show a very uniform structure and the porous silicon demonstrates an 829 nm wide photonic band gap.



Photonic crystals (PhCs) which can control the propagation of light very efficiently, have beenattracting great interest in a wide range of optoelectronics fields. One of the most important and useful properties of PhCs is the existence of a photonic band gap (PBG).1 This structure is very suitable for designing various functional photonic devices such as sensors and waveguides.2,3 Due to the versatile nature of porous silicon (PSi), high surface-area-to-volume ratio and biocompatibility, PSi PBG structures have already found many applications such as dielectric mirrors, waveguides, sensors and many other devices.

On the other hand, silicon-on-insulator (SOI) has demonstrated great potential in both photoelectric devices and has improved a number of desirable features, such as lower power consumption, higher package density and other parameters.910.11 For these reasons, porous silicon PhCs on SOI wafer can be a very interesting aspect of PSi research which can combine the advantages of porous silicon PhCs and SOI technology. M. Balarin et al. reported that PSi was successfully prepared by electrochemical etching of SOI wafers consisting of 45 μm thick p-type silicon epitaxial layer grown on a thin 100 nm SiO2 layer on silicon substrates.12 However, despite many attempts, our work team could not reproduce their results. We believe the most likely reason is that their buried layer contained impurities. Furthermore, in their most recent work,13 they used another substrate which had no insulator layer. The n-type silicon wafers consisted only of upper and lower layers with different resistivity. This shows that the conventional electrochemical etching method for preparing PSi on SOI wafers has many restrictions. Non-electrochemical etching methods can be easily used to prepare PSi on SOI wafers, but it is difficult to prepare multilayer PSi. Moreover, the electrochemical etching method yields reproducible porosity and thickness at the same key parameters.

In this paper, a novel method for preparing multi-layer PSi is presented. In addition, we have designed an unusual double tank electrochemical etching cell, which is shown in Fig. 1, and have successfully prepared PSi-based PhCs on SOI substrate. The optical and physical properties were studied by cross-sectional scanning electron microscope, SEM, micrographs, atomic force microscopy (AFM) and reflectivity spectra.

Fig. 1

Schematic of experimental setup.



Experimental Details

PSi photonic crystals were prepared using boron doped p-type SOI silicon wafer consisting of 50 μm thick p-type silicon epitaxial layer with a resistivity of 0.02Ω·cm which were grown on a thin 12 μm SiO2 layer on silicon substrates. The resulting PSi was prepared at an applied current density of 10mA/cm2 and 50mA/cm2 under 15 five minute periods, respectively. The electrolyte solution was a 11 mixture of 49 percent hydrofluoric acid (HF) and 95 percent ethanol.

A specially designed double tank electrochemical etching cell, illustrated in Fig. 1, was used for preparation of PSi samples. In this method, the outside of etching area was immersed in conducting liquid. A cushion was used to separate HF electrolyte solution and conducting liquid. Thus, the accumulation of positive charge carriers, which is necessary for the chemical reaction, was provided through the bottom of the top layer.


Results and Discussion

Figure 2 displays cross sections SEM and AFM images of the freshly prepared multilayer PSi. This multilayer structure is simply nothing but a one dimension PSi photonic crystal prepared on SOI wafer which is composed of 15 periods of high and low refractive index, respectively. From the Fig. 2(a), we can found that the PSi layer shows a good uniformity and homogeneity. Figure 2(b) represents the cross-section of the sample. From this image, it is possible to see the parallel multi-layer structures. The measured thickness of the sample is approximately 9 μm. This shows the modified electrochemical etching method can be used to prepare multilayer PSi. A. Splinter et al.reported14 that thick PSi had been successfully prepared by the stain etching method, but the PSi was a single layer. It is important to mention, that using this etching method yields a one-dimensional PSi-based PhCs prepared on SOI wafer.

Fig. 2

Atomic force microscopy and cross-section SEM of 15 periods’ porous silicon layers.


The optical reflectivity spectrum of the sample, presented in Fig. 3, where solid line is the reflectivity spectrum at the centre of PSi layer and dotted line is the reflectivity spectrum of the edge. At the angle of incidence of 5 degrees, the width of the PBG of the two positions, corresponding to reflectivity higher than 80 percent, is approximately 829 nm, ranging from 3792 to 4621 nm at the center and 3832 to 4661 nm at the edge. The value of Rmax has been determined by standard reflectivity. The center wavelength of the PBG centers has a little shift to the red side. According to D.R. Huanca’s research,15 the different PBG centers, shown by the samples, can be explained only by the difference between layer thicknesses and porosity of samples. Accordingly, we can expect that the edge of the PSi has greater layer thickness and porosity. If a transverse current exists in the etching process, the etching rate near the edge will be higher than that of the center and the optical thickness increase. If suitable etching process parameters are selected, the PBG can be tuned almost anywhere within the near infrared range.

Fig. 3

Reflection spectra of 1D porous silicon PhCs at two different positions.


The theoretically estimated PBG of this PhCs is shown in Fig. 4. The refractive indexes of each layer were estimated by the single layer of etched by constant current of 50 and 10 mA, respectively. The width of the stop band, corresponding to reflectivity higher than 80 percent, is around 730 nm, ranging from 3860 to 4590 nm. The measured PBG of the PhCs is broader than that of simulated reflectance spectra. It is known to all, that in the electrochemical etching process, reaction products and bubbles are produced and HF concentration reduces at the bottom of PSi holes which leads to the slower etching rate of PSi and decrease the porosity. Thus, even in the same etching parameters, the refractive index of PSi increases from upper to the bottom. For this reason, the refractive index of the PhCs increased from the upper to the bottom layers which caused the broader PBG.16

Fig. 4

Measured (solid line) and simulated (dashed line) reflectance spectra of PhCs.




It has been demonstrated, that the modified double-tank electrochemical etching method allows formation of PSi on SOI silicon which was very difficult using the conventional electrochemical etching method. Bragg structure PSi, with 829 nm bandwidth, was successfully fabricated on SOI wafer.


This work was supported by the National Natural Science Foundation of China (No. 60968002).


1. Y. OhteraT. Kawashima, “Extremely low optical transmittance in the stopbands of photonic crystals,” Photonic. Nanostruct. 7(2), 85–91 (2009). Google Scholar

2. B. V. LotschG. A. Ozin, “All-clay photonic crystals,” J. Am. Chem. Soc. 130(46), 15252–15253 (2008).JACSAT0002-7863 http://dx.doi.org/10.1021/ja806508h Google Scholar

3. L.-C. Yanget al., “FDTD simulation of time varying optical vortex phenomena in SOI photonic crystal structures,” Optik 122(10), 924–927 (2011).OTIKAJ0030-4026 http://dx.doi.org/10.1016/j.ijleo.2010.06.019 Google Scholar

4. R. J. Martín-Palmaet al., “Nanostructured-porous-silicon-based two-dimensional photonic crystals,” Appl. Phys. Lett. 89(5), 053126 (2006).APPLAB0003-6951 http://dx.doi.org/10.1063/1.2335586 Google Scholar

5. J. O. Estevezet al., “Enlargement of omnidirectional photonic bandgap in porous silicon dielectric mirrors with a Gaussian profile refractive index,” Appl. Phys. Lett. 94(6), 061914 (2009).APPLAB0003-6951 http://dx.doi.org/10.1063/1.3081113 Google Scholar

6. G. Ronget al., “Label-free porous silicon membrane waveguide for DNA sensing,” Appl. Phys. Lett. 93(16), 161109 (2008).APPLAB0003-6951 http://dx.doi.org/10.1063/1.3005620 Google Scholar

7. V. MulloniL. Pavesi, “Porous silicon microcavities as optical chemical sensors,” Appl. Phys. Lett. 76(18), 2523 (2000).APPLAB0003-6951 http://dx.doi.org/10.1063/1.126396 Google Scholar

8. A. Birneret al., “Silicon-based photonic crystals,” Adv. Mater. 13(6), 377–388 (2001).ADVMEW0935-9648 http://dx.doi.org/10.1002/(ISSN)1521-4095 Google Scholar

9. J. Wanget al., “High-Q photonic crystal surface-mode cavities on crystalline SOI structures,” Optic. Comm. 283(11), 2461–2464 (2010).OPCOB80030-4018 http://dx.doi.org/10.1016/j.optcom.2010.02.011 Google Scholar

10. R. ThomasZ. IkonicR. W. Kelsall, “Plasmonic enhanced electro-optic stub modulator on a SOI platform,” Photon. Nanostruc. 9(1), 101–107 (2011).1569-4410 http://dx.doi.org/10.1016/j.photonics.2011.01.001 Google Scholar

11. S. LinJ. HuB. Kenneth, “Ultracompact, broadband slot waveguide polarization splitter,” Appl. Phys. Lett. 98(15), 151101 (2011).APPLAB0003-6951 http://dx.doi.org/10.1063/1.3579243 Google Scholar

12. A. Balarinet al., “Structure and optical properties of porous silicon prepared on thin epitaxial silicon layer on silicon substrates,” J. Mol. Struct. 834, 465–470 (2007).JMOSB40022-2860 http://dx.doi.org/10.1016/j.molstruc.2006.12.010 Google Scholar

13. M. Balarinet al., “Optical properties of porous silicon on an insulator layer,” J. Mol. Struct. 993(1–3), 208–213 (2011).JMOSB40022-2860 http://dx.doi.org/10.1016/j.molstruc.2011.02.006 Google Scholar

14. A. SplinterJ. StürmannW. Benecke, “Novel porous silicon formation technology using internal current generation,” Mater. Sci. Eng. C 15(1–2), 109–112 (2001).MSCEEE0928-4931 http://dx.doi.org/10.1016/S0928-4931(01)00263-6 Google Scholar

15. D. R. HuancaD. S. RaimundoW. J. Salcedo, “Backside contact effect on the morphological and optical features of porous silicon photonic crystals,” Microelectron. J. 40(4–5), 744–748 (2009).MICEB90026-2692 http://dx.doi.org/10.1016/j.mejo.2008.11.005 Google Scholar

16. S. K. SrivastavaS. P. Ojha, “Broadband optical reflector based on Si/SiO2 one-dimensional graded photonic crystal structure,” J. Mod. Optic. 56(1), 33–40 (2009).JMOPEW0950-0340 http://dx.doi.org/10.1080/09500340802428330 Google Scholar


Furu Zhong received his MS degree from University of Electronic and Technology of China in 2005. He is currently working toward his PhD degree at Xinjiang University. His research interests include porous silicon-based optics sensors and optical communication.

Xiaoyi Lv received MS degree in Information and Communication Engineering from Xinjiang University, China in 2006 and PhD degree in Electronic and Information Engineering at Xi’an Jiaotong University, China in 2010. His current work will focus upon porous silicon-based optics sensors and optical communication.

Zhenhong Jia received his MS and PhD degrees in Physic, from Shanghai Jiao Tong University, China in 1990 and 1995, respectively. He is now a professor in College of Information Science and Engineering, Xinjiang University. He has been working in the fields of organic and silicon-based photonic devices.

Jiaqing Mo received his BS and MS degrees in Physics, from Xinjiang University and Beijing University of Technology, China in 1996 and 2004, respectively. He is currently working toward his PhD degree at Xi’anJiaotong University. He is now a teacher in College of Information Science and Engineering, Xinjiang University. He has been working in the fields of porous silicon-based optics sensors and optical communication.

© 2012 Society of Photo-Optical Instrumentation Engineers (SPIE)
Furu Zhong, Furu Zhong, Xiao-yi Lv, Xiao-yi Lv, Zhen-hong Jia, Zhen-hong Jia, Jiaqing Mo, Jiaqing Mo, } "Fabrication of porous silicon-based silicon-on-insulator photonic crystal by electrochemical etching method," Optical Engineering 51(4), 040502 (18 April 2012). https://doi.org/10.1117/1.OE.51.4.040502 . Submission:

Back to Top