Brightening of Long, Polymer-Wrapped Carbon Nanotubes by sp<sup>3</sup> Functionalization in Organic Solvents

Berger, F.; Lüttgens, Jan; Nowack, Tim; Kutsch, Tobias; Lindenthal, Sebastian; Kistner, Lucas; Müller, Christine Charlotte; Bongartz, Lukas M.; Lumsargis, Victoria; Zakharko, Yuriy; Zaumseil, Jana

doi:10.1021/acsnano.9b03792

Cited by 53 publications

(131 citation statements)

References 66 publications

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“…Adding pyridine groups to the backbone seems to be able to disperse larger diameter SWNTs, such as those produced by laser vaporization or arc discharge [ 36 , 51 ]. The extracted s-SWNTs have both high purity and high yield, with a reduced diameter abundance, which is more desired for electrical and optical uses [ 52 , 53 , 54 , 55 , 56 ]. Tange et al found that PFO-Py (P4) could selectively extract (13, 5) SWNT [ 52 ].…”

Section: Conjugated Polymers Used For Separationmentioning

confidence: 99%

Separation of Semiconducting Carbon Nanotubes Using Conjugated Polymer Wrapping

Wang

Lei

2020

Polymers

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In the past two decades, single-walled carbon nanotubes (SWNTs) have been explored for electronic applications because of their high charge carrier mobility, low-temperature solution processability and mechanical flexibility. Semiconducting SWNTs (s-SWNTs) are also considered an alternative to traditional silicon-based semiconductors. However, large-scale, as-produced SWNTs have poor solubility, and they are mixtures of metallic SWNTs (m-SWNTs) and s-SWNTs, which limits their practical applications. Conjugated polymer wrapping is a promising method to disperse and separate s-SWNTs, due to its high selectivity, high separation yield and simplicity of operation. In this review, we summarize the recent progress of the conjugated polymer wrapping method, and discuss possible separation mechanisms for s-SWNTs. We also discuss various parameters that may affect the selectivity and sorting yield. Finally, some electronic applications of polymer-sorted s-SWNTs are introduced. The aim of this review is to provide polymer chemist a basic concept of polymer based SWNT separation, as well as some polymer design strategies, influential factors and potential applications.

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Section: Conjugated Polymers Used For Separationmentioning

confidence: 99%

Separation of Semiconducting Carbon Nanotubes Using Conjugated Polymer Wrapping

Wang

Lei

2020

Polymers

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“…The deep optical traps (100–200 meV) lead to a strong red shift of the emission and facilitate high-purity single-photon emission at room temperature. 47 , 48 These defects can be created synthetically by arylation, 43 , 44 alkylation, 49 or covalent oxygen doping. 47 Depending on the binding configuration, two main types of defects have been identified, commonly named E 11 * (1.05 eV or 1180 nm) and E 11 * – (0.95 eV or 1300 nm) for (6,5) nanotubes (see Figure 1 , right).…”

mentioning

confidence: 99%

Population of Exciton–Polaritons via Luminescent sp³ Defects in Single-Walled Carbon Nanotubes

2020

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Semiconducting single-walled carbon-nanotubes (SWCNTs) are an interesting material for strong-light matter coupling due to their stable excitons, narrow emission in the near infrared and high charge carrier mobilities. Furthermore, they have emerged as quantum light sources as a result of the controlled introduction of luminescent quantum defects (sp 3 -defects) with redshifted transitions that enable single-photon emission. The complex photophysics of SWCNTs and overall goal of polariton condensation pose the question of how exciton-polaritons are populated and how it might be optimized. The contributions of possible relaxation processes, i.e., scattering with acoustic phonons, vibrationally assisted scattering, and radiative pumping, are investigated using angle-resolved reflectivity and time-resolved photoluminescence measurements on microcavities with a wide range of detunings. We show that the predominant population mechanism for SWCNT exciton-polaritons in planar microcavities is radiative pumping. Consequently, the limitation of polariton population due to the low photoluminescence quantum yield of nanotubes, can be overcome by luminescent sp 3 defects.Without changing the polariton branch structure, radiative pumping through these emissive defects leads to an up to 10-fold increase of the polariton population for detunings with a large photon fraction. Thus, the controlled and tunable functionalization of SWCNTs with sp 3 defects presents a viable route towards bright and efficient polariton devices.

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“…[30] Diese Technik ermçglichte auch die Abstimmung der Defektfluoreszenz sowohl in Bezug auf die Intensitäta ls auch auf die Emissionswellenlänge über verschiedene Substituenten am Aryl/Alkyl-Defekt. [31][32][33][34] In den letzten Jahren wurde über eine Reihe verschiedener Sauerstoff-und Aryl-Defekte berichtet, die nun sehr vielversprechende Werkzeuge fürd ie Erzeugung von helleren/modifizierten SWCNTs, [31,35,36] pH- [37] or Saccharid [38] -Sensoren, kurzen fluoreszierenden SWCNTs fürd ie hochauflçsende Mikroskopie [39] oder Einzelphotonenquellen für das Quanten-Computing sind. [40,41] Darüber hinaus verschiebt dieses neue Defekt-induzierte Fluoreszenzsignal die Emission noch weiter in das Biotransparenzfenster,w as zu noch besseren Gewebepenetrationseigenschaften führt.…”

Section: Einführungunclassified

Quantendefekte als Werkzeugkasten für die kovalente Funktionalisierung von Kohlenstoffnanoröhren mit Peptiden und Proteinen

Mann

Herrmann

Opazo³

et al. 2020

Angewandte Chemie

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Einwandige Kohlenstoffnanoröhren (SWCNTs) sind ein 1D‐Nanomaterial, das im nahen Infrarot (NIR, >800 nm) fluoresziert. In der Vergangenheit wurde kovalente Chemie zur Funktionalisierung von SWCNTs wenig genutzt, da sie die NIR‐Emission beeinträchtigt. Es sind jedoch bestimmte sp3‐Defekte (Quantendefekte) im Kohlenstoffgitter beobachtet worden, die die NIR‐Fluoreszenz erhalten und sogar zu einer neuen, rotverschobenen Emission führen. Hier berichten wir über Quantendefekte, die mittels lichtinduzierter Diazoniumchemie eingeführt wurden und als Ankerpunkte für Peptide und Proteine dienen. Wir zeigen, dass Maleimid‐Anker die Konjugation Cystein‐haltiger Proteine, z. B. eines GFP‐bindenden Nanobodys, ermöglichen. Darüber hinaus fungiert ein Fmoc‐geschützter Phenylalanin‐Defekt als Ausgangspunkt für die Konjugation von sichtbaren Fluorophoren zur Erzeugung mehrfarbiger SWCNTs und In‐situ‐Peptidsynthese direkt auf dem Nanoröhren. Daher stellen diese Quantendefekte eine vielseitige Plattform dar, um sowohl die photophysikalischen Eigenschaften der Nanoröhren als auch ihre Oberflächenchemie anzupassen.

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Brightening of Long, Polymer-Wrapped Carbon Nanotubes by sp³ Functionalization in Organic Solvents

Cited by 53 publications

References 66 publications

Separation of Semiconducting Carbon Nanotubes Using Conjugated Polymer Wrapping

Separation of Semiconducting Carbon Nanotubes Using Conjugated Polymer Wrapping

Population of Exciton–Polaritons via Luminescent sp³ Defects in Single-Walled Carbon Nanotubes

Quantendefekte als Werkzeugkasten für die kovalente Funktionalisierung von Kohlenstoffnanoröhren mit Peptiden und Proteinen

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Brightening of Long, Polymer-Wrapped Carbon Nanotubes by sp3 Functionalization in Organic Solvents

Cited by 53 publications

References 66 publications

Separation of Semiconducting Carbon Nanotubes Using Conjugated Polymer Wrapping

Separation of Semiconducting Carbon Nanotubes Using Conjugated Polymer Wrapping

Population of Exciton–Polaritons via Luminescent sp3 Defects in Single-Walled Carbon Nanotubes

Quantendefekte als Werkzeugkasten für die kovalente Funktionalisierung von Kohlenstoffnanoröhren mit Peptiden und Proteinen

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About

Brightening of Long, Polymer-Wrapped Carbon Nanotubes by sp³ Functionalization in Organic Solvents

Population of Exciton–Polaritons via Luminescent sp³ Defects in Single-Walled Carbon Nanotubes