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Sulfur-Quinone Polyurethanes and the Protection of Iron against Corrosion Yongqi Hu1,3, A. Brent Helms1,3, David E. N i k l e s 1,3,*, Rahul Sharma2,3, Shane C. Street , Garry W. Warren2,3, and Dehua Yang 1,3
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Departments of C h e m i s t r y and Metallurgical and Materials Engineering and Center for Materials for Information Technology, The University of Alabama, Tuscaloosa, A L 35487-0209 *Corresponding author: Email:
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A sulfur-quinone diol monomer, 2,5-bis-(2-hydroxyethylthio)1,4-benzoquinone (SQM-2), was prepared by the reaction of 2mercaptoethanol with 1,4-benzoquinone. SQM-2 and polycaprolactone diol (M = 1250) were condensed with toluene diisocyanate to give a sulfur-quinone polyurethanes, SQPU-1, containing 7 mole percent SQM-2. SQPU-1 was coated onto an iron square and exposed to either 0.1 M sodium chloride electrolyte or substitute ocean water. Electrochemical impedance spectroscopy monitored any degradation of the coatings and showed that the sulfur-quinone polyurethane protected the iron against corrosion. Reflectance absorption infrared spectroscopy showed that the chemisorbed sulfur-quinone functional group lies parallel to the iron surface. n
For more than a decade polymers containing the 2,5-diamino- 1,4benzoquinone functional group have been of interest, since Erhan's observation that this class polymers have a strong affinity for the surface of iron. They found that the amine-quinone polymers could displace moisture from the surface of iron, making it hydrophobic. If the amine-quinone polymers would prevent moisture from adsorbing onto the iron surface, then they would inhibit corrosion. Indeed, they reported salt-spray testing data showing that aminequinone polymers prevent corrosion. We have synthesized amine-quinone polyurethanes by condensing the amine-quinone monomer, 2,5-bis(N-2-hydroxyethyl-N-methylamino)-1,4benzoquinone, and an oligomeric diol monomer (e.g., polycaprolactone diol, 1
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polytetrahydrofuran diol) with a diisocyanate (TDI, MDI or IPDI). These polyurethanes were shown to inhibit the corrosion of the commercial iron particles used in state-of-the-art metal particle tape. They also promoted the adhesion of epoxy to steel. Curiosity led us to explore the possibility of replacing the amine group with a thioether group. We have developed the synthesis of a sulfur-quinone diol monomer and die preparation of polyurethanes containing this sulfurquinone monomer. We also demonstrated that the sulfur-quinone polyurethanes protect commercial iron particles against corrosion by pH 2 aqueous buffer. He we report further investigations of the corrosion protection of iron by sulfur-quinone polymers. We also report evidence for bonding interactions between the sulftir-quinone functional group an iron surface. 4
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Experimental Materials. Cyclohexanone (HPLC grade), was purchased from Fisher and used as received. Iron squares (99.5+%, 1.5 mm thick, 25 mm χ 25 mm or 50 mm χ 50 mm) were purchased from Goodfellow. The synthesis of SQM-1, SQM-2 and sulfur-quinone polyurethane (SQPU) were described in previously. SQPU-1 was made by a random copolymerization of 4 mmol polycaprolactone diol (PCL with molecular weight of 1250), 0.7 mmol SQM-2 and 4.7 mmol toluene diisocyanate. Electrochemical Impedance Spectroscopy. The polished iron squares (50 mm χ 50 mm) were spin coated with SQPU-1 polymer solution (10 weight percent in cyclohexanone). A thickness of 10 μιη was obtained by coating iron square twice in order to minimize the number of defects or D-type areas. The coating was dried in air for 24 hr then in a vacuum oven at 40°C for another 24 hr. The coating thickness was determined with a Sloan Dektak II surface profilometer from the average of at least five measurements in different locations. Electrochemical impedance spectroscopy (EIS) measurements on the coated metal square were carried out using an electrochemical cell consisted of a Plexiglass cylinder (25 mm inner diameter) placed on top of the coated substrate in order to create a vessel to hold the aqueous electrolyte, either 0.1 M NaCl or substitute ocean water. The experimental details have been reported elsewhere. Surface Spectroscopy. Iron squares (25 mm χ 25mm) were polished with 240, 400, 600 silicon carbide grit papers, then with 1 and 3 μιη A1 0 slurries, followed by degreasing with CH C1 vapor. Films of SQM-1 were deposited by spin coating from a 0.005 weight percent solution in cyclohexanone) at 1500 rpm. The films were dried in vacuum oven at 40°C for 24 hr. XPS spectra were collected with an AXIS 165 X-ray Photoelectron/Auger Scanning Surface Analysis system using A l monochromatic K X-rays as the excitation source. The samples were pumped down to 5 χ 10" ton* before being put into sample transfer chamber and analytical testing chamber, where the measurements were 6
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taken at 4 χ 10* ton*. The spectrometer work function was adjusted so that the 4f peak of a pure Au sample was at 84.0 eV. High resolution scans were made with the analyzer set at a 80 eV constant pass energy and an average irradiation time of 1 min. was used to scan. Charge compensation was made for the testing of SQM-1 powder pellet. Reflectance IR spectra were obtained using a Digilab FTS-40 spectrometer with room temperature DTGS detector and single reflection accessory at 70° angle of incidence. The number of scans was 4000 with 16 cm" resolution. Background spectra were measured on a polished bare iron surface.
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Results and Discussion EIS was used to investigate the ability of SQPU-1 to inhibit the corrosion of iron during exposure to 0.1 M aqueous NaCl. In figures 1 and 2 are plots of impedance and phase angle as a function of frequency. The initial spectrum showed the coatings were behaving like a dielectric over a wide range of frequencies. The resistance of the coating exceeded 10 ohms. After 95 days of exposure, the EIS spectrum for the commercial polyurethane , fig. 1, showed a new peak in the phase angle curve, indicative of a electrochemical double layer. The electrolyte had diffused through the coating and broken the adhesive bond between the polymer and the iron. Pitting corrosion was observed soon after this feature appeared. After 95 days exposure SQPU-1, fig. 2, showed very little change, indicating the coating was acting as a barrier, preventing moisture from penetrating to the iron surface and breaking the adhesive bond between the polymer and the iron. SQPU-1 also resisted attack by substitute ocean water, fig. 3. The sulfur-quinone polyurethane contained many different function groups that confound the interpretation of the x-ray photoelectron spectra. We tried obtaining data on the sulfur, but the photoelectron yield was so low, that beam damage occurred before we could obtain a reasonable signal to noise. Therefore we adsorbed the simple model compound, SQM-1 onto iron and obtained spectra, figure 4. The oxygen Is peak for the bulk sample had a binding energy of 530 eV. When adsorbed to iron there were two oxygen peaks, one at 530 eV and a new feature with a 1 eV higher binding energy. This higher binding energy suggested that the oxygen atoms in SQM-1 were donating electron density to iron surface, forming a coordination bond. This coordinate bond could be main source for strong interfacial reaction between SQPU polymers and metal surface. In other words this coordination bond is a key factor for the control of metal corrosion rate by sulfur-quinone polymers. We attempted to obtain sulfur XPS data for SQM-1 on iron. Unfortunately XPS data for sulfur were very noisey due to a small cross section of sulfur requiring more collecting time imposed which led to the decomposition of SQM-1, especially in the case of spin coated thin layer on iron surface. A grazing incidence reflectance infrared spectrum, fig. 5, for SQM-1 on iron showed the absence of the quinone C-H stretching mode at 3045 cm' . The quinone carbonyl stretching mode at 1640 cm" was also missing, fig. 6. This suggests that the quinone lies parallel to the iron surface. 6
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In Electroactive Polymers for Corrosion Control; Zarras, P., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.
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Frequency (Hz)
Figure 1. Bode plot for a commercial polyurethane binder exposed to 0.1M NaCl electrolyte. Open circles - phase angle curves, closed circles - impedance curves.
Frequency (Hz)
Figure 2. Bode plots for data obtained for an iron sample coated with SQPU1 and exposed to 0.1M NaCl electrolyte. The closed symbols are the impedance curves. The open symbols are the phase angle curves. Circles - initial curve, squares - 70 days exposure, triangles - 85 days exposure, upside down triangles - 95 days exposure.
In Electroactive Polymers for Corrosion Control; Zarras, P., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.
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Frequency (Hz)
Figure 3. Bode plots for data obtained for an iron sample coated with SQPU1 and exposed to substitute ocean water. The closed symbols are the impedance curves. The open symbols are the phase angle curves. Circles initial curve, squares - 40 days exposure.
Binding Energy (eV)
Figure 4. Oxygen Is XPS for SQM-1.
In Electroactive Polymers for Corrosion Control; Zarras, P., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.
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SQM-1 thin film on iron
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Figure 5. Reflectance infrared spectrum for SQM-1. Spectra recorded in the C-H stretching region.
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Conclusions SQPU polymers were good candidates for the protection of metal corrosion. Sulfur-quinone functional groups in SQPU polymers provided a high affinity for the iron surface by forming coordinate bonds. The adhesive bond was so strong that it can not be broken by water. This interfered with the ability of water to adsorb to the iron surface and form an electrolyte, effectively inhibiting down corrosion. Acknowledgments This work was supported by the sponsors of the Center for Materials for Information Technology. Y. Hu was supported by the School of Graduate Studies by a Graduate Council Fellowship. D. Yang was supported by the NSF Materials Research Science and Engineering Center award DMR-9809423. The MRSEC also provided shared user instrumentation. The x-ray photoelectron spectrometer was purchased under the NSF Academic Research Infrastructure award DMR-9512264. References (1) Kaleem, K.; Chertok, F.; Erhan, S. Prog. Organ. Coatings 1987, 15, 6371, Nithianandam, V. S.; Erhan, S. J. Appl. Polym. Sci. 1991, 42, 23872389, Nithianandam, V. S.; Erhan, S. Polymer 1991, 52, 114, Kaleem, K.; Chertok, F.; Erhan, S. J. Polym. Sci, Pt A, Polym. Chem. 1989, 27, 865-871, Nithianandam, V. S.; Chertok, F.; Erhan, S. J. Appl. Polym. Sci. 1991, 42, 2899-2901, Nithianandam, V. S.; Kaleem, K.; Chertok, F.; Erhan, S. J. Appl. Polym. Chem. 1991, 42, 2893-2897, Reddy, T. Α.; Erhan, S. J. Polym. Sci, Pt A, Polym. Chem. 1994, 32, 557-565. (2) Nithianandam, V. S.; Chertok, F.; Erhan, S. J. Coating Technol. 1991, 63, 47-49. (3) Nikles, D. E.; Liang, J.-L.; Cain, J. L.; Chacko, A. P.; Webb, R. I.; Belmore, K. J. Polym. Sci., Pt. Α.: Polym. Chem. 1995, 33, 2881-2886. (4) Liang, J.-L.; Nikles, D. E. IEEE Trans. Magnetics 1993, 29(6), 36493651, Nikles, D. E.; Cain, J. L.; Chacko, A. P.; Webb, R. I. IEEE Trans. Magnetics 1994, 30(6), 4068-4070. (5) Vaideeswaran, K.; Bell, J. P.; Nikles, D. E. J. Adhes. Sci. Technol. 1999, 13(4), 477-499. (6) Hu, Y.; Nikles, D. Ε J. Polym. Sci., Pt A, Polym. Chem. 2000, 38(18), 3278-3283. (7) ASTM Standard D1141-86, Substitute Ocean Water (1986). (8) Warren, G. W.; Sharma, R; Nikles, D. E.; Hu, Y.; Street, S. Materials Research Society Proceedings, Volume 517, 439-444, 1998., Warren, G. W.; Sharma, R.; Hu, Y.; Nikles, D. E.; Street, S. J. Magn. Magn. .Mat.. 1999, 193, 276-278.
In Electroactive Polymers for Corrosion Control; Zarras, P., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2003.