Synthesis and characterization of a highly strained donor–acceptor nanohoop

Raden, Jeff M. Van; Darzi, Evan R.; Zakharov, Lev N.; Jasti, Ramesh

doi:10.1039/c6ob00133e

Cited by 55 publications

(62 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Whereas for the aza‐[ n ]CPP series of compounds, the HOMO‐LUMO gap increases monotonically from 2.87 to 3.37 eV when going from the aza‐[6]CPP to the aza‐[10]CPP system, as it also happens for the unsubstituted [ n ]CPPs, the gap does not significantly alters (up to 0.1‐0.2 eV) in the other two cases, reflecting the strong localization of both frontier molecular orbitals in spatially separated fragments of the molecule. Thus, the conclusions drawn before about the impact of inserting pyridinium and methylpyridinium units are expected to also approximately hold, independently of the nanoring size, as it was also recently inferred experimentally after comparing aza‐[6]CPP with aza‐[8]CPP and N ‐methylaza‐[6]CPP + with N ‐methylaza‐[8]CPP + . The same trend regarding the evolution of the HOMO‐LUMO gap is also found for the N‐doped linear paraphenylenes, although to a lesser extent due to edge effects: the gap decreases monotonically from 3.98 to 3.81 eV for the aza‐[6]LPP and aza‐[10]LPP cases, and changes up to 0.1‐0.3 eV in the other cases, again reflecting some localization of both frontier molecular orbitals in spatially separated fragments of the charged molecules.…”

Section: Resultssupporting

confidence: 75%

N‐doped cycloparaphenylenes: Tuning electronic properties for applications in thermally activated delayed fluorescence

Graham

Moral²,

Muccioli

et al. 2017

Int J of Quantum Chemistry

View full text Add to dashboard Cite

We theoretically characterize a series of substituted cycloparaphenylene nanohoops to study the effect of incorporating an electron-withdrawing group into their cyclic structure. We systematically vary the nature, position, and number of nitrogen-containing acceptor groups in both neutral (pyridine) and charged forms (pyridinium and methylpyridinium) to provide insights into how this functionalization affects the structural, electronic, and optical properties of these systems. We focus also on the singlet-triplet energy difference, with low values found, which might pave the way to further applications in the field of devices for light-emitting applications providing a potential class of TADF-based emitters. K E Y W O R D S density functional theory, donor-acceptor cycloparaphenylenes, optoelectronic properties, TD-DFT, thermally activated delayed fluorescence | I N TR ODU C TI ONOrganic Electronics is a field of rapid growth attracting interest from interdisciplinary domains including electronics & engineering, chemistry, physics, and materials science, not to mention the great commercial interest toward its applications. [1,2] The facile tunability of organic molecules has paved the way for a wealth of organic-based materials to be synthesized with novel key properties. Already, small organic molecules find their place in photovoltaic cells, [3,4] light-emitting transistors, [5][6][7][8][9] and diodes, [10][11][12] to name just a few of these applications. The flexibility of organic materials over inorganic has enabled the birth of the "soft electronics" market, including devices that can twist, bend or mould to any surface or textile. With so many possibilities arising from unique properties of organic molecules, the future of organics appears bright: not only do organic materials promise more innovative technologies but also are far more sustainable (organic molecules are abundant, easily synthesized and potentially Int J Quantum Chem. 2018;118:e25562.

show abstract

Section: Resultssupporting

confidence: 75%

N‐doped cycloparaphenylenes: Tuning electronic properties for applications in thermally activated delayed fluorescence

Graham

Moral²,

Muccioli

et al. 2017

Int J of Quantum Chemistry

View full text Add to dashboard Cite

show abstract

“…Additionally, as a consequence of breaking molecular orbital symmetry, it should be noted that both 3 and 4 were fluorescent, with 3 emitting at λ max of 509 nm ( Φ =0.14) and 4 at λ max of 476 nm ( Φ =0.62). Of note, the all para ‐substituted nanohoop with a single embedded pyridine is non‐emissive; a detailed investigation of the result of symmetry breaking on nanohoop fluorescence is disclosed in a separate study…”

Section: Figurementioning

confidence: 99%

Nanohoop Rotaxanes from Active Metal Template Syntheses and Their Potential in Sensing Applications

et al. 2019

View full text Add to dashboard Cite

The unique optoelectronic properties and smooth, rigid pores of macrocycles with radially oriented p systems render them fascinating candidates for the design of novel mechanically interlocked molecules with new properties.T wo high-yielding strategies are used to prepare nanohoop [2]rotaxanes,which owing to the p-rich macrocycle are highly emissive. Then, metal coordination, an intrinsic property afforded by the resulting mechanical bond, can lead to molecular shuttling as well as modulate the observed fluorescence in both organic and aqueous conditions.Inspired by these findings,aself-immolative [2]rotaxane was then designed that self-destructs in the presence of an analyte,e liciting as trong fluorescent turn-on response,s erving as proof-of-concept for an ew type of molecular sensing material. More broadly,this work highlights the conceptual advantages of combining compact p-rich macrocyclic frameworks with mechanical bonds formed via active-template syntheses.

show abstract

“…[30] Additionally, due to Laporte forbidden HOMOàLUMO transitions, all nanohoops share a common absorption maxima (labs = 340 nm) with high absorption coefficients (e) and large effective Stokes shifts ranging from 100-200 nm depending on size. [31][32][33][34] Taken together, the nanohoop scaffold offers the possibility of multiplexed imaging using a single excitation source. Moreover, the non-planarity of the benzene rings in the nanohoop also leads to better solubility when compared to planar aromatic systems.…”

Section: Introductionmentioning

confidence: 99%

Expanding the Chemical Space of Biocompatible Fluorophores: Nanohoops in Cells

White¹,

Yu²,

Kawashima³

et al. 2018

Preprint

View full text Add to dashboard Cite

Abstract:The design and optimization of fluorescent molecules has driven the ability to interrogate complex biological events in real time. Notably, most advances in bioimaging fluorophores are based on optimization of core structures that have been known for over a century. Recently, new synthetic methods have resulted in an explosion of non-planar conjugated macrocyclic molecules with unique optical properties yet to be harnessed in a biological context. Herein we report the synthesis of the first aqueous-soluble carbon nanohoop (i.e. a macrocyclic slice of a carbon nanotube prepared via organic synthesis) and demonstrate its bioimaging capabilities in live cells. This work establishes the nanohoops as an exciting new class of macrocyclic fluorophores poised for further development as novel bioimaging tools.

show abstract

Synthesis and characterization of a highly strained donor–acceptor nanohoop

Cited by 55 publications

References 26 publications

N‐doped cycloparaphenylenes: Tuning electronic properties for applications in thermally activated delayed fluorescence

N‐doped cycloparaphenylenes: Tuning electronic properties for applications in thermally activated delayed fluorescence

Nanohoop Rotaxanes from Active Metal Template Syntheses and Their Potential in Sensing Applications

Expanding the Chemical Space of Biocompatible Fluorophores: Nanohoops in Cells

Contact Info

Product

Resources

About