Sung-Kee Jo scite author profile

The structure of benzene deposited on a Cu(111) surface has been investigated by a combination of temperature-programmed desorption (TPD), high-resolution electron energy loss spectroscopy (HREELS), and near-edge x-ray absorption fine structure (NEXAFS) measurements. The results indicate that benzene forms a stable bilayer on Cu(ll1) at 110 K prior to multilayer formation. The TPD studies show that the second layer benzene desorbs with a peak temperature 5 K higher than that for benzene multilayers. HREELS and NEXAFS results indicate that benzene in the first layer bonds with its T ring parallel to the surface. With increasing coverage, benzene forms a second layer with its GT ring significantly tilted away from the surface. The results are consistent with an approximately perpendicular configuration between the first and second layer benzene molecules, which is analogous to the structure of crystalline benzene. Isotope labeling experiments indicate there is almost complete mixing between molecules in different layers during sequential adsorption at 110 K.

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Quantitative and sensitive detection of SARS coronavirus nucleocapsid protein using quantum dots‐conjugated RNA aptamer on chip

Roh

2011

J of Chemical Tech & Biotech

119

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CH3I and C2H5I on Au(100): adsorption and reaction

Yang

Avila

et al. 1995

Surface Science

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Relationship between body composition and bone mineral density (BMD) in perimenopausal Korean women

Kim¹,

Oh²,

Rhee³

et al. 2009

Clinical Endocrinology

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Direct Absorption of Gas-Phase Atomic Hydrogen by Si(100): A Narrow Temperature Window

Kang

Yan³

et al. 2000

Phys. Rev. Lett.

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Absorption of thermal-energy gaseous hydrogen atoms by Si(100), exceeding by far the dopant and other impurity concentrations, occurs within a narrow substrate temperature (T(s)) window centered at approximately 460 K. The absorbed hydrogen persists in the crystalline bulk as highly mobile species before migrating out and desorbing as molecular hydrogen at T(s) as high as 900 K, well above the recombinative desorption temperatures of surface-adsorbed H. Developing and sustaining atomic-scale surface roughness, by H-induced silicon etching, is a prerequisite for H absorption and determines the T(s) window.

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Sung-Kee Jo

Benzene adsorption on Cu(111): Formation of a stable bilayer

Quantitative and sensitive detection of SARS coronavirus nucleocapsid protein using quantum dots‐conjugated RNA aptamer on chip

CH3I and C2H5I on Au(100): adsorption and reaction

Relationship between body composition and bone mineral density (BMD) in perimenopausal Korean women

Direct Absorption of Gas-Phase Atomic Hydrogen by Si(100): A Narrow Temperature Window

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