Spectroscopic Fingerprints of Work-Function-Controlled Phthalocyanine Charging on Metal Surfaces

Borghetti, Patrizia; El-Sayed, Afaf; Goiri, E.; Rogero, Celia; Lobo-Checa, Jorge; Floreano, Luca; Ortega, J. E.; Oteyza, Dimas G. de

doi:10.1021/nn5060333

Cited by 37 publications

(65 citation statements)

References 49 publications

(128 reference statements)

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“…5 These interesting properties of MPcs have spurred significant interest in the adsorption of metal phthalocyanines on single crystal surfaces of materials such as copper, silver, and aluminium. [6][7][8][9] Surface-driven modification of the molecular properties plays an important role, and recent research into phthalocyanine compounds includes the control of the Kondo effect, 10 switching of magnetic anisotropy, 11 and uneven charge transfer leading to distortion and symmetry reduction. 12 The preparation of MPc monolayers (ML) on metal surfaces by thermal evaporation onto the room temperature surface is often tedious since it is difficult to determine the exact amount of deposited material.…”

Section: Introductionmentioning

confidence: 99%

Iron phthalocyanine on Cu(111): Coverage-dependent assembly and symmetry breaking, temperature-induced homocoupling, and modification of the adsorbate-surface interaction by annealing

Snezhkova

Bischoff

et al. 2016

The Journal of Chemical Physics

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We have examined the geometric and electronic structures of iron phthalocyanine assemblies on a Cu(111) surface at different sub- to mono-layer coverages and the changes induced by thermal annealing at temperatures between 250 and 320 °C by scanning tunneling microscopy, x-ray photoelectron spectroscopy, and x-ray absorption spectroscopy. The symmetry breaking observed in scanning tunneling microscopy images is found to be coverage dependent and to persist upon annealing. Further, we find that annealing to temperatures between 300 and 320 °C leads to both desorption of iron phthalocyanine molecules from the surface and their agglomeration. We see clear evidence of temperature-induced homocoupling reactions of the iron phthalocyanine molecules following dehydrogenation of their isoindole rings, similar to what has been observed for related tetrapyrroles on transition metal surfaces. Finally, spectroscopy indicates a modified substrate-adsorbate interaction upon annealing with a shortened bond distance. This finding could potentially explain a changed reactivity of Cu-supported iron phthalocyanine in comparison to that of the pristine compound.

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Section: Introductionmentioning

confidence: 99%

Iron phthalocyanine on Cu(111): Coverage-dependent assembly and symmetry breaking, temperature-induced homocoupling, and modification of the adsorbate-surface interaction by annealing

Snezhkova

Bischoff

et al. 2016

The Journal of Chemical Physics

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“…Borghetti et al . reported that a CuPc layer on Ag(111) is charged negatively, while that on Au(111) remains neutral 38 . Although the charge state of the molecules and their stability strongly depend on the energy alignment and atomic scale details at the junction, three charge states of CuPc, i .…”

Section: Resultsmentioning

confidence: 99%

Molecular floating-gate single-electron transistor

Yamamoto

Azuma

Sakamoto

et al. 2017

Sci Rep

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We investigated reversible switching behaviors of a molecular floating-gate single-electron transistor (MFG-SET). The device consists of a gold nanoparticle-based SET and a few tetra-tert-butyl copper phthalocyanine (ttbCuPc) molecules; each nanoparticle (NP) functions as a Coulomb island. The ttbCuPc molecules function as photoreactive floating gates, which reversibly change the potential of the Coulomb island depending on the charge states induced in the ttbCuPc molecules by light irradiation or by externally applied voltages. We found that single-electron charging of ttbCuPc leads to a potential shift in the Coulomb island by more than half of its charging energy. The first induced device state was sufficiently stable; the retention time was more than a few hours without application of an external voltage. Moreover, the device exhibited an additional state when irradiated with 700 nm light, corresponding to doubly charged ttbCuPc. The life time of this additional state was several seconds, which is much shorter than that of the first induced state. These results clearly demonstrate an alternative method utilizing the unique functionality of the single molecule in nanoelectronics devices, and the potential application of MFG-SETs for investigating molecular charging phenomena.Organic molecules are ideal candidates for bottom-up electronics components because of their atomically controlled structures and functionalities [1][2][3][4] . The charge, spin, and thermal transport characteristics of individual single molecules in a molecular junction (metal-molecule-metal) have been investigated via scanning probe microscopes [5][6][7][8][9] , mechanically controllable break junctions 10,11 , and nanogap electrodes 12,13 . Although these previous studies revealed the transport mechanisms of single molecules in molecular junctions, the fabrication of single-molecular devices is still challenging. One of the main difficulties in this field is the formation of molecular junctions in solid-state device structures. Moreover, the charge states of single molecules have not been sufficiently studied for charge transport through single molecules, even though understanding them would provide significant benefits for single-molecular devices 14,15 . Chemically synthesized metal or semiconductor NPs have also attracted much attention because of their potential applications in bottom-up electronics [16][17][18] . AuNPs are ideal materials for the fabrication of Coulomb islands owing to their uniform density of states, and large charging energy. AuNP-based SETs show clear Coulomb diamonds, which can be well-characterized by the orthodox theory [19][20][21][22][23][24][25] . Moreover, flexible logic operations were demonstrated in chemically assembled double-gate AuNP-SETs 26 . Recently, we proposed a new device structure, i.e., molecular floating-gate SETs (MFG-SETs) in which individual molecules function as floating gates [27][28][29][30] . Organic molecules are smaller than typical NPs; thus, several functional molecules can be a...

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“…Borghetti et al have argued that the strong electron-accepting nature of this molecule leads to a notable charge transfer from the metal substrates into the F 16 CuPc LUMO, thus counteracting the omnipresent pushback effect. [49] Corresponding STM data show that the adlayer structures for F 16 CuPc on Au(111) (c.f. Figure 1f and Ag(111) (see Supporting Information) are consistent with structures reported in the literature.…”

Section: Non-polar Phthalocyaninesmentioning

confidence: 99%

“…For higher coverage, ΔΦ for Ag(111) (cf. [36,44,48,49] Theoretical investigations show that partial charge transfer depends sensitively on the position of the former LUMO relative to the Fermi level of the substrate, but precise calculation of the coverage dependence remains challenging. For Au(111), on the other hand, a further reduction of 150 meV is observed after completion of the first ML.…”

Section: Non-polar Phthalocyaninesmentioning

confidence: 99%

“…[47] Several explanations for these varying behaviors have been considered, ranging from a reduced pushback effect for CuPc/Ag(111) to charge transfer processes between CuPc and the different metal surfaces. [36,44,48,49] Theoretical investigations show that partial charge transfer depends sensitively on the position of the former LUMO relative to the Fermi level of the substrate, but precise calculation of the coverage dependence remains challenging.…”

Section: Non-polar Phthalocyaninesmentioning

confidence: 99%

See 1 more Smart Citation

A Solvent‐Free Solution: Vacuum‐Deposited Organic Monolayers Modify Work Functions of Noble Metal Electrodes

Widdascheck

Hauke

Witte

2019

Adv Funct Materials

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The energy level alignment between organic semiconductors (OSCs) and the respective (metal) electrodes in organic electronic devices is of key importance for efficient charge carrier injection. For many years, researchers have attempted to control this energy level alignment by means of functional self‐assembled monolayers or the insertion of thin injection layers (made, e.g., of doped OCSs or pure dopants). The present work demonstrates an alternative to these approaches, namely the use of phthalocyanine monolayers as contact primers, which are deposited onto noble metal electrodes by means of vacuum deposition. It is shown that polar as well as non‐polar phthalocyanines modify the work functions of clean Au(111) and Ag(111) surfaces as a function of their coverage and thus enable quantitative control of the metal work functions. This behavior is successfully replicated for the respective polycrystalline metal surfaces and it is found that full monolayers can even withstand air exposure when protected by sacrificial multilayers, which are afterward removed by thermal desorption.

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Spectroscopic Fingerprints of Work-Function-Controlled Phthalocyanine Charging on Metal Surfaces

Cited by 37 publications

References 49 publications

Iron phthalocyanine on Cu(111): Coverage-dependent assembly and symmetry breaking, temperature-induced homocoupling, and modification of the adsorbate-surface interaction by annealing

Iron phthalocyanine on Cu(111): Coverage-dependent assembly and symmetry breaking, temperature-induced homocoupling, and modification of the adsorbate-surface interaction by annealing

Molecular floating-gate single-electron transistor

A Solvent‐Free Solution: Vacuum‐Deposited Organic Monolayers Modify Work Functions of Noble Metal Electrodes

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