Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically

Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically

We have investigated the current creation accompanied by the water decomposition H₂O → OH + H caused by various catalytically active electrodes with different electrochemical potentials, both without external electric voltage on these electrodes and with the applied voltage V₀ = ±9.7 V. It is fou...

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Datum:2007
Hauptverfasser: Primachenko, V.E., Serba, O.A., Chernobai, V.A., Venger, E.F.
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Sprache:English
Veröffentlicht: Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України 2007
Schriftenreihe:Semiconductor Physics Quantum Electronics & Optoelectronics
Online Zugang:https://nasplib.isofts.kiev.ua/handle/123456789/117891
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spelling nasplib_isofts_kiev_ua-123456789-1178912025-06-03T16:25:26Z Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically Primachenko, V.E. Serba, O.A. Chernobai, V.A. Venger, E.F. We have investigated the current creation accompanied by the water decomposition H₂O → OH + H caused by various catalytically active electrodes with different electrochemical potentials, both without external electric voltage on these electrodes and with the applied voltage V₀ = ±9.7 V. It is found that the current value and its time dependence are essentially influenced by such factors as thermal and natural (in ambient atmosphere) oxidation of electrodes (made of Al, Si, Yb, Ni, Ti, Cr₃Si, and Ni₃Si), changing their relief (texturing, polishing), and the electrolytic deposition of palladium as an impurity on the surface (Ti, Cr₃Si). Changes in the current caused by the above factors are realized as a consequence of changes in both the electron work function inherent to these electrodes and their catalytical activity concerning the water decomposition both in the absence and the presence of the external voltage V₀. 2007 Article Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically / V.Ye. Primachenko, O.A. Serba, V.A. Chernobai, E.F. Venger // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2007. — Т. 10, № 2. — С. 40-45. — Бібліогр.: 7 назв. — англ. 1560-8034 PACS 81.16.Hc, 82.30.Lp, 82.45.Fk https://nasplib.isofts.kiev.ua/handle/123456789/117891 en Semiconductor Physics Quantum Electronics & Optoelectronics application/pdf Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description We have investigated the current creation accompanied by the water decomposition H₂O → OH + H caused by various catalytically active electrodes with different electrochemical potentials, both without external electric voltage on these electrodes and with the applied voltage V₀ = ±9.7 V. It is found that the current value and its time dependence are essentially influenced by such factors as thermal and natural (in ambient atmosphere) oxidation of electrodes (made of Al, Si, Yb, Ni, Ti, Cr₃Si, and Ni₃Si), changing their relief (texturing, polishing), and the electrolytic deposition of palladium as an impurity on the surface (Ti, Cr₃Si). Changes in the current caused by the above factors are realized as a consequence of changes in both the electron work function inherent to these electrodes and their catalytical activity concerning the water decomposition both in the absence and the presence of the external voltage V₀.
format Article
author Primachenko, V.E.
Serba, O.A.
Chernobai, V.A.
Venger, E.F.
spellingShingle Primachenko, V.E.
Serba, O.A.
Chernobai, V.A.
Venger, E.F.
Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically
Semiconductor Physics Quantum Electronics & Optoelectronics
author_facet Primachenko, V.E.
Serba, O.A.
Chernobai, V.A.
Venger, E.F.
author_sort Primachenko, V.E.
title Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically
title_short Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically
title_full Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically
title_fullStr Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically
title_full_unstemmed Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically
title_sort influence of some physico-chemical factors on properties of electrodes that decompose water catalytically
publisher Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
publishDate 2007
url https://nasplib.isofts.kiev.ua/handle/123456789/117891
citation_txt Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically / V.Ye. Primachenko, O.A. Serba, V.A. Chernobai, E.F. Venger // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2007. — Т. 10, № 2. — С. 40-45. — Бібліогр.: 7 назв. — англ.
series Semiconductor Physics Quantum Electronics & Optoelectronics
work_keys_str_mv AT primachenkove influenceofsomephysicochemicalfactorsonpropertiesofelectrodesthatdecomposewatercatalytically
AT serbaoa influenceofsomephysicochemicalfactorsonpropertiesofelectrodesthatdecomposewatercatalytically
AT chernobaiva influenceofsomephysicochemicalfactorsonpropertiesofelectrodesthatdecomposewatercatalytically
AT vengeref influenceofsomephysicochemicalfactorsonpropertiesofelectrodesthatdecomposewatercatalytically
first_indexed 2025-11-27T15:37:53Z
last_indexed 2025-11-27T15:37:53Z
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fulltext Semiconductor Physics, Quantum Electronics & Optoelectronics, 2007. V. 10, N 2. P. 40-45. © 2007, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 40 PACS 81.16.Hc, 82.30.Lp, 82.45.Fk Influence of some physico-chemical factors on properties of electrodes that decompose water catalytically V.E. Primachenko, O.A. Serba, V.A. Chernobai, E.F. Venger V. Lashkaryov Institute of Semiconductor Physics, NAS of Ukraine 41, prosect Nauky, 03028 Kyiv, Ukraine, e-mail: pve18@isp.kiev.ua Abstract. We have investigated the current creation accompanied by the water decomposition H2O → OH + H caused by various catalytically active electrodes with different electrochemical potentials, both without external electric voltage on these electrodes and with the applied voltage V0 = ±9.7 V. It is found that the current value and its time dependence are essentially influenced by such factors as thermal and natural (in ambient atmosphere) oxidation of electrodes (made of Al, Si, Yb, Ni, Ti, Cr3Si, and Ni3Si), changing their relief (texturing, polishing), and the electrolytic deposition of palladium as an impurity on the surface (Ti, Cr3Si). Changes in the current caused by the above factors are realized as a consequence of changes in both the electron work function inherent to these electrodes and their catalytical activity concerning the water decomposition both in the absence and the presence of the external voltage V0. Keywords: catalytically active electrodes, oxidation, water decomposition. Manuscript received 20.10.06; accepted for publication 24.04.07; published online 19.10.07. 1. Introduction One of the actual up-to-date problems is the power production with minimum injury to the ecology of ambient medium and minimum economic expenses. An example of solving this problem is the use of the difference of electrochemical potentials that is set by the nature in different substances or created, or changed in them, including the synthesis of new substances. In our previous works [1-3], we studied the phenomenon of electric current creation accompanied with water decomposition H2O → OH + H when dipping two electrodes with different electrochemical potentials into it, these electrodes (at least one of them) being a catalyst of the decomposition of water molecules. As shown in these works [1-3], the catalytic decomposition of water is mainly realized due to the presence of physico-chemical inhomogeneities on the micro(nano) scale on the electrode surface and to strong electric fields existing there. In particular, we studied the influence of thermal oxidation of catalytically active Si- based electrodes on current magnitudes and time dependences inherent to these electrodes and counterelectrodes made of Al, Yb, Pt [3]. This work is devoted to the influence of electrodes made of Al, Yb, Ni, Ti, and Cr3Si on water decomposition. In addition, a considerable attention was paid to studying such factors as a change of the electrode relief (texturing, grinding, and polishing) and the electrochemical deposition of Pd on Ti, Cr3Si electrodes. 2. Experimental The method of our experiments was described in works [1-3] in detail. When dipping two different electrodes into distilled water simultaneously, there arises the difference of potentials ∆Vk between them, which, as a rule, is less than the difference between the electron work functions for these electrodes ∆φ (this difference ∆φ is equal to the difference between the electro- chemical potentials of electrodes). After making the external electric circuit to be closed (the time t = 0), we measured time dependences for the current, J(t). Since the area of electrodes S and the distance between them L for various electrode pairs are different, we compare the efficient conductivities σ = J(t)(L / ∆Vk S) = AJ(t) of the electrochemical systems, where A = = L /(∆Vk S) V−1cm−1. When the electric circuit was supplied with the additional external voltage V0 = ±9.7 V, we used the value (∆Vk ± V0) instead of the value ∆Vk. Thermal oxidation of electrodes was realized at Т = = 450 °С for 4 h in dry О2, while natural oxidation took place under ambient atmospheric conditions and by applying these electrodes as anodes. The relief of electrodes was changed using emery-paper (for grinding), diamond paste on felt (for polishing), as well as using anisotropic chemical etching (texturing). Before measuring the σ = AJ(t) dependence, we determined the electron work function inherent to the electrodes in use. To this end, we used a standard reference electrode made of Pt (φ = 5.32 eV) [4], as Pt is Semiconductor Physics, Quantum Electronics & Optoelectronics, 2007. V. 10, N 2. P. 40-45. © 2007, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 41 the most chemically stable electrode in our inves- tigations. The values of φ for various electrodes were determined via calculations made after measuring the current between Pt and the investigated electrode in the forward and backward directions [1-3] and are presented in the table. 3. Experimental results and discussion In our investigations, the electrode made of Yb that possesses a relatively low electron work function was mostly used as anode [1-3]. It is known (see, in particular, [1]) that, when Yb is oxidized, the values of AJ(t) are increased to some extent despite the growth of φ. Therefore, we studied first the changes of φ and AJ(t) which accompany the changes of an Yb surface state. Fig. 1 shows the obtained dependences AJ(t) at V0 = 0 for three states of the Yb surface: (i) naturally oxidized (initial) (curve 1); (ii) polished (curve 2); (iii) oxidized for three months when it is operating as anode (curve 3) after polishing. As seen from Fig. 1, the dependences AJ(t) noticeably differ from each other only within the first 20 min after bridging the Yb and Pt electrodes. This is related both to different φ values (and ∆Vk, respectively) and the dependence of the catalytic activity of the Yb electrode on the degree of oxidation. As seen from the table, the values of φ were as follows: 3.65, 3.04, and 3.67 eV, while ∆Vk were equal to 0.86, 1.37, and 0.85 V. AJ, 10–6 Ohm–1 cm–1 0 10 20 30 0 5 10 15 20 t,min , 1 3 2 Fig. 1. Time dependences of the efficient conductivity AJ(t) when water is decomposed using the pair of electrodes Yb-Pt. The Yb electrode is: 1 – naturally oxidized; 2 – as polished; 3 – oxidized after polishing and operation for 3 months. Table. The electron work functions φ for electrodes in various physico-chemical states. Electrode Electrode symbol φ, eV Aluminum as grinded AlGr СВ 4.12 Aluminum grinded and aged AlGr AG 4.3 Aluminum plain and aged AlP AG 4.57 Aluminum AlP AG after thermal oxidation AlP ТО 5.11 Aluminum textured and aged AlТAG 4.58 Aluminum AlТAG after thermal oxidation AlТAG 5.12 Nickel (plane) Ni 4.82 Nickel thermally oxidized NiTO 4.97 Chromium silicide Cr3Si 4.43 Chromium silicide after thermal oxidation Cr3SiТО 5.44 Chromium silicide after Pd doping (1.5·1016 cm−2) Cr3Si 〈Pd1〉 4.53 Chromium silicide after Pd doping (1·1018 cm−2) Cr3Si 〈Pd5〉 6.24 Titanium as grinded TiGr СВ 4.38 Titanium grinded and aged TiGr AG 5.15 Titanium doped with Pd (2·1016cm−2) Ti〈Pd1〉 5.17 Titanium doped with Pd (1·1018cm−2) Ti〈Pd4〉 5.30 Titanium TI〈Pd4〉 thermally oxidized Ti〈Pd4〉ТО 5.42 Silicon textured and aged SiТAG 4.85 Silicon SiТAG after treatment in HF SiТHF 4.76 Ytterbium aged YbAG 3.65 Ytterbium polished YbP 3.04 Ytterbium YbP after 1-month operation as anode (oxidized) YbОX 3.67 Nickel silicide Ni3Si 4.85 Ni3Si after thermal oxidation Ni3SiТО 4.88 Considering the obtained data, it seems reasonable to make the following conclusions: (i) when measuring the AJ(t) dependences 20 min after the circuit closing, the values of AJ(t) are practically the same, i.e., the oxidizing degree of the Yb electrode does not influence its stable functioning; (ii) catalytic activity of the Yb electrode at t < 0 and for the first minutes of the current transfer increases with its oxidation degree. It is not surprising, because not only the transition metals with their internal unfilled electron shells but also their oxides are catalytically active in reduction reactions (it is this reaction that provides water decomposition). It is seen from the table that oxidation of all the electrodes in air and in the course of exploitation causes the growth of φ which is more pronounced after thermal oxidation of electrodes. In most cases, thermal oxidation Semiconductor Physics, Quantum Electronics & Optoelectronics, 2007. V. 10, N 2. P. 40-45. © 2007, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 42 AJ, 10–6 Ohm–1 cm–1 0 10 20 30 0 10 20 30 2(-) 4(+) 3(-) 3(+) 1(-) 2(+) 1(+) t,min , 1 2 4 3 Fig. 2. AJ(t) dependences for the electrode pairs AlT TO-Yb (1, 1(+), 1(−)), NiTO-Yb (2, 2(+), 2(−)), Cr3SiTO-Yb (3, 3(+), 3(−)), Ti〈Pd4〉TO-Yb (4, 4(+)). The curves 1, 2, 3 and 4 were obtained at V0 = 0, curves marked with signs (+) and (−) at V0 = ±9.7 V on the Yb electrode, respectively. induces also the growth of AJ(t). Fig. 2 shows these dependences for thermally oxidized electrodes AlT TO, NiTO, Gr3SiTO, and Ti〈Pd4〉TO coupled with the aged Yb electrode. The superscripts (+) and (–) indicate the AJ(t) dependences when the voltages V0 = ±9.7 V are applied, respectively, to the Yb electrode. Curves 1-4 were obtained at V0 = 0. Comparing the dependences in Fig. 2 with the respective ones obtained before thermal oxidation of electrodes (in work [2] and in this one), we can draw conclusion that thermal oxidation increases the AJ(t) values (excluding the dependence for Ti〈Pd4〉TO) and often changes the character of their time dependences. It is indicative of the changes in the processes of catalytic decomposition of water molecules on electrodes as a consequence of the creation of oxide films thermally grown on them. A natural oxide film can provide the current creation along with water decomposition in some other way as compared to the thermally grown one. It was shown in [3] that a thermally grown film on Si increases the electron work function up to 10…11 eV and essen- tially changes the AJ(t) dependences when the Si ele- ctrode is coupled with Al, Yb, and Pt counterelectrodes. As seen from the table, the HF etching of the natural oxide film on a textured silicon electrode SiT AG aged for 10 years [6] changes φ only a little (from 4.85 down to 4.76 eV), while the character of the AJ(t) dependences is changed noticeably (Fig. 3a and b), but in another manner as compared to that in [3]. AJ, 10–6 Ohm–1 cm–1 0 10 20 30 0 10 20 2(+) 2(-) 1(+) 1(-) t,min 1 2 AJ, 10–6 Ohm–1 cm–1 0 10 20 30 0 10 20 2(-) 2(+) 1(-) 1(+) , t,min 1 2 Fig. 3. AJ(t) dependences for the electrode pairs SiT-Pt (a) and SiT-Yb (b). The curves 1, 1(+), 1(−) were obtained using aged textured silicon SiT AG, curves 2, 2(+), 2(−) – after treating it in HF (SiT HF). 1, 2 – at V0 = 0; 1(+), 2(+) and 1(−), 2(−), at V0 = ± 9.7 V on the SiT electrode, respectively. If the Pt electrode is coupled with the SiT electrode playing the role of an anode, curves 2, 2(+), and 2(−) (measured after etching the oxide film) possess some higher AJ(t) values as compared to the respective values for curves 1, 1(+), and 1(−) for the SiT AG electrode with the oxide film. In the pair with the Yb electrode where the SiT electrode serves as cathode, curves 1 and 1(+) possess lower AJ(t) values as compared with those for curves 2, 2(+) curves only in the initial parts of the time dependences. At t > 20 min, curve 1 is located above curve 2, as well as curve 1(+) is above curve 2(+) at t > 6 min. All these results indicate the changes in features of catalytic water decomposition both after deletion of the oxide film on the SiT electrode and after changing its role (anode or cathode). The essential role of a relief and thermal oxidation of the Al electrode in the character of AJ(t) dependences for Semiconductor Physics, Quantum Electronics & Optoelectronics, 2007. V. 10, N 2. P. 40-45. © 2007, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 43 the pair Al-Pt is illustrated in Fig. 4. Curves 1' and 2' were obtained, respectively, on the plane AlPAG and textured AlTAG electrodes, both being aged in ambient air. It is seen that the preliminary texturing of Al in an electrochemical bath with a chlorine salt solution considerably increases the catalytic activity of the Al electrode, which increases AJ(t). The latter value can be further increased in the course of thermal oxidation of AlP AG and AlТAG electrodes (see curves 1, 1(+), and 1(−) as well as 2, 2(+) and 2(−), respectively). The considerable distinction between curves 1(+) and 1(−) as compared with curves 2(+) and 2(−) indicates a considerable role of the electric field effects inherent to non-uniformities of the relief when decomposing molecules of water on the Al electrode. Faster catalytic decomposition of water can be obtained not only by texturing the Al electrode but by its grinding, which is especially clear pronounced for the first 10 min of the decomposition. This is evident from the comparison of curves 2' and 1' Gr obtained, respectively, for the textured and grinded Al electrodes. Grinding the electrode made of nickel silicide Ni3Si increases the AJ(t) values by 1.5-2 times, when it is used as cathode coupled with the AlP AG anode. Grinding the Ti electrode (cathode) also increases twice the AJ(t) values obtained in the pair with the Yb electrode (anode). The electrode made of a precious metal (Pt) can be successfully substituted with the electrode from thermally oxidized chromium silicide Cr3SiTO that possesses φ = 5.44 eV. In Fig. 5, we show the AJ(t) dependences for the pairs AlP AG-Cr3SiTO (curves 1, 1(+), and 1(−)), as well as those for AlTTO-Cr3SiTO (curves 2, 2(+), and 2(−)). It can be seen that the AJ(t) values in Fig. 5 are considerably higher than those in Fig. 4, especially for the pair AlTTO-Cr3SiTO. In our opinion, metal silicides are rather promising as cathodes for the more efficient current creation based on water decomposition. The time dependence AJ(t) at V = 0 obtained for the grinded ТіGr electrode (cathode) coupled with the Yb electrode is shown in Fig. 6 with curve 0. When the measurements last up to 2 h, the AJ(t) values increase up to 21·10-6 Ohm−1cm−1, ∆Vk being increased only from +1.14 to +1.19 V (sign (+) on the Yb electrode). In Fig. 6, curves 1, 2, 3, and 4 were obtained using the Yb electrode (anode) coupled with the ТіGr electrode (cathode) covered via step-by-step deposition by the Pd impurity with the following concentrations: 2·1016, 2·1017, 5·1017, and 1·1018cm−2, respectively. In the course of deposition, Al served as anode. In this case, the φ values determined relatively to the Pd electrode grew from 5.17 up to 5.39 eV. As seen from Fig. 6, at low concentrations (2⋅(1016…1017) cm−2) of Pd deposited on the grinded ТіGr electrode, the AJ(t) values are decreased (curves 1 and 2 as compared with curve 0). This means that, at the very beginning, Pd atoms neutralize catalytically active centers of a structural character, which arise after grinding. A further growth of the concentration of deposited Pd impurity results in the creation of new catalytically active Pd centers which enhance the AJ(t) values (curves 3 and 4). Curve 4(−) obtained after applying the voltage V0 = −9.7 V to the ТіGr〈Pd4〉 electrode evidences a considerable growth of the catalytic activity inherent to the ТіGr electrode doped with Pd in the presence of strong local electric fields on its surface. 0 10 20 30 0 5 10 15 20 2(-) 2(+) 1(-) 1(+) AJ,10-6Om-1cm-1 t,min 1 2 Fig. 5. AJ(t) dependences for the electrode pairs AlP AG-Cr3SiTO (1, 1(+), 1(−)) and AlТТО-Cr3SiTO (2, 2(+), 2(−)).The curves 1, 2 were obtained at V0 = 0; the signs (+) and (−) correspond to V0 = ±9.7 V on the Al electrode. 0 10 20 30 0 5 10 1' 1 1(-) 1(+) 2(+) 2(-)AJ,10-6Om-1cm-1 t,min 1 1' 2 2' ' Fig. 4. AJ(t) dependences for the electrode pairs AlP AG-Pt (1'), AlТAG-Pt (2'), AlP ТО-Pt (1, 1(+), 1(−)), AlТТО-Pt (2, 2(+), 2(-)), AlGr СВ-Pt (1' Gr). The curves 1', 2', 1, 2, 1' Gr at V0 = 0; the signs (+) and (−) correspond to V0 = ±9.7 V on the Al electrode. AJ, 10–6 Ohm–1 cm–1 AJ, 10–6 Ohm–1 cm–1 1′Gr 1′Gr Semiconductor Physics, Quantum Electronics & Optoelectronics, 2007. V. 10, N 2. P. 40-45. © 2007, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 44 AJ, 10–6 Ohm–1 cm–1 0 10 20 30 0 10 20 30 4(-) , t,min 4 3 1 2 0 Fig. 6. AJ(t) dependences for the electrode pair TiGr〈Pd〉-Yb. The curve 0 was obtained for the pair TiGr СВ-Yb in absence of Pd impurity, curve 1 – Pd (2·1016cm−2), 2 – Pd (2·1017cm−2), 3 – Pd (5·1017cm−2), 4 – Pd (1·1018cm−2), 4(−) − V0 = –9.7 V on the electrode TiGr〈Pd4〉. The highest AJ(t) values were obtained when using the Yb electrode as anode and Cr3Si as cathode that was preliminarily covered electrolytically with the Pd impurity up to the concentration close to 1·1018 cm−2. Fig. 7 illustrates the AJ(t) dependences for the pair Yb- Cr3Si without doping Cr3Si with Pd (curve 0), when the concentration of the doping impurity is equal to 1.5·1016 cm−2 (curve 1), as well as for the maximal concentration of the Pd impurity of 1·1018 cm−2 (curves 2, 2(+), and 2(−)). Moreover, in the catalytic water decomposition, an essential role is played by not only the Cr3Si〈Pd5〉 electrode but the Yb electrode as well, since the substitution of it with the AlP AG electrode results in considerably lower AJ(t) values (curves 3, 3(+), and 3(−)). The signs (+) and (−) marking curves in Fig. 7 mean the application of respective potentials, V0 = ±9.7 V, to the Yb or Al electrode. When studying the current transfer provided by the pair Yb-Cr3Si〈Pd5〉 for 2 h at V0 = 0, we observed the growth of AJ(t) values up to 100·10−6 Ohm−1cm−1. It is our highest value among those in works [1-3]. This means the creation of a current source with a current density close to 120 µA·cm−2 and the potential difference between the electrodes ∆Vk = +1.8 V, i.e., the power of this electrochemical system is close to 0.216 mW per 1 cm2 of the Cr3Si〈Pd5〉 electrode area. Note that the value ∆Vk = +1.8 V was the same both at t = 0 and t = 2 h. AJ, 10–6 Ohm–1 cm–1 0 10 20 30 0 50 100 150 3(+) 3(-) 2(+) 2(-) , t,min 0 1 3 2 Fig.7. AJ(t) dependences for the electrode pairs Yb-Cr3Si〈Pd〉 (curves 0, 1, 2, 2(+), 2(−)) and AlP AG-Cr3Si〈Pd5〉 (curves 3, 3(+), 3(−)). The curves 0, 1, 2, 3 were obtained at V0 = 0; the signs (+) and (−) correspond to V0 = ±9.7 V on the Yb and Al electrodes. The Cr3Si electrode was doped with Pd: 0 (Pd = 0); 1 (Pd = 1.5·1016cm−2); 2, 3 (Pd = 1·1018cm−2). This means that the growth of AJ(t) values from 33·10−6 Ohm−1⋅cm−1 (t = 0) up to 100·10−6 Ohm−1cm−1 (t = 2 h) is realized due to the increase in the catalytic activity of electrodes (first of all, that of the Cr3Si〈Pd5〉 electrode, because the Yb electrode activity is constant in the system Yb-Pt (Fig. 1) at t > 20 min and does not practically depend on its oxidation degree). Curves 2(+) and 2(−) corresponding to the maximum AJ(t) values confirm the essential influence of an electric field present on non-uniformities of doped Pd and on porous Cr3Si on the water decomposition. In [2], we have already estimated the recovered energy as a result of the water decomposition in accord with the reaction Н2О ↔ ОН + Н: 5.1 eV per one Н2О molecule [7]. However, in [2], we did not take into account the recovered energy (power) due to the current creation. Let us estimate a power gain under these conditions by taking into account both the current creation and the hydrogen output that can be also used for the energy yield. The calculations made following the way described in [2] show that a current density of 120 µA·cm−2 provides the release of approximately 6·1012 OH and H particles per one second. Their recombination in the course of the reaction Н + ОН → Н2О provides the power close to 4.8·10−3 mW, which is 45 times less than the value obtained due to the current (0.216 mW). Thus, the main source to recover energy in this process is the current, rather than the hydrogen output. Semiconductor Physics, Quantum Electronics & Optoelectronics, 2007. V. 10, N 2. P. 40-45. © 2007, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 45 Conclusions 1. We have investigated the time dependences for the current that arises between two electrodes with different electrochemical potentials when changing their catalytic activity as to the water decomposition by using the following physico- chemical factors: natural and thermal oxidation of electrodes, changing the character of their relief (chemical structuring, grinding, polishing), and the electrolytic deposition of a catalytically active Pd impurity onto electrodes. 2. It was found that natural (as well as in the course of operation) oxidation of the Yb electrode most often used as anode due to the low electron work function does not practically influence the current after 20 min since abridging the Yb-Pt electrodes. 3. Thermal oxidation (450 ºС, 4 h in dry О2) of electrodes (Al, Ti, Ni, Cr3Si) increases the electron work function for them and, as a rule, enhances the current between them and a counterelectrode (Yb, Pt, Al) both in the absence of an external voltage and at V0 = ±9.7 V. 4. The chemical structuring of the electrode (Al, Si) surface and the mechanical processing (grinding, polishing) of the electrodes (Al, Ti, Cr3Si, Ni3Si, Yb, Si) change the electron work function for these electrodes and their catalytic activity as to the water decomposition due to changes in the structure of the electrode surface and a natural oxide film covering them. 5. As a rule, structuring the electrode surface results in the acceleration of the catalytic water decomposition both at V0 = 0 and at V0 = ±9.7 V, which indicates an essential influence of the strong electric field arising at micro(nano)- nonuniformities of the electrode structure on water decomposition. 6. The best current creation (at V0 = 0) was observed in the case of the pair Yb-Cr3Si〈Pd5〉, when the current density reaches 120 µA·cm−2 at the voltage between the electrodes ∆Vk = 1.8 V. It has been calculated that the energy recovered due to the current creation is considerably higher (by tens of times) than that obtained with the use of reduced hydrogen. References 1. V.E. Primachenko, B.M. Bulakh, S.I. Kirillova, V.A. Chernobai, E.F. Venger, Electronic properties of palladium doped porous silicon and decomposition of water without an external electric voltage on its basis // Ukr. Phys. J. 52(3), p. 236- 243 (2007). 2. V.E. Primachenko, I.V. Kud’, S.I. Kirillova, V.A. Chernobai, Decomposition of water and application of electrode catalytic properties // Zhurnal Tekhnicheskoi Fiziki (2007) (be published) (in Russian). 3. V.E. Primachenko, A.A. Serba, V.A. Chernobai, E.F. Venger, Effect of oxidizing on water decomposition by catalytic active electrode on silicon based // Semiconductor Physics, Quantum Electronics and Optoelectronics 10(1), p.88 (2007). 4. Physical encyclopedia. Encyclopediya Publ., Moscow, 1988 (in Russian). 5. Short chemical encyclopedia. Encyclopediya Publ., Moscow, 1963 (in Russian). 6. S.I. Kirillova, V.E. Primachenko, A.A. Serba, L.P. Tarasenko, V.A. Chernobai, Temperature dependence of surface potential on textural silicon surface // Optoelektronika i Poluprovodnikovaya Tekhnika N 27, p. 29-35 (in Russian). 7. H.B. Gray, Electrons and Chemical Bonding. Ben- jamin, New York, 1964.

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