Mass producible, robust SERS substrates based on metal film on nanosphere (MFON) on an adhesive substrate for detection of surface-adsorbed molecules and their evaluation by helium ion microscopy
Takei H, Saito N, Okamoto T, Watanabe K, Westphal M, Tomioka R, Gölzhäuser A (2023)
Analyst.
Zeitschriftenaufsatz
| E-Veröff. vor dem Druck | Englisch
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Autor*in
Takei, H.;
Saito, N.;
Okamoto, T.;
Watanabe, K.;
Westphal, M.;
Tomioka, R.;
Gölzhäuser, ArminUniBi
Abstract / Bemerkung
We have developed a SERS stamp that can be pressed directly onto a solid surface for characterization of surface-adsorbed target molecules. The stamp was fabricated by transfer of a dense monolayer of SiO2 nanospheres from a glass surface onto a piece of adhesive tape and subsequent evaporation of silver. The performance of the resulting SERS stamps was evaluated by their exposure to methyl mercaptan vapor, and immersion in rhodamine 6G and ferbam solutions. It was found that beside the nanosphere diameter and metal deposition thickness, the extent of burial of the nanospheres into the adhesive tape, dictated by the pressure during the nanosphere transfer process, had a significant effect. We carried out FDTD calculations of the near field. Models are based on morphological information obtained from helium ion microscopy, which can provide high-resolution images of poor electrical conductors such as our SERS stamp. While one of our main eventual goals is detection of pesticides on agricultural produce, we have begun to take a careful step by testing our SERS stamp on better characterized surfaces such as a porous gel surface, having been immersed in fungicides such as ferbam. We also present our preliminary results with ferbam on oranges. It is expected that our well-characterized SERS stamp will play a role in shedding light on the poorly studied transfer process of target molecules onto a SERS surface as well as serving as a new SERS platform.
Erscheinungsjahr
2023
Zeitschriftentitel
Analyst
ISSN
0003-2654
eISSN
1364-5528
Page URI
https://pub.uni-bielefeld.de/record/2979723
Zitieren
Takei H, Saito N, Okamoto T, et al. Mass producible, robust SERS substrates based on metal film on nanosphere (MFON) on an adhesive substrate for detection of surface-adsorbed molecules and their evaluation by helium ion microscopy. Analyst. 2023.
Takei, H., Saito, N., Okamoto, T., Watanabe, K., Westphal, M., Tomioka, R., & Gölzhäuser, A. (2023). Mass producible, robust SERS substrates based on metal film on nanosphere (MFON) on an adhesive substrate for detection of surface-adsorbed molecules and their evaluation by helium ion microscopy. Analyst. https://doi.org/10.1039/d3an00272a
Takei, H., Saito, N., Okamoto, T., Watanabe, K., Westphal, M., Tomioka, R., and Gölzhäuser, Armin. 2023. “Mass producible, robust SERS substrates based on metal film on nanosphere (MFON) on an adhesive substrate for detection of surface-adsorbed molecules and their evaluation by helium ion microscopy”. Analyst.
Takei, H., Saito, N., Okamoto, T., Watanabe, K., Westphal, M., Tomioka, R., and Gölzhäuser, A. (2023). Mass producible, robust SERS substrates based on metal film on nanosphere (MFON) on an adhesive substrate for detection of surface-adsorbed molecules and their evaluation by helium ion microscopy. Analyst.
Takei, H., et al., 2023. Mass producible, robust SERS substrates based on metal film on nanosphere (MFON) on an adhesive substrate for detection of surface-adsorbed molecules and their evaluation by helium ion microscopy. Analyst.
H. Takei, et al., “Mass producible, robust SERS substrates based on metal film on nanosphere (MFON) on an adhesive substrate for detection of surface-adsorbed molecules and their evaluation by helium ion microscopy”, Analyst, 2023.
Takei, H., Saito, N., Okamoto, T., Watanabe, K., Westphal, M., Tomioka, R., Gölzhäuser, A.: Mass producible, robust SERS substrates based on metal film on nanosphere (MFON) on an adhesive substrate for detection of surface-adsorbed molecules and their evaluation by helium ion microscopy. Analyst. (2023).
Takei, H., Saito, N., Okamoto, T., Watanabe, K., Westphal, M., Tomioka, R., and Gölzhäuser, Armin. “Mass producible, robust SERS substrates based on metal film on nanosphere (MFON) on an adhesive substrate for detection of surface-adsorbed molecules and their evaluation by helium ion microscopy”. Analyst (2023).
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