To
understand the effect of the ethylene glycol (EG) substituent
of alkanethiols on domain formation, surface structure, and adsorption
condition of self-assembled monolayers (SAMs) on Au(111), we examined
SAMs formed by 1-ethanethiol with methoxy-terminated mono(ethylene
glycol) (EG1-OMe SAMs) by scanning tunneling microscopy
(STM) and X-ray photoelectron spectroscopy and compared the results
to those of heptanethiolate SAMs with a normal alkyl chain of similar
molecular length. STM imaging clearly revealed that the surface features
of EG1-OMe SAMs on Au(111) were noticeably different than
those of heptanethiolate SAMs. The adsorption of EG1-OMe
molecules on Au(111) in a 1 mM ethanol solution at RT for 1 min led
to the formation of SAMs containing mixed phases: a paired-row ordered
phase and poorly ordered phase containing molecular spots with an
apparent bright contrast. The paired-row ordered domain of EG1-OMe SAMs on Au(111) was assigned to the (2√5 ×
5)R11° packing structure, which is comparable to a closely packed c(4 × 2) structure for heptanethiolate SAMs. After
a longer immersion of 24 h, similar surface features were also observed
with a different (√3 × 7) packing structure. The formation
of these unique domains for EG1-OMe SAMs on Au(111) was
caused by a conformational change of the EG1-OMe backbone
due to the electrostatic repulsions of oxygen atoms between the EG1 substituents in the SAMs. We report the first STM results
of EG1-OMe SAMs on Au(111) showing very unique surface
features that have not been observed in other SAM systems derived
from alkanethiols or aromatic thiols. X-ray photoelectron spectroscopy
(XPS) measurements also showed that EG1-OMe SAMs on Au(111)
were formed by chemical reactions between the thiol group and Au(111)
surface. The results obtained from a molecular-scale viewpoint will
provide new insight into the effect of EG1-OMe substituent
attached to ethanethiol on the formation and structure of EG1-OMe SAMs on Au(111).
The surface structure
and binding conditions of self-assembled
monolayers (SAMs) on Au(111) derived from 1-acetylthio-4-[(phenyl)ethynyl]benzene
(OPE2-SAc) without and with tetrabutylammonium cyanide (TBACN) as
a deprotection reagent were examined using scanning tunneling microscopy
(STM) and X-ray photoelectron spectroscopy (XPS). STM observation
revealed that OPE2-S SAMs on Au(111) formed from direct adsorption
of OPE2-SAc in 1 mM methanol solution at room temperature (RT) for
24 h were composed of short-range, ordered phase separated by a disordered
phase. In contrast, adsorption of OPE2-SAc SAMs on Au(111) at a higher
solution temperature of 50 °C for 24 h led to formation of a
fully ordered phase with slightly increased domain size. The structural
quality of OPE2-S SAMs on Au(111) was remarkably enhanced when TBACN
was used. OPE2-S SAMs at RT had a well-ordered (√3 × √7)R30°
structure with a domain size larger than 80 nm. The SAMs deposited
at 50 °C contained very uniform and highly ordered domains with
a size exceeding 100 nm, which can be assigned to a (2 × 3√3)rect
structure. XPS measurements showed that OPE2-S SAMs were mainly formed
via chemical interactions between sulfur and the Au(111) surface regardless
of the use of a TBACN deprotection reagent. In this study, we reported
the first molecular-scale features of OPE2-S SAMs on Au(111) with
highly ordered domains derived from OPE2-SAc and clearly demonstrated
that TBACN can be used as an effective deprotection reagent for formation
of uniform and well-ordered OPE2-S SAMs with long-range domains derived
from thioacetyl-protected OPE2-S molecules on Au(111).
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