Realization of well-controlled hybrid interfaces between solid surfaces and functional complex molecules can be hampered by the presence of contaminants originated by the fragmentation of fragile architectures based on the coordinative bond. Here, we present a morphological and spectroscopic analysis of submonolayer films obtained by sublimation of the [Fe4(L)2(dpm)6] (Fe4) single molecule magnet on different substrates. Though intact tetranuclear molecules can be transferred to surfaces, smaller molecular species are often codeposited. By comparison of substrates characterized by different reactivities, such as Au(111), Cu(100), and Cu2N, and employing a protocol of indirect exposure of the substrate, we infer that the observed fragments do not originate from the reaction of Fe4 molecules with the surface but rather are produced during Fe4 sublimation, which releases Fe(dpm)3 as a very volatile compound. Fe(dpm)3 undergoes substrate-dependent on-surface decomposition to final products that have been identified by combined STM, UPS, XPS, and DFT studies.
The Challenge of Thermal Deposition of Coordination Compounds: Insight into the Case of an Fe4 Single Molecule Magnet / Lanzilotto, Valeria; Malavolti, Luigi; Ninova, Silviya; Cimatti, Irene; Poggini, Lorenzo; Cortigiani, Brunetto; Mannini, Matteo; Totti, Federico; Cornia, Andrea; Sessoli, Roberta. - In: CHEMISTRY OF MATERIALS. - ISSN 0897-4756. - 28:21(2016), pp. 7693-7702. [10.1021/acs.chemmater.6b02696]
The Challenge of Thermal Deposition of Coordination Compounds: Insight into the Case of an Fe4 Single Molecule Magnet
CORNIA, Andrea;
2016
Abstract
Realization of well-controlled hybrid interfaces between solid surfaces and functional complex molecules can be hampered by the presence of contaminants originated by the fragmentation of fragile architectures based on the coordinative bond. Here, we present a morphological and spectroscopic analysis of submonolayer films obtained by sublimation of the [Fe4(L)2(dpm)6] (Fe4) single molecule magnet on different substrates. Though intact tetranuclear molecules can be transferred to surfaces, smaller molecular species are often codeposited. By comparison of substrates characterized by different reactivities, such as Au(111), Cu(100), and Cu2N, and employing a protocol of indirect exposure of the substrate, we infer that the observed fragments do not originate from the reaction of Fe4 molecules with the surface but rather are produced during Fe4 sublimation, which releases Fe(dpm)3 as a very volatile compound. Fe(dpm)3 undergoes substrate-dependent on-surface decomposition to final products that have been identified by combined STM, UPS, XPS, and DFT studies.Pubblicazioni consigliate
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