Sains Malaysiana 36(1): 27-32 (2007)
Adsorbed CO at Polycrystalline Copper in Phosphate Buffered Solution
(CO Terjerap dipermukaan Kuprum Polihablur dalam Larutan Tampan Fosfat)
Jumat Salimon
Pusat Pengajian Sains Kimia dan Teknologi Makanan
Fakulti Sains dan Teknologi, Universiti Kebangsaan Malaysia
43600 UKM Bangi Selangor D.E. Malaysia
AbstraCT
The adsorption of CO at polycrystalline copper surface was investigated spectroscopically. It was found that CO adsorbed as a linear adsorbed CO, Cu-COL and was a dominant species on copper surface at low CO concentration. A Cu-COL was electrochemically converted to a bridge bonded CO, Cu-COB at a high CO concentration condition. Increasing the CO surface coverage, qCO will increase the formation of adsorbed bridge bonded CO. A nitrogen gas purging treatment was used to examine the stability of an adsorbed CO through the evacuation process. The result showed that Cu-COB remained intact while Cu-COL was completely removed from the copper surface. It suggests that Cu-COL may involve in a weak bonding to a copper surface such as in a physisorbed interaction, while Cu-COB consists much stronger bonding such as a chemisorbed interaction. The N2 purging treatment also gave an additional prove that Cu-COB was partly converted to Cu(I)-CO at anodic potential regions.
Keywords: Adsorbed carbon monoxide; copper surface
AbsTRAK
Penjerapan CO di atas permukaan polihablur kuprum telah dikaji melalui sifat spektroskopiknya. Didapati CO yang terjerap wujud dalam bentuk CO terjerap linear, Cu-COL dan merupakan bentuk CO terjerap yang dominan pada kepekatan CO yang rendah. Cu-COL bertukar secara elektro-kimia ke bentuk CO terjerap secara jambatan, Cu-COB pada kepekatan CO yang tinggi. Penambahan penurapan permukaan CO, qCO akan menambahkan kadar pembentukan CO terjerap secara jambatan. Kestabilan CO terjerap telah diuji secara pengolahan penyahjerapan melalui proses alih tukar gas nitrogen. Hasil kajian menunjukkan bahawa Cu-COB didapati masih kekal manakala Cu-COL telah terkeluar keseluruhannya dari permukaan kuprum. Ini mencadangkan bahawa pembentukan Cu-COL melibatkan ikatan secara lemah ke atas permukaan kuprum seperti jerapan fizik, sementara Cu-COB terlibat dengan ikatan yang kuat seperti jerapan kimia. Pengolahan alih tukar gas nitrogen juga memberi bukti tambahan bahawa sebahagian Cu-COB telah bertukar kebentuk kuprum(I) karbonil, Cu(I)-CO pada julat keupayaan anodik.
Kata kunci: Krbon monoksida terjerap; permukaan kuprum
RUJUKAN/REFERENCES
Beden, B., Melendres, C.A., Bowmaker, G.A., Liu, C., Maroni, V.A., The adsorption of CO and H2O on polycrystalline gold, as studies by synchrotron infrared spectroscopy, 1994. Synchroton Techniques in Interface Electrochemistry, 432: 433-449.
Biberian, J.P. & Van Hove, M.A. 1984. A new mood for carbon monoxide ordering at high coverage on low index metal surface: a correlation between LEED, HREELS and IRS.II. carbon monoxide adsorbed on fcc.(111) and hcp.(0001) surface, Surf. Sci. 138: 361-389.
Blitz, M.A., Mitchell, S.A. & Hackett, P.A. 1991. Gas-phase reactions of copper atom: formation of copper dicarbonyl, bis(acetylene)copper and bis(ethylene)copper, J. Phys. Chem. 95(22): 8719- 8726.
Blyholder, G. & Lawless, M. 1993. A theoretical study of the site of carbon monoxide dissociation on iron(100), J. Phys. Chem. 290: 155-162.
Chenier, J.H.B., Hampson, C.A., Howard, J.A. & Mile, B. 1989. A spectroscopy study of the reaction of copper atom onto carbon monoxide in a rotatory cryostat: evidence for the formation of monocarbonylcopper, tricarbonylcopper and hexacarbonyldicopper, J. Phys. Chem. 93: 114-117.
Fournier, R. 1995. Theoritical study of the bonding of ammonia, carbon monoxide and ethylene to copper atom, dimmer and trimer, J. Chem. Phys. 102: 5396-5407.
Hee, J.W., Kuhn, W.K., Leung, L.H. & Goodman, D.W. 1990. Infrared vibrational studies of carbon monoxide adsorption on ultrathin copper films on a rhodium(100) surface, J. Chem. Phys. 93(10): 7463-7470.
Hollins, P. 1983. Interaction of carbon monoxide molecules adsorbed on oxidized copper(III) and copper (110), Surf. Sci. 134: 91-108
Hollins, P. & Pritchard, J. 1980. Vibrational Spectroscopy of Adsorbates, Series in “Chemical Physics”, vol. 15, Chp. 8, 567-573
Jumat Salimon, 2001. Electrocatalytiv activity of copper towards reduction of CO2, Ph.D. thesis, University of Wales, United Kingdom.
Jumat Salimon & Maher Kalaji, 2001. Linearly adsorbed carbon monoxide at polycrystalline copper: the influence of anions, temperature and pH. Malay. J. of Science. 20: 71-76.
Kitamura, F., Takahashi, M. & Ito, M. 1988. Adsorption site interconcersion induced by electrode potential of carbon monoxide on the platinum (100) single-crystal electrode, J. Phys. Chem. 92: 3320-3323.
Ogasawara, H., J. Inukai, J. & Ito, M. 1992. Potential induced migration of top layer atoms and molecules on platinum (110) electrode surface studied by Infrared Reflection Adsorption Spectroscopy, Chem. Phys. Let. 198: 389-394.
Persson, B.N.J., Tushaus, M. & Bradshaw, A.M. 1990. On the nature of dense carbon monoxide adlayers, J. Chem. Phys. 92: 5034-5046.
Raval, R., Parker, S.F., Pemble, M.E., Hollins, P., Pritchard, J. & Chesters, M.A. 1988. FT-RAIRS, EELS and LEEDS studies of the adsorption of carbon monoxide on copper (III), Surf. Sci. 203: 353-377.
Ruggiero, C. & Hollins, P. 1996. Adsorption of carbon monoxide on the gold (332) surface, J. Chem. Soc., Faraday Trans. 92: 4829-4834.
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