Deciphering the Metal-C<sub>60</sub> Interface in Optoelectronic Devices: Evidence for C<sub>60</sub> Reduction by Vapor Deposited Al

Matz, Dallas L.; Ratcliff, Erin L.; Meyer, Jens; Kahn, Antoine; Pemberton, Jeanne E.

doi:10.1021/am400640x

Cited by 22 publications

(30 citation statements)

References 81 publications

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“…Although, the excitation wavelength dependence is a major factor affecting the enhancement, as demonstrated by Ye et al [25] and by Alvarez-Puebla, [26] greater understanding can be gained by combining the excitation wavelength dependence with an investigation of the SERS substrate morphology. In our study, we thermally evaporating tapered thin films of Au using a shadow mask that causes a shadowing effect across the Au film's borders and generates a range of Au nanostructure morphologies at this region, as similarly published by Oates et al [27] Fullerene C 60 is a molecule with closed-cage structure that has been widely studied and used in technological applications such as biological sensing, [28] drug delivery, [28] organic light emitting diodes, [29] organic photovoltaics, [30,31] and organic field effect transistors. [32,33] We chose Fullerene C 60 as our SERS probe molecule because it is a highly symmetric molecule that produces uniform films via thermal evaporation, it is optically stable, and it does not have strong fluorescence that would have limited our excitation range.…”

Section: Introductionmentioning

confidence: 96%

“…Fullerene C 60 is a molecule with closed‐cage structure that has been widely studied and used in technological applications such as biological sensing, drug delivery, organic light emitting diodes, organic photovoltaics, and organic field effect transistors . We chose Fullerene C 60 as our SERS probe molecule because it is a highly symmetric molecule that produces uniform films via thermal evaporation, it is optically stable, and it does not have strong fluorescence that would have limited our excitation range.…”

Section: Introductionmentioning

confidence: 99%

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The effect of excitation wavelength and metallic nanostructure on SERS spectra of C₆₀

Sinwani

Muallem

Tischler

2017

J Raman Spectroscopy

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Understanding the mechanisms of surface‐enhanced Raman scattering (SERS) phenomena is essential for advancing next‐generation Raman‐based chemical and biological sensors. SERS studies typically examine the excitation wavelength dependence for a given nanostructure morphology. However, more comprehension of the SERS mechanisms can be gained by investigating the combined excitation wavelength and metal morphology dependencies. Here, using a thin Au film with tapered boundaries as the Raman enhancing surface, we investigate the SERS mechanisms exhibited along the sloped region of the sample. The tapered boundaries provide controllably different Au morphologies from densified thin film to nano‐island to nanoparticle structures. A layer of Fullerene C60 was thermally evaporated uniformly across the Au film. The excitation wavelength of 532 nm generated similar SERS spectra across the Au surface, which closely matched the regular Raman scattering spectrum, thus indicating enhancement of the normal Raman modes of C60. In contrast, an excitation wavelength of 784 nm generated different SERS spectra across the boundary whose intensity from the tapered Au film surface was 10 times higher than the SERS signal from the Au thin film region. The spectral differences observed with 784‐nm excitation are indicative of an electromagnetic mechanism controlled by near field interactions of local surface plasmon resonances. Using the configuration of tapered Au films can enable fast determination of the most enhancing Au nanostructure for a given laser excitation and provide an in‐depth insight into the enhancement mechanisms associated with a particular analyte molecule, as shown here for C60. Copyright © 2017 John Wiley & Sons, Ltd.

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Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

The effect of excitation wavelength and metallic nanostructure on SERS spectra of C₆₀

Sinwani

Muallem

Tischler

2017

J Raman Spectroscopy

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“…The literature on C 60 films growth on metal substrates is abundant [8,[13][14][15][16][17][18][19][20][21][22][23][24]. Particularly on Cu(111) substrates, STM experiments combined with theoretical calculations of bands structure [16], and photoemission [19] were used to demonstrate that electron transfer from the Cu(111) substrate to C 60 varies between 1 and 2 electrons per molecule.…”

Section: Introductionmentioning

confidence: 99%

Growth, thermal desorption and low dose ion bombardment damage of C₆₀ films deposited on Cu(111)

et al. 2017

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Auger electron spectroscopy (AES), low energy electron diffraction (LEED) and reflection electron energy loss spectrometry (REELS) were used to characterize the growth and thermal stability of C 60 films deposited on Cu(111). By means of LEED we found that while C 60 grows in an ordered fashion up to the first monolayer (ML) at room temperature (RT), it turns amorphous beyond that point. On the other hand, when the substrate temperature is kept at 450 K, films up to two ML with crystalline structure are obtained. For substrate temperatures beyond 570 K thick films (more than 1 ML) do not grow at all. By using AES, we found that a thick C 60 film starts to desorb at a temperature around 470 K but the first ML remains stable up to temperatures as high as 900 K. A ML with a better crystalline order is obtained after desorption than that growth with the substrate at RT or higher temperatures. When the substrate is heated at 970 K, the first ML is not fully removed but the C 60 molecular structure is altered or molecules break up into smaller pieces. The ion induced damage on C 60 on Cu(111) films was studied for typical ions, incoming energies and irradiation doses used in low energy ion scattering (LEIS) experiments. The D-value of C(KLL) Auger spectra, the π-plasmon of REELS and the evolution of the LEIS spectra, were monitored to characterize the damage caused to the film. We found that, at low doses (∼10 14 ions cm −2 ), damage is only detectable for massive ions like Ar, but not for H and He in the 2-8 keV range.

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“…2 In the direct architecture, the top metal contact should attain a low work function for electron extraction, and hence, aluminum and calcium are the common preferences (F = 4.11 eV and 2.8 eV respectively). 3,4 However, their low work function inherently imposes low environmental stability due to oxidation when exposed to ambient conditions 5,6 and interaction with the underlying organic film. 7 Indeed, the limited lifetime associated with direct architecture devices is often attributed to the oxidation of the metal electrode and not necessarily the degradation of the organic materials.…”

Section: Introductionmentioning

confidence: 99%

Spontaneous generation of interlayers in OPVs with silver cathodes: enhancing V_oc and lifetime

2016

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Deciphering the Metal-C₆₀ Interface in Optoelectronic Devices: Evidence for C₆₀ Reduction by Vapor Deposited Al

Cited by 22 publications

References 81 publications

The effect of excitation wavelength and metallic nanostructure on SERS spectra of C₆₀

The effect of excitation wavelength and metallic nanostructure on SERS spectra of C₆₀

Growth, thermal desorption and low dose ion bombardment damage of C₆₀ films deposited on Cu(111)

Spontaneous generation of interlayers in OPVs with silver cathodes: enhancing V_oc and lifetime

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Deciphering the Metal-C60 Interface in Optoelectronic Devices: Evidence for C60 Reduction by Vapor Deposited Al

Cited by 22 publications

References 81 publications

The effect of excitation wavelength and metallic nanostructure on SERS spectra of C60

The effect of excitation wavelength and metallic nanostructure on SERS spectra of C60

Growth, thermal desorption and low dose ion bombardment damage of C60 films deposited on Cu(111)

Spontaneous generation of interlayers in OPVs with silver cathodes: enhancing Voc and lifetime

Contact Info

Product

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Deciphering the Metal-C₆₀ Interface in Optoelectronic Devices: Evidence for C₆₀ Reduction by Vapor Deposited Al

The effect of excitation wavelength and metallic nanostructure on SERS spectra of C₆₀

The effect of excitation wavelength and metallic nanostructure on SERS spectra of C₆₀

Growth, thermal desorption and low dose ion bombardment damage of C₆₀ films deposited on Cu(111)

Spontaneous generation of interlayers in OPVs with silver cathodes: enhancing V_oc and lifetime