Reaction Pathways of 2-Iodoacetic Acid on Cu(100): Coverage-Dependent Competition between C−I Bond Scission and COOH Deprotonation and Identification of Surface Intermediates

Lin, Yi; Lin, Jain Shiun; Liao, Yung Hsuan; Yang, Che Ming; Kuo, Che Wei; Lin, Hsueh-Yi; Fan, Liang Jen; Yang, Yaw Wen; Lin, Ja‐Chen

doi:10.1021/la904576z

Cited by 4 publications

(7 citation statements)

References 17 publications

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“…The O 1s spectrum can be fitted with three peaks located at 531.3, 532.7, and 533.7 eV. Previously, the respective O 1s binding energies have been found at 532.4 eV (broad) and 532.9 eV for the acetic acid on Cu(110) and the iodoacetic acid on Cu(100). , Upon deprotonating the acetic acid on Cu(110) to form acetate, the O 1s peak is shifted to 531.6 eV . Acetate on hydroxylated NiO(111) has an O 1s binding energy of 531.2 eV .…”

Section: Resultsmentioning

confidence: 91%

“…Previously, the respective O 1s binding energies have been found at 532.4 eV (broad) and 532.9 eV for the acetic acid on Cu(110) and the iodoacetic acid on Cu(100). 11,12 Upon deprotonating the eV has been reported for H 2 O on Cu(100) and Ni(110). 14,15 Four deconvoluted peaks are obtained at 284.9, 286.2, 287.8, and 289.7 eV after curve-fitting to the C 1s spectrum (Figure 2).…”

Section: ■ Results and Discussionmentioning

confidence: 98%

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Comparative Study on the Reaction Pathways of 2-Chloropropanoic Acid on Cu(100) and O/Cu(100)

et al. 2016

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CH 3 CHCOOH and CH 3 CHCOO have been theoretically predicted to be important in the decarboxylation or decarbonylation of propanoic acid on Pd(111). In the present study, we explore the possibility to prepare these two intermediates on Cu(100) and oxygen-predosed Cu(100) (O/Cu(100)), with CH 3 CHClCOOH as the precursor, and to investigate their adsorption geometries and reactions on the surfaces using X-ray photoelectron spectroscopy, reflection− absorption infrared spectroscopy, temperature-programmed reaction/desorption, and calculations of density functional theory. CH 3 CHClCOO and CH 3 CHCOO are suggested to be formed on Cu(100) at 250 K by heating the CH 3 CHClCOOH adsorption layers. However, CH 3 CHCOO can promptly recombine with the H from the deprotonation of CH 3 CHClCOOH to generate CH 3 CH 2 COO. The adsorbed propanoate decomposes mainly into H 2 , CO, and CO 2 at a temperature higher than ∼380 K. On O/Cu(100), CH 3 CHClCOO is the predominant species found in the dissociation of CH 3 CHClCOOH at 250 K. The preadsorbed O disables the CH 3 CHCOO hydrogenation to form CH 3 CH 2 COO due to the lack of adsorbed H. This intermediate is not stable above ∼400 K and decomposes into H 2 , H 2 O, CO, and CO 2 , probably with a small amount of acrolein or methylketene. The CH 3 CHCOO is shown theoretically to be bonded on Cu(100) via the unsaturated carbon and one of the oxygen atoms.

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Section: Resultsmentioning

confidence: 91%

Section: ■ Results and Discussionmentioning

confidence: 98%

Comparative Study on the Reaction Pathways of 2-Chloropropanoic Acid on Cu(100) and O/Cu(100)

et al. 2016

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“…No ICH 2 CN desorption below 1.2 L indicates that ICH 2 CN dissociates on the surface at 180 K or during the heating course in the TPD experiment. The previous studies regarding the chemistry of alkyl iodides on copper single crystals indicated that C−I bond scission is the primary reaction step, which occurs below 180 K, resulting in the formation of adsorbed iodine atoms and alkyl groups.29−31 Indeed, the separate X-ray photoelectron spectroscopic study of ICH 2 CN/Cu(100), as shown in supporting FigureS1, confirms the C−I breakage at 180 K. FigureS1shows the I 4d XP spectra taken after ICH 2 CN adsorption (2.0 L) on Cu(100) at 180 K, followed by annealing to 210 K. There are four resolved peaks in the 180 K spectrum that can be attributed to ICH 2 CN molecules (50.8 and 52.5 eV) and iodine atoms (49.5 and 51.2 eV) on Cu(100) 32,33. The C−I bonds dissociate completely at 210 K.Spectroscopic Evidence of Coverage-Dependent CH 2 CN Adsorption Structures.…”

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confidence: 99%

Adsorption and Reactions of ICH₂CN on Cu(100) and O/Cu(100)

et al. 2013

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Monitoring surface species and their bonding structures in link to specific chemical processes has long been an active, important subject in heterogeneous catalysis. In this article, with employment of temperature-programmed reaction/desorption, reflection− absorption infrared spectroscopy, Auger electron spectroscopy, and X-ray photoelectron spectroscopy in combination with density functional theory computation, we present three CH 3 CN formation channels from reaction of CH 2 CN generated by ICH 2 CN dissociative adsorption on Cu(100) and first spectroscopic evidence for CHCN on single crystal surfaces. The CH 3 CN formation mechanisms are dependent on CH 2 CN adsorption geometries. At lower coverages, CH 2 CN is adsorbed with the C−C−N approximately parallel to the surface. Reaction of these adsorbates produces CH 3 CN via firstand second-order kinetics, with the largest desorption rates occurring at 213 K and ∼400 K, respectively. At or near a saturated first-layer coverage, decomposition of ICH 2 CN forms C-bonded CH 2 CN (−CH 2 CN), which then transforms to N-bonded −NCCH 2 with tilted orientation. Disproportionation of the −NCCH 2 generates CH 3 CN at ∼324 K. Thermal products of H 2 , HCN and (CN) 2 evolving at higher temperatures are originated from the CHCN dissociation. On oxygen-precovered Cu(100), reaction of CH 2 CN forms new surface intermediates of vertical −NCO and −CCO, in addition to perturbed CH 3 CN desorption. In the conditions studied, formation of H 2 , HCN, and (CN) 2 is terminated due to the presence of preadsorbed O. −NCO and −CCO on O/Cu dissociate at ∼525 and 610 K, respectively, into CO and CO 2 .

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“…In the 370 K spectrum, the peaks of I 4d3/2 at 51.3 eV and I 4d5/2 at 49.6 eV are ascribed to I adsorbed on Cu(100) in accordance with previously reported assignments. 19 This result, together with the absence of other iodine signals, also indicates that both CÀI bonds in 1,3-C 6 H 4 I 2 have dissociated on Cu(100) at 370 K, leaving atomic iodine on the surface. The 230, 290, and 320 K spectra can be nicely fitted with four peaks.…”

Section: ' Results and Discussionmentioning

confidence: 88%

“…However, none of hydrocarbons was detected, but H 2 . In Figure 5 showing the TPR/D spectra of hydrogen, it is found that H 2 starts to desorb at approximately 550 K and extends up to ∼900 K. This result suggests that no H atoms are present on the surface before 550 K, i.e., the CÀH bonds remaining intact before 550 K, because it has been known that recombination of H atoms on Cu(100), forming H 2 , occurs around 300 K. 19 After considering that the two CÀI bonds of 1,3-C 6 H 4 I 2 have dissociated at 370 K, as shown in Figure 2, C 6 H 4 is suggested to be the species present on the surface at this temperature. In the inset of Figure 5, the yield of H 2 desorption increases linearly with exposure of 1,3-C 6 H 4 I 2 and levels off as the exposure is approximately above 3.0 L. Figure 6 shows the Auger electron spectra obtained after adsorption of 3 L 1,3-C 6 H 4 I 2 on Cu(100) at 180 K, followed by briefly heating the surface to 450 and 980 K. Both the carbon (∼276 eV) and iodine (∼512 and 521 eV) peaks are detected at 450 K. The carbon is ascribed to the presence of C 6 H 4 from CÀI bond breakage of 1,3-C 6 H 4 I 2 .…”

Section: ' Results and Discussionmentioning

confidence: 96%

Bonding Structure, Dehydrogenation, and Dimerization of 1,3-C₆H₄ from Decomposition of 1,3-C₆H₄I₂ on Cu(100)

Liao

Lin

et al. 2011

J. Phys. Chem. C

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Temperature-programmed reaction/desorption, Auger electron spectroscopy, X-ray photoelectron spectroscopy, and near-edge X-ray absorption fine structure in combination of calculations based on density functional theory have been employed to investigate adsorption and reaction of 1,3-C 6 H 4 I 2 on Cu(100). At 100 K, the surface species after 1,3-C 6 H 4 I 2 adsorption are found to be 1,3-C 6 H 4 I 2 , C 6 H 4 I, and 1,3-C 6 H 4 . The formation of these adsorbates is dependent on the adsorption sites of 1,3-C 6 H 4 I 2 . 1,3-C 6 H 4 I 2 adsorbed with the ring at a hollow site and parallel to the surface is predicted to be unstable and preferentially leads to CÀI bond dissociation. 1,3-C 6 H 4 , the intermediate from 1,3-C 6 H 4 I 2 decomposition, has a tilted adsorption geometry with a distorted ring. H 2 is the only reaction product observed after 550 K in the 1,3-C 6 H 4 I 2 decomposition on Cu(100), with all of the carbon atoms left on the surface. Dimerization of 1,3-C 6 H 4 molecules on Cu(100) has been described computationally, showing an activated and exothermic process. With the theoretically obtained activation energy of 28.2 kcal/mol and estimated surface coverages, coupling of 1,3-C 6 H 4 can occur by second-order kinetics before H 2 evolution. Dimerization of 1,3-C 6 H 4 on Cu(100) shows a different intermolecular interaction behavior from those of 1,2-C 6 H 4 and 1,4-C 6 H 4 on copper single crystal surfaces.

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Reaction Pathways of 2-Iodoacetic Acid on Cu(100): Coverage-Dependent Competition between C−I Bond Scission and COOH Deprotonation and Identification of Surface Intermediates

Cited by 4 publications

References 17 publications

Comparative Study on the Reaction Pathways of 2-Chloropropanoic Acid on Cu(100) and O/Cu(100)

Comparative Study on the Reaction Pathways of 2-Chloropropanoic Acid on Cu(100) and O/Cu(100)

Adsorption and Reactions of ICH₂CN on Cu(100) and O/Cu(100)

Bonding Structure, Dehydrogenation, and Dimerization of 1,3-C₆H₄ from Decomposition of 1,3-C₆H₄I₂ on Cu(100)

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Reaction Pathways of 2-Iodoacetic Acid on Cu(100): Coverage-Dependent Competition between C−I Bond Scission and COOH Deprotonation and Identification of Surface Intermediates

Cited by 4 publications

References 17 publications

Comparative Study on the Reaction Pathways of 2-Chloropropanoic Acid on Cu(100) and O/Cu(100)

Comparative Study on the Reaction Pathways of 2-Chloropropanoic Acid on Cu(100) and O/Cu(100)

Adsorption and Reactions of ICH2CN on Cu(100) and O/Cu(100)

Bonding Structure, Dehydrogenation, and Dimerization of 1,3-C6H4 from Decomposition of 1,3-C6H4I2 on Cu(100)

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Adsorption and Reactions of ICH₂CN on Cu(100) and O/Cu(100)

Bonding Structure, Dehydrogenation, and Dimerization of 1,3-C₆H₄ from Decomposition of 1,3-C₆H₄I₂ on Cu(100)