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An STM investigation of the interaction and ordering of pentacene molecules on the Ag/Si(111)-(√3x√3)R30° surface Ph. Guaino et. al (NCSR), Dublin City.

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Presentation on theme: "An STM investigation of the interaction and ordering of pentacene molecules on the Ag/Si(111)-(√3x√3)R30° surface Ph. Guaino et. al (NCSR), Dublin City."— Presentation transcript:

1 An STM investigation of the interaction and ordering of pentacene molecules on the Ag/Si(111)-(√3x√3)R30° surface Ph. Guaino et. al (NCSR), Dublin City University 24 May 2003 Surface Science Lee Min Hee (Ph.D Course 2)

2 FIG. 1.(a) Molecular structure and (b) and (c) Herringbone crystalline structure of pentacene. (d) Typical OTFT geometry (top contact). The structure of pentacene(C 22 H 14 )

3 Purpose Studying the ordering of pentacene (C 22 H 14 ) molecules on the Ag/Si(111)-(√3x√3)R30° surface at RT. The role of competition between intermolecular and molecule-substrate interactions and the nature of the adsorption sites is discussed.

4  A new generation of devices based on organic semiconductors  Investigation of the interactions of pentacene molecules on surfaces: molecule-substrate interactions on semiconductor surface. chemisorbtion and none-diffusion at RT. molecule-molecule interactions on the metallic surfaces weaker Van der Waals type interactions. Introduction

5 Pre-researches C 22 H 14 /Cu(110)  A long range ordering of the unidirectional close packed side-by-side configuration molecular rows.  The formation of standing waves (Friedel oscillations) in the surface-state free- electron gas.

6 Ag/Si(111)-(√3x√3)R30° substrate.  C 60 molecules are found to bond preferentially at defect sites and step edges and molecular domains are formed which are ordered in a double domain configuration.  Cobalt-phthalocyanine (CoPc) molecules form a close packed arrangement at a coverage close to a monolayer.

7 STM(Omicron Vakumphysik GmbH). RT. pressure of 5 x10 -11 mbar. Si(111) substrate. p-type boron-doped with 0.1~1.0 Ωcm. current heating to 1250 ℃ after degassing (600 ℃ for 10 h). Silver 5N (Goodfellow Metals) evaporated onto the Si substrate at 500 ℃ Pentacene (Aldrich Chemicals) degassing( 12 h) to remove water vapor. evaporated at a rate of about 1 ML/min at 180 ℃. Experimental details

8 Results and discussion The honeycomb-chained-trimer (HCT) model Ag trimer Size =5x5 nm 2, V sample = 1.0 V, I t =2.0 nA Si trimer Unit average length : 6.8 ±0.5Ǻ Hexagonal structure in the STM empty state image Ag/Si(111)-(√3x√3)R30°

9 Fig 2. STM image of S1 phase. ~0.35ML Pentacene. Packing Density = 3.4x10 -3 molǺ -2 Size= 40 x 40 nm 2, V sample =1:5V, I t = 100 pA. Parallel shifts of the molecular rows Perpendicular shifts of the molecular rows Small ordered region The symmetry Orientation (√3x√3)R30° Honeycomb geometry 120° Molecule-Substrate interaction. Molecular row 7.9±1.0Ǻ 18.4±2.0Ǻ 15.8±2.0Ǻ Head to Head orientation

10 Results and discussion Fig. 3. STM image of Ag/Si-√3 coverage after pentacene deposition of 0.2 ML. Image parameters: size =120 x120 nm 2, V sample =1.0 V, I t =100 pA. short parallel rows of pentacene molecules. A shadowing of the sample by the sample holder during deposition.

11 Histogram of the statistical distribution of the inter-rows spacings. d 1 =16.2±2 Ǻ(2.5 x unit cell length) d 2 =33.5±2 Ǻ(5 x unit cell length) d 3 =44.1±2 Ǻ (6.5 x unit cell length) The adsorbed layer is in registry with the structure of the substrate. Fig. 4.

12 High resolution image of Ag/Si-√3 coverage after pentacene deposition of 0.2 ML. Molecule row Honeycomb structure of the substrate Perpendicular shifts of the molecular rows 40nm V sample=+1.0 V, It=100 pA. Fig. 5.

13 Molecular row align direction 15.8±2 Ǻ 18.4±2 Ǻ 20.0±2 Ǻ 113°±3° 6-fold hollow site(CB-site) 3-fold hollow site(CA-site) The high-order (25 X 25) commensurate cell containing 75 molecules. Proposed model of the Ag/Si(111)-(25X25)-pentacene structure, S1 phase.  Pentacene molecules On the Ag/Si-√3 surface no preferentially decorating the steps no alignment occurs along step edges  The S1 phase growth of the film is governed by molecule-substrate interactions and molecule-molecule interactions.  Adsorption takes place (CA-site) and (CB- site). Fig. 6.

14 STM image of solid phase S 2 Major axis 6.5±0.5Ǻ inter row distance AB=15.6±2Ǻ molecular pair CD=20.85±2Ǻ neighbouring pair D = (9.6± 0.2)x 10 -3 mol Ǻ -2. V sample =1.1 V, I t =200 pA. Fig. 7. STM image of solid phase S 2 formed after deposition of 1 ML of pentacene. Close-packed side-by-side arrangement domains 21.5nm

15 STM images of solid phase S 2 recorded in dual scan mode. 7.8 nm high bias in forward scan direction V sample =-1.9 V, I t =50 pA. low bias in the backward scan direction V sample =+0.3 V, I t =190 pA. Resonant tunneling through the energy levels of the molecule. Tunneling occurs within the HOMO-LUMO gap Charge transfer between Ag/Si(111)-(√3x√3)R30° surface and the π electron of the pentacene Fig. 8.

16 Proposed model of the Ag/Si(111)-(2x3)-pentacene structure, S 2 phase. 19.5 Ǻ 15.6 Ǻ 118±2° Unit Cell Inter-row separation correspond to Van der Waals interaction radius of 6.5Ǻ. An attractive force between the molecules leading to a lateral rearrangement Relatively large quadrupole moment may provide a significant portion of the lateral molecule-molecule interaction Fig. 9.

17 Crystallographic data for pentacene superstructures on the Ag/Si-√3 substrate High ~x3

18 Conclusion  The formation of well-ordered pentacene layers on the Ag/Si-√3 substrate depends not only on competition between intermolecular and molecule-substrate interactions but also on the nature of the adsorption site.  For the S 1 phase, adsorption takes place a three-fold hollow site at the centre of a Ag-trimer (CA-site) and a six-fold hollow site at the centre of the hexagonal arrangement of silver atoms (CB-site).  No adsorption takes place on six-fold hollow site (CB-site) for the S 2 phase, in which the short- range interactions are stronger. Adsorption takes place exclusively on the Ag-trimer (CA) site  The strength of the molecule-substrate interaction at the Ag trimer sites (CA-site) is sufficient to produces a new commensurate structure, even in the presence of short-range lateral interactions.

19 Abstract S1 solid phase : coverage of 0.35 ML pentacene A high-order commensurate lattice, Ag/Si(111)-(25x25)-pentacene, containing 75 molecules per unit cell. Adsorption takes place a three-fold hollow site at the centre of a Ag-trimer (CA-site) and a six-fold hollow site at the centre of the hexagonal arrangement of silver atoms (CB-site). S2 solid phase : coverage of 1.0 ML pentacene A molecular reorganization and a new commensurate structure Ag/Si(111)-(2x3)- pentacene,containing two molecules per unit cell. Adsorption takes place exclusively on the Ag-trimer (CA) site and the CB-site is lost because of strong lateral molecule-molecule interactions.

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