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Q. T. Du 1 and J. S. Tan 1 and Q. T. Wang 2 and C. Y. Li 1 and X. H. Liu 1 and R. S. Cai 1 and Y. H. Ding 1 and Y. Q. Wang 1
Recommended by Miguel de la Guardia
1, Cultivation Base for State Key Laboratory, Qingdao University, No. 308 Ningxia Road, Qingdao 266071, China
2, College of Physics Science, Qingdao University, No. 308 Ningxia Road, Qingdao 266071, China
Received 17 November 2011; Revised 2 February 2012; Accepted 14 February 2012
This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
1. Introduction
It is well known that the shape and size of the inorganic nanoparticles have a great influence on their physical properties [1]. In recent years, the synthesis of nanoparticles with well-controlled morphology and size has received lots of interest for their potential applications in nanoscale plasmon photonics, drug delivery, calorimetric sensing [2], nanoelectronics, catalysis, and information storage [3-5]. Two general strategies are usually employed for the "bottom-up" chemical synthesis of nanomaterials: one is the use of the templates, which could confine the shape and size of nanoparticles [6]; the other is the use of the capping agents, which could control the direction and dimension of nanoparticles during the growth process [7, 8].
Cuprous oxide (Cu2 O), which has excellent optical and magnetic properties, is a relatively nontoxic p-type semiconductor with a direct bandgap of 2.17 eV [9]. Tailoring the architecture of Cu2 O crystals has received extensive attention. Over the past few decades, a variety of well-controlled Cu2 O micro-/nanostructures such as cubes [10-15], octahedra [16-19], dodecahedra [17], nanowires [20], and hollow spheres [21] have been synthesized by various methods. Comparing with other methods, electrochemical deposition is a convenient way of preparing many well-defined structures with high uniformity. It has been reported that Cu2 O could be deposited onto different substrates such as Pt, Cu, Au, indium-doped tin oxide (ITO), and stainless steel using electrochemical method [22], most of which concentrated on the fabrication of Cu2 O films or nanowires. Three main methods have been reported to prepare Cu2 O octahedra (a) solution-phase route with surfactants; (b) reduction method with glucose, hydrazine hydrate, and ascorbic acid; (c) γ -irradiation with Triton X-100 water-in-oil microemulsions. Few reports can be found to synthesize Cu2 O octahedra by electrochemical deposition onto the Al foils with the existence of capping agents, and the formation mechanism of Cu2 O octahedra is not clear yet.
Here, we report the electrochemical deposition of single-crystalline Cu2 O octahedra onto aluminum (Al) foils using alkaline cupric sulfate solutions stabilized by lactate ions. Morphology and microstructure of Cu2 O octahedra were investigated in detail. The formation mechanism of the octahedra is proposed.
2. Experimental Details
A DJS-292 potentiostat with a standard three-electrode system was used for Cu2 O octahedra deposition. An Ag/AgCl electrode in a saturated KCl solution was used as a reference electrode and a platinum coil as a counterelectrode. After rinsing several times with acetone and deionized water, Al foil was used as a working electrode.
The electrolyte solution consisted of 0.4 M cupric sulfate and 3 M lactic acid (LA). By complexing with the lactate ions, the copper ions were stabilized. The pH of the solution was adjusted to 9 by 4 M NaOH solution, and a dark blue solution was obtained under constant stirring. The electrochemical deposition was performed potentiostatically with a potential of -0.3 V (versus Ag/AgCl) for 30 min and the temperature of the electrolyte was kept at 60°C by water bath. In order to analyze the effect of other anions, CuSO4 was replaced with CuCl2 with the other parameters unchanged. The specimen for transmission electron microscopy observation was prepared by evaporating a drop of the dispersion onto a carbon-film-coated copper grid.
Morphology examinations were performed using XL30 S-FEG scanning electron microscope (SEM). Selected-area electron diffraction (SAED), bright-field (BF) imaging, and energy dispersive X-ray spectroscopy (EDS) analyses were carried out using a JEOL JEM 2100F transmission electron microscope (TEM) operating at 200 kV. Electron energy-loss spectroscopy (EELS) was carried out on a CM200 FEG transmission electron microscope operating at 200 kV.
3. Results and Discussion
The morphology of the as-deposited products was characterized using SEM. We recorded more than 150 nanoparticles and carried out a statistical analysis of the nanoparticles which showed that the average edge length of the octahedra is 300 ± 10 nm. It can be seen clearly from the low-magnification SEM image (Figure 1(a)) that the shape of the particles is a regular octahedron. The octahedra have slightly different orientations due to the anisotropy of the rough surface of Al foil. The enlarged SEM images of the octahedra viewed from different directions are shown in Figures 1(b) and 1(c), which depict clearly that the particles are perfect octahedra with eight {111} planes. The edge lengths are 300 and 295 nm, respectively. When increasing the deposition time to 1 h, no evident change of the octahedra size was observed. The octahedron looks like a pyramid (Figure 1(b)) viewed from the top and a rhombus (Figure 1(c)) from the side. Careful examination of the SEM images shows that there are lots of pores or network on the Al substrate surface after the deposition, which could result from the erosion of the base. In order to clarify the role of lactic acid in the formation of Cu2 O octahedra, we also carried out the electrochemical deposition without addition of lactic acid in the electrolyte. When no lactic acid was added in the electrolyte, the flocculent precipitates were produced rapidly after the addition of NaOH solution into the CuSO4 electrolyte and the morphology of the as-deposited products changed drastically, which is shown in Figure 1(d). Two morphologies, one being aggregates composed of irregular particles, and the other being dendrites, can be found in Figure 1(d). This suggested that the lactic acid has a great influence on the formation of Cu2 O octahedra. When CuCl2 was used as a copper salt in this experiment, the shape of most particles will become irregular. To determine the chemical composition of the octahedra, energy dispersive X-ray spectroscopy (EDS) was performed. The typical EDS spectrum from the particles in Figure 1(a) indicates that the particles are composed of Cu and O. The quantification of the spectrum shows that the ratio of Cu and O is close to 2 : 1, which suggests that the particles have a chemical formula of Cu2 O.
(a) Low-magnification SEM image of as-deposited specimen; (b) and (c) enlarged SEM images of as-deposited specimen; (d) SEM image of as-deposited specimen without lactic acid in the electrolyte.
(a) [figure omitted; refer to PDF]
(b) [figure omitted; refer to PDF]
(c) [figure omitted; refer to PDF]
(d) [figure omitted; refer to PDF]
The morphology and microstructure of the Cu2 O octahedra were further characterized using TEM. Typical TEM images are shown in Figure 2. Most of the nanooctahedra look like a square (Figure 2(a)) and a rhombus (Figure 2(b)) in the projected images, which correspond to Figures 1(b) and 1(c). For the octahedra with eight {111} planes, the line connecting any two corners that are not in the same face is along the Y9;100YA; direction. In Figure 2(a), we assume that the direction perpendicular to the paper outwardly is along [001] direction, then the two adjacent edges of the square that are perpendicular to each other are along [1-10] and [110] directions, respectively. In Figure 2(b), the rhombus is obtained viewed from the side of the octahedron. It can be seen clearly that two diagonal lengths of the rhombus are not equal, of which the longer diagonal is upward. HRTEM imaging was carried out to determine the growth direction of octahedra. Figure 2(c) shows a typical HRTEM image of the region enclosed by a square in Figure 2(b). The interplanar spacing is measured to be 2.21 Å, which corresponds to the (002) crystal plane of Cu2 O. The SAED pattern (Figure 2(d)) taken from an individual octahedron in Figure 2(b) suggests that it is single crystalline. Careful examinations of Figures 2(b)-2(d) show that the growth direction of Cu2 O octahedra is along Y9;001YA; , which is indicated by a white arrow. This agrees well with the work of Golden et al. in which the preferred orientation of the Cu2 O films is along Y9;100YA; direction when deposited at pH = 9 [23]. The diffraction spots in Figure 2(d) can be indexed as (11-1) , (111) , and (002) , respectively, using the lattice parameter of Cu2 O ( a=4.2696 Å), which is in good agreement with the EDS analysis result. In a typical EELS spectrum acquired from a single octahedron, two peaks at 530 and 932 eV correspond to O-K and Cu- L2,3 edges, respectively. No impurity phase could be found in the products.
TEM images of individual Cu2 O octahedron viewed from the top (a) and the side (b); (c) typical HRTEM image of the region enclosed by a square in (b); (d) corresponding SAED pattern.
(a) [figure omitted; refer to PDF]
(b) [figure omitted; refer to PDF]
(c) [figure omitted; refer to PDF]
(d) [figure omitted; refer to PDF]
Further study shows that the shapes of particles are all octahedra in the presence of lactic acid, and SEM images are shown in Figure 3. Figure 3(a) shows that the average size of the octahedra is 63.5 nm when the ratio of lactic acid and CusO4 is 0.75/0.4. As the ratio decreases to 1.5/0.4, the size rises to 105 nm; but when the ratio increases up to 4.5/0.4 and 6/0.4, the size decreases to 167.5 and 132.5 nm (Figures 3(b) and 3(c)), respectively. This suggests that the size of the octahedra increased initially and then decreased with the increase of the concentration of the lactic acid.
SEM images of the as-deposited specimen with different mole ratios of lactic acid/CuSO4 : (a) R=0.75/0.4 ; (b) R=4.5/0.4 ; (c) R=6/0.4 while other parameters are kept constant.
(a) [figure omitted; refer to PDF]
(b) [figure omitted; refer to PDF]
(c) [figure omitted; refer to PDF]
In order to clarify the effect of pH, a bath with different pH was used to fabricate the Cu2 O nanoparticles. Figure 4 shows the SEM images of the octahedra deposited at different pH. It suggests that the octahedra can form in alkaline solution if the other reaction parameters are kept constant. At pH = 8, the average size of the octahedra in Figure 4(a) is about 382 nm, which is larger than others. When pH rises to 9, the size is approximately 300 nm (Figure 4(b)), relatively smaller than that deposited at pH = 8. However, when the pH values are up to 11 and 12, the size of the octahedra has an obvious decrease compared with those obtained at lower pH, which were about 92 and 87 nm, respectively. From the typical EDS spectrum, it is found that the particles have a chemical formula of Cu2 O.
SEM images of the as-deposited specimen at different bath pH: (a) pH = 8; (b) pH = 9; (c) pH = 11; (d) pH = 12 at -0.3 V for 30 min.
(a) [figure omitted; refer to PDF]
(b) [figure omitted; refer to PDF]
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(d) [figure omitted; refer to PDF]
In the crystal structure of Cu2 O shown in Figure 5(a), the oxygen atoms are arranged in a body-centered-cubic manner, with each oxygen atom being surrounded by a tetrahedron of copper ions, each of which has two oxygen neighbors. The {100} and {111} surfaces in cubic Cu2 O are different in the surface atom structures and bonding as well as the possibility of chemical reactions. It is believed that during the crystal growth process, the crystal faces with higher growth rate will be eliminated first and the morphology is defined by the crystal faces with the slowest growth speed. The shape of the crystals was determined by the ratio ( R ) of the growth rate along the Y9;100YA; direction to that along the Y9;111YA; direction [24]. The preferential crystal growth along the Y9;111YA; direction leads to the formation of the nanocubes [14], while the high growth rate of {100} planes leads to the formation of the octahedra [25]. This is illustrated in Figures 5(b) and 5(c).
(a) Crystal structure of cubic-phase Cu2 O; (b) and (c) schematic illustration of the crystal faces of Cu2 O cube and octahedron.
(a) [figure omitted; refer to PDF]
(b) [figure omitted; refer to PDF]
(c) [figure omitted; refer to PDF]
Lee et al. [26] deposited spherical Cu2 O clusters onto Al substrate in acidic solutions, and Cu2 O thin films were also synthesized on Al foils. Leopold et al. [27] discussed the reaction scheme of Cu2 O nanocrystals deposited on coppers for the self-oscillations and explained the sudden decrease in the potential and increase in the local pH with precipitation model.
Based on the previous work and experimental results, we proposed a growth mechanism for the Cu2 O octahedra. The electrode reactions can be described as follows [27]: [figure omitted; refer to PDF]
The formation process of Cu2 O octahedra is shown in Figure 6. At the initial stage, under the effect of the electric field and Coulomb force, the double layer can form on the electrodes (Figure 6(a)). In alkaline solution, the Cu(II) has two forms in the presence of lactic acid, one being CuL2 2- and the other being [CuL2 (OH)]3- . The Cu(II) complexes in the diffusion layer were reduced into Cu2 O (reactions (2) and (3)) and the L2- ions were liberated. Then, the Cu2 O adsorbed on the surface of the cathode and nuclei formed in an extremely short time (Figure 6(b)). The lactate ions, as a face selective adsorption additive [28], could be adsorbed on the {111} planes and confines the crystal growth along Y9;111YA; directions. Compared with {111} planes, the {100} planes grew faster. At the same time, the lactate ions could be protonated and OH- ions were released (reaction (4)), which could balance the local pH close to the cathode to a certain extent. In this process, SO4 2- [17] and OH- ions might play important roles as the face selective adsorption additives to control the final shape of the Cu2 O crystals. Therefore, the {100} planes were eliminated and finally Cu2 O octahedra were formed. Then the ripening mechanism was dominant in the subsequent steps, which led to the size increase of Cu2 O octahedra. With the increase of the time, the diffusion layer became thicker and the concentration of lactate ions in the diffusion layer increased. The size of the octahedra was gradually stabilized because no enough Cu(II) complexes in the diffusion layer could be reduced and no extra Cu2 O compounds were formed on the surface of the octahedra, which is demonstrated in Figure 6(c). As the depletion of OH- ions, the pH value of the electrolyte tended to be neutral (pH = 7.5 after the deposition for 30 min) and the reaction will be terminated.
(a) Schematic diagram of the adsorption process on the electrodes; (b) and (c) formation process of Cu2 O nuclei and octahedra.
(a) [figure omitted; refer to PDF]
(b) [figure omitted; refer to PDF]
(c) [figure omitted; refer to PDF]
4. Conclusions
Single-crystalline Cu2 O octahedra have been deposited onto the Al foils by a simple electrochemical deposition method. The Cu2 O octahedra have an average edge length of 300 ± 10 nm. The growth direction of Cu2 O octahedra is determined to be along the [001] direction. The size of the octahedra firstly increases and then decreases with the increase of mole ratio of lactic acid/CuSO4 , while the size of the octahedra decreases with pH. The Cu2 O octahedra can be obtained through the synergic effect of face selective additive adsorption upon the particle growth and ripening mechanism with the change of the pH.
Acknowledgments
The authors would like to thank the financial support from National Key Basic Research Development Program of China (973 special preliminary study plan) (Grant no. 2012CB722705), the Natural Science Foundation for Outstanding Young Scientists in Shandong Province (Grant no. JQ201002), the Scientific Research Award for Outstanding Young and Middle-Aged Scientists in Shandong Province (Grant no. BS2009CL0005), and the Scientific Research Starting Foundation for Introduced Talents at Qingdao University (Grant no. 06300701). One author (Y. Q. Wang) would also like to thank the financial support from Taishan Scholar Program (Outstanding Overseas Scholar) of Shandong Province.
[1] F. Williams, A. J. Nozik, "Solid-state perspectives of the photoelectrochemistry of semiconductor-electrolyte junctions," Nature , vol. 312, no. 5989, pp. 21-27, 1984.
[2] Y. Sun, Y. Xia, "Shape-controlled synthesis of gold and silver nanoparticles," Science , vol. 298, no. 5601, pp. 2176-2179, 2002.
[3] X. Duan, Y. Huang, C. M. Lieber, "Nonvolatile memory and programmable logic from molecule-gated nanowires," Nano Letters , vol. 2, no. 5, pp. 487-490, 2002.
[4] S. Sun, C. B. Murray, D. Weller, L. Folks, A. Moser, "Monodisperse FePt nanoparticles and ferromagnetic FePt nanocrystal superlattices," Science , vol. 287, no. 5460, pp. 1989-1992, 2000.
[5] R. Jin, Y. Cao, C. A. Mirkin, K. L. Kelly, G. C. Schatz, J. G. Zheng, "Photoinduced conversion of silver nanospheres to nanoprisms," Science , vol. 294, no. 5548, pp. 1901-1903, 2001.
[6] C. A. Foss, G. L. Hornyak, J. A. Stockert, C. R. Martin, "Template-synthesized nanoscopic gold particles: optical spectra and the effects of particle size and shape," Journal of Physical Chemistry , vol. 98, no. 11, pp. 2963-2971, 1994.
[7] A. Filankembo, M. P. Pileni, "Is the template of self-colloidal assemblies the only factor which controls nanocrystal shapes?," Journal of Physical Chemistry B , vol. 104, no. 25, pp. 5865-5868, 2000.
[8] N. R. Jana, L. Gearheart, C. J. Murphy, "Wet chemical synthesis of high aspect ratio cylindrical gold nanorods," Journal of Physical Chemistry B , vol. 105, no. 19, pp. 4065-4067, 2001.
[9] C. H. B. Ng, W. Y. Fan, "Shape evolution of Cu2 O nanostructures via kinetic and thermodynamic controlled growth," Journal of Physical Chemistry B , vol. 110, no. 42, pp. 20801-20807, 2006.
[10] Y. Q. Wang, W. S. Liang, A. Satti, K. Nikitin, "Fabrication and microstructure of Cu2 O nanocubes," Journal of Crystal Growth , vol. 312, no. 9, pp. 1605-1609, 2010.
[11] L. Gou, C. J. Murphy, "Solution-phase synthesis of Cu2 O nanocubes," Nano Letters , vol. 3, no. 2, pp. 231-234, 2003.
[12] Z. Wang, X. Chen, J. Liu, M. Mo, L. Yang, Y. Qian, "Room temperature synthesis of Cu2 O nanocubes and nanoboxes," Solid State Communications , vol. 130, no. 9, pp. 585-589, 2004.
[13] C. H. Kuo, C. H. Chen, M. H. Huang, "Seed-mediated synthesis of monodispersed Cu2 O nanocubes with five different size ranges from 40 to 420 nm," Advanced Functional Materials , vol. 17, no. 18, pp. 3773-3780, 2007.
[14] D. Wang, M. Mo, D. Yu, L. Xu, F. Li, Y. Qian, "Large-scale growth and shape evolution of Cu2 O cubes," Crystal Growth and Design , vol. 3, no. 5, pp. 717-720, 2003.
[15] Z. Wang, H. Wang, L. Wang, L. Pan, "Controlled synthesis of Cu2 O cubic and octahedral nano-and microcrystals," Crystal Research and Technology , vol. 44, no. 6, pp. 624-628, 2009.
[16] X. Zhang, Y. Xie, F. Xu, X. Liu, D. Xu, "Shape-controlled synthesis of submicro-sized cuprous oxide octahedra," Inorganic Chemistry Communications , vol. 6, no. 11, pp. 1390-1392, 2003.
[17] X. Liang, L. Gao, S. Yang, J. Sun, "Facile synthesis and shape evolution of single-crystal cuprous oxide," Advanced Materials , vol. 21, no. 20, pp. 2068-2071, 2009.
[18] P. He, X. Shen, H. Gao, "Size-controlled preparation of Cu2 O octahedron nanocrystals and studies on their optical absorption," Journal of Colloid and Interface Science , vol. 284, no. 2, pp. 510-515, 2005.
[19] S. Jing, S. Xing, Y. Wu, Y. Wang, B. Zhao, C. Zhao, "Synthesis of octahedral Cu2 O microcrystals assisted with mixed cationic/anionic surfactants," Materials Letters , vol. 61, no. 11-12, pp. 2281-2283, 2007.
[20] W. Z. Wang, G. H. Wang, X. S. Wang, Y. J. Zhan, Y. K. Liu, C. L. Zheng, "Synthesis and characterization of Cu2 O nanowires by a novel reduction route," Advanced Materials , vol. 14, no. 1, pp. 67-69, 2002.
[21] Y. Chang, J. J. Teo, H. C. Zeng, "Formation of colloidal CuO nanocrystallites and their spherical aggregation and reductive transformation to hollow Cu2 O nanospheres," Langmuir , vol. 21, no. 3, pp. 1074-1079, 2005.
[22] P. E. de Jongh, D. Vanmaekelbergh, J. J. Kelly, "Cu2 O: electrodeposition and characterization," Chemistry of Materials , vol. 11, no. 12, pp. 3512-3517, 1999.
[23] T. D. Golden, M. G. Shumsky, Y. Zhou, R. A. VanderWerf, R. A. van Leeuwen, J. A. Switzer, "Electrochemical deposition of copper(I) oxide films," Chemistry of Materials , vol. 8, no. 10, pp. 2499-2504, 1996.
[24] Z. L. Wang, "Transmission electron microscopy of shape-controlled nanocrystals and their assemblies," Journal of Physical Chemistry B , vol. 104, no. 6, pp. 1153-1175, 2000.
[25] H. Xu, W. Wang, W. Zhu, "Shape evolution and size-controllable synthesis of Cu2 O octahedra and their morphology-dependent photocatalytic properties," Journal of Physical Chemistry B , vol. 110, no. 28, pp. 13829-13834, 2006.
[26] J. Lee, T. G. Noh, Y. Tak, "Electrochemical deposition of spherical shaped Cu2 O cluster on aluminum electrode," Journal of Industrial and Engineering Chemistry , vol. 8, no. 5, pp. 454-457, 2002.
[27] S. Leopold, M. Herranen, J. O. Carlsson, L. Nyholm, "In situ pH measurement of the self-oscillating Cu(II)-lactate system using an electropolymerised polyaniline film as a micro pH sensor," Journal of Electroanalytical Chemistry , vol. 547, no. 1, pp. 45-52, 2003.
[28] T. J. Whang, M. T. Hsieh, J. M. Tsai, S. J. Lee, "Lactic acid aided electrochemical deposition of c -axis preferred orientation of zinc oxide thin films: structural and morphological features," Applied Surface Science , vol. 257, no. 22, pp. 9539-9545, 2011.
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Copyright © 2012 Q. T. Du et al. Q. T. Du et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Abstract
A simple electrochemical deposition was developed to synthesize the cuprous oxide (Cu2O) octahedra on aluminum foils. The average edge length of the octahedra is about 300 nm. The chemical composition of the octahedra was determined using energy dispersive X-ray spectroscopy and electron energy-loss spectroscopy. The microstructure of the octahedra was investigated using transmission electron microscopy. The formation mechanism of the octahedra is proposed.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
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