Your search keyword '"Song HC"' showing total 4 results

1. Isotope- and Thickness-Dependent Friction of Water Layers Intercalated Between Graphene and Mica

Author

Lee, H, Lee, H, Ko, JH, Song, HC, Salmeron, M, Kim, YH, Park, JY, Lee, H, Lee, H, Ko, JH, Song, HC, Salmeron, M, Kim, YH, and Park, JY

Abstract

The lubricating properties of water have been discussed extensively for millennia. Water films can exhibit wearless high friction in the form of cold ice, or act as lubricants in skating and skiing when a liquid. At the fundamental level, friction is the result of a balance between the rate of energy generation by phonon excitation during sliding and drainage of the energy from the interface by coupling with bulk atoms. Using atomic force microscopy, we found that when H2O intercalates between graphene and mica, it increases the friction between the tip and the substrate, dependent on the thickness of the water and graphene layers, while the magnitude of the increase in friction was reduced by D2O intercalation. With the help of first-principles density functional theory calculations, we explain this unexpected behavior by the increased spectral range of the vibration modes of graphene caused by water, and by better overlap of the graphene vibration modes with mica phonons, which favors more efficient energy dissipation. The larger increase in friction with H2O versus D2O shows that the high-frequency vibration modes of the water molecules play a very important role in the transfer of the vibrational energy of the graphene to the phonon bath of the substrate.

Published

2018

2. Isotope- and Thickness-Dependent Friction of Water Layers Intercalated Between Graphene and Mica

Author

Lee, H, Lee, H, Ko, JH, Song, HC, Salmeron, M, Kim, YH, Park, JY, Lee, H, Lee, H, Ko, JH, Song, HC, Salmeron, M, Kim, YH, and Park, JY

Abstract

The lubricating properties of water have been discussed extensively for millennia. Water films can exhibit wearless high friction in the form of cold ice, or act as lubricants in skating and skiing when a liquid. At the fundamental level, friction is the result of a balance between the rate of energy generation by phonon excitation during sliding and drainage of the energy from the interface by coupling with bulk atoms. Using atomic force microscopy, we found that when H2O intercalates between graphene and mica, it increases the friction between the tip and the substrate, dependent on the thickness of the water and graphene layers, while the magnitude of the increase in friction was reduced by D2O intercalation. With the help of first-principles density functional theory calculations, we explain this unexpected behavior by the increased spectral range of the vibration modes of graphene caused by water, and by better overlap of the graphene vibration modes with mica phonons, which favors more efficient energy dissipation. The larger increase in friction with H2O versus D2O shows that the high-frequency vibration modes of the water molecules play a very important role in the transfer of the vibrational energy of the graphene to the phonon bath of the substrate.

Published

2018

3. Physics perspectives of heavy-ion collisions at very high energy

Author

Chang, NB, Chang, NB, Cao, SS, Chen, BY, Chen, SY, Chen, ZY, Ding, HT, He, M, Liu, ZQ, Pang, LG, Qin, GY, Rapp, R, Schenke, B, Shen, C, Song, HC, Xu, HJ, Wang, Q, Wang, XN, Zhang, BW, Zhang, HZ, Zhu, XR, Zhuang, PF, Chang, NB, Chang, NB, Cao, SS, Chen, BY, Chen, SY, Chen, ZY, Ding, HT, He, M, Liu, ZQ, Pang, LG, Qin, GY, Rapp, R, Schenke, B, Shen, C, Song, HC, Xu, HJ, Wang, Q, Wang, XN, Zhang, BW, Zhang, HZ, Zhu, XR, and Zhuang, PF

Abstract

Heavy-ion collisions at very high colliding energies are expected to produce a quark-gluon plasma (QGP) at the highest temperature obtainable in a laboratory setting. Experimental studies of these reactions can provide an unprecedented range of information on properties of the QGP at high temperatures. We report theoretical investigations of the physics perspectives of heavy-ion collisions at a future high-energy collider. These include initial parton production, collective expansion of the dense medium, jet quenching, heavy-quark transport, dissociation and regeneration of quarkonia, photon and dilepton production. We illustrate the potential of future experimental studies of the initial particle production and formation of QGP at the highest temperature to provide constraints on properties of strongly interaction matter.

Published

2016

4. Physics perspectives of heavy-ion collisions at very high energy

Author

Chang, NB, Chang, NB, Cao, SS, Chen, BY, Chen, SY, Chen, ZY, Ding, HT, He, M, Liu, ZQ, Pang, LG, Qin, GY, Rapp, R, Schenke, B, Shen, C, Song, HC, Xu, HJ, Wang, Q, Wang, XN, Zhang, BW, Zhang, HZ, Zhu, XR, Zhuang, PF, Chang, NB, Chang, NB, Cao, SS, Chen, BY, Chen, SY, Chen, ZY, Ding, HT, He, M, Liu, ZQ, Pang, LG, Qin, GY, Rapp, R, Schenke, B, Shen, C, Song, HC, Xu, HJ, Wang, Q, Wang, XN, Zhang, BW, Zhang, HZ, Zhu, XR, and Zhuang, PF

Abstract

Heavy-ion collisions at very high colliding energies are expected to produce a quark-gluon plasma (QGP) at the highest temperature obtainable in a laboratory setting. Experimental studies of these reactions can provide an unprecedented range of information on properties of the QGP at high temperatures. We report theoretical investigations of the physics perspectives of heavy-ion collisions at a future high-energy collider. These include initial parton production, collective expansion of the dense medium, jet quenching, heavy-quark transport, dissociation and regeneration of quarkonia, photon and dilepton production. We illustrate the potential of future experimental studies of the initial particle production and formation of QGP at the highest temperature to provide constraints on properties of strongly interaction matter.

Published

2016