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A field emission study of silver on rhenium
A8 220
Surface Science 124 (1983) 220-240 North-Holland Publishing Company
A FIELD EMISSION O.Z. AL-RAWI
STUDY
OF SILVER
ON RHENIUM
* and J.P. JONES
School of Electronic Engineering Science, University College of North Wales, Dean Street, Bangor. G~ynedd LL57 7UT, Wales, UK Received 6 May 1982; accepted for publication 23 September 1982 Field emission measurements of the change in average work function ~ of rhenium with adsorbed silver indicate that a rhenium-silver dipole forms with silver positive, of moment tt0 = 5.2_+ 1.5× 10 -3o C m and polarizability a = 29_+ 12 ,~3. Measurement of the rate of thermal desorption yields a mean binding energy of 2.31 _+0.04 eV for sub-monolayer silver and 2.69 _+0.04 eV for a 2.5 monolayer deposit. Changes in work function induced by adsorption of silver on low-index rhenium plane surfaces are characterised by the formation of welt-defined states and in this, silver resembles gold. These states are thought to result from a relatively large difference between the binding energy of adatoms on the low-index planes and on the surrounding surfaces, and this differnce is maintained when the surfaces are covered with silver. At the lowest coverage. silver is believed to be absent from all four observed planes and the measured rise in work function is thought to be apparent and to result from a decrease in field strength on the plane due to extension of the plane area by surrounding adsorbed silver. The structures adopted by silver overlayers are not known, but it is argued_that on (1010) and (1011) the final state at high coverage has the Ag(111) surface structure. On (1120) and (1122) the silver layer at high coverage is thought to have either Ag(110) or Ag(100) surface structure. The structures of intermediate states found on all four low-index planes remain unkown. Field emission spectroscopy shows that emission from clean (1010) is free-electron like and confirms earlier observations that emission from (2021) is not. Spectroscopy also reveals a feature in the spectrum from silver on (1010) which may be identified with a known surface state on Ag(111), thus providing some support for the assignment of Ag(111) to the surface structure of thick silver layers ( > 3 monolayers) on (1010).
Surface Science 124 (1983) 241 252 North-Holland Publishing Company ON
241
THE SURFACE T E M P E R A T U R E D E P E N D E N C E O F
NON-EQUILIBRIUM
TRANSLATIONAL
ENERGY
ACCOMMODATION
COEFFICIENTS Ann
M. RICHARD
Department of Chemistry, University of North Carolina, Chapel Hill, North Carohna 27514, USA and Andrew
E. D E P R I S T O
*
Department of Chemisto', Iowa State University, Ames, Iowa 50011, USA Received 1 September 1982; accepted for publication 12 October 1982
The formalism of classical scaling theory is applied to the process of translational energy accommodation in the gas-solid surface system. The scaling provides a systematic description of energy transfer as a function of the initial occupation numbers of the solid. This yields a relatively simple equation for the surface temperature variation of the non-equilibrium EAC, a(Tg, 7~,), at
Surface Science 124 (1983) 220-240 North-Holland Publishing Company
A FIELD EMISSION O.Z. AL-RAWI
STUDY
OF SILVER
ON RHENIUM
* and J.P. JONES
School of Electronic Engineering Science, University College of North Wales, Dean Street, Bangor. G~ynedd LL57 7UT, Wales, UK Received 6 May 1982; accepted for publication 23 September 1982 Field emission measurements of the change in average work function ~ of rhenium with adsorbed silver indicate that a rhenium-silver dipole forms with silver positive, of moment tt0 = 5.2_+ 1.5× 10 -3o C m and polarizability a = 29_+ 12 ,~3. Measurement of the rate of thermal desorption yields a mean binding energy of 2.31 _+0.04 eV for sub-monolayer silver and 2.69 _+0.04 eV for a 2.5 monolayer deposit. Changes in work function induced by adsorption of silver on low-index rhenium plane surfaces are characterised by the formation of welt-defined states and in this, silver resembles gold. These states are thought to result from a relatively large difference between the binding energy of adatoms on the low-index planes and on the surrounding surfaces, and this differnce is maintained when the surfaces are covered with silver. At the lowest coverage. silver is believed to be absent from all four observed planes and the measured rise in work function is thought to be apparent and to result from a decrease in field strength on the plane due to extension of the plane area by surrounding adsorbed silver. The structures adopted by silver overlayers are not known, but it is argued_that on (1010) and (1011) the final state at high coverage has the Ag(111) surface structure. On (1120) and (1122) the silver layer at high coverage is thought to have either Ag(110) or Ag(100) surface structure. The structures of intermediate states found on all four low-index planes remain unkown. Field emission spectroscopy shows that emission from clean (1010) is free-electron like and confirms earlier observations that emission from (2021) is not. Spectroscopy also reveals a feature in the spectrum from silver on (1010) which may be identified with a known surface state on Ag(111), thus providing some support for the assignment of Ag(111) to the surface structure of thick silver layers ( > 3 monolayers) on (1010).
Surface Science 124 (1983) 241 252 North-Holland Publishing Company ON
241
THE SURFACE T E M P E R A T U R E D E P E N D E N C E O F
NON-EQUILIBRIUM
TRANSLATIONAL
ENERGY
ACCOMMODATION
COEFFICIENTS Ann
M. RICHARD
Department of Chemistry, University of North Carolina, Chapel Hill, North Carohna 27514, USA and Andrew
E. D E P R I S T O
*
Department of Chemisto', Iowa State University, Ames, Iowa 50011, USA Received 1 September 1982; accepted for publication 12 October 1982
The formalism of classical scaling theory is applied to the process of translational energy accommodation in the gas-solid surface system. The scaling provides a systematic description of energy transfer as a function of the initial occupation numbers of the solid. This yields a relatively simple equation for the surface temperature variation of the non-equilibrium EAC, a(Tg, 7~,), at