Molecular Orientation and Energy Transfer Dynamics of a Metal Oxide Bound Self-Assembled Trilayer

Pattadar, Dhruba K.; Arcidiacono, Ashley; Beery, Drake; Hanson, Kenneth; Saavedra, S. Scott

doi:10.1021/acs.langmuir.3c01323

Langmuir

2023

DOI: 10.1021/acs.langmuir.3c01323

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Molecular Orientation and Energy Transfer Dynamics of a Metal Oxide Bound Self-Assembled Trilayer

Dhruba K. Pattadar

Ashley Arcidiacono

Drake Beery

et al.

Abstract: Self-assembly of molecular multilayers via metal ion linkages has become an important strategy for interfacial engineering of metalloid and metal oxide (MO x ) substrates, with applications in numerous areas, including energy harvesting, catalysis, and chemical sensing. An important aspect for the rational design of these multilayers is knowledge of the molecular structure–function relationships. For example, in a multilayer composed of different chromophores in each layer, the molecular orientation of each la… Show more

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2024

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Cited by 2 publications

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Differentiating Intra-Assembly and Interlayer Energy Transfer in Metal-Ion-Linked Molecular Multilayers

McLeod,

Nolder,

Arcidiacono

et al. 2024

J. Phys. Chem. C

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Metal-ion-linked molecular multilayers on metal oxide surfaces are promising for applications ranging from solar energy conversion to sensing. Most of these applications rely on energy and electron transfer between layers/molecules which can be envisioned to occur via intra-assembly (IA; between metal-ion-linked molecules) and interlayer (IL; between separate layers of nonlinked molecules) processes. Here, we describe our effort to differentiate between IL and IA energy transfer using a bilayer composed of ZrO 2 , a phosphonated anthracene derivative (A), a zinc(II) linking ion, and a Pt(II)porphyrin (P). Both time-resolved emission and transient absorption measurements show no impact of diluting the anthracene layer with a spectroscopically inert spacer on the rate of 1 A* to P and 3 P* to A, singlet, and triplet energy transfer, respectively. These results indicate that energy transfer within the metal-ion-linked assembly (i.e., ZrO 2 -A−Zn-P) is more rapid than with an adjacent, nonlinked A molecule, even for a P derivative capable of laying down on the surface. These insights are an important step toward structural design principles maximizing the efficiency/rate of energy transfer in multilayer assemblies.

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Differentiating Intra-Assembly and Interlayer Energy Transfer in Metal-Ion-Linked Molecular Multilayers

McLeod,

Nolder,

Arcidiacono

et al. 2024

J. Phys. Chem. C

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Structural insights to metal ion linked multilayers on metal oxide surfaces via energy transfer and polarized ATR measurements

Arcidiacono,

Ruchlin,

McLeod

et al. 2024

J. Mater. Chem. A

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Molecular Orientation and Energy Transfer Dynamics of a Metal Oxide Bound Self-Assembled Trilayer

Cited by 2 publications

References 76 publications

Differentiating Intra-Assembly and Interlayer Energy Transfer in Metal-Ion-Linked Molecular Multilayers

Differentiating Intra-Assembly and Interlayer Energy Transfer in Metal-Ion-Linked Molecular Multilayers

Structural insights to metal ion linked multilayers on metal oxide surfaces via energy transfer and polarized ATR measurements

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