Unifying Principles of the Reductive Covalent Graphene Functionalization

Abellán, Gonzalo; Schirowski, Milan; Edelthalhammer, Konstantin F.; Fickert, Michael; Werbach, Katharina; Peterlik, Herwig; Hauke, Frank; Hirsch, Andreas

doi:10.1021/jacs.7b00704

Cited by 54 publications

(103 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…As seen in Figure 2, the TGA spectra of three chosen SWCNT-PhI samples are identical until 150 8C. [13a, 15] Alternatively, the high mass loss temperature and the toluene peak are an indicator for lattice decomposition, which has been previously reportedf or graphene [14] and SWCNTs. At even highert emperatures (> 400 8C), no indication for ad ifference in the samples can be found, as the TGA curvesare parallel in that region.…”

Section: Resultsmentioning

confidence: 77%

Controlling the Degree of Functionalization: In‐Depth Quantification and Side‐Product Analysis of Diazonium Chemistry on SWCNTs

Schirowski

Hauke

Hirsch

2019

Chemistry A European J

Self Cite

View full text Add to dashboard Cite

We present an in‐depth qualitative and quantitative analysis of a reaction between 4‐iodobenzenediazonium tetrafluoroborate and single‐walled carbon nanotubes (SWCNTs) via thermogravimetric analysis coupled with mass spectrometry (TG‐MS) or a gas chromatography and mass spectrometry (TG‐GC‐MS) as well as Raman spectroscopy. We propose a method for precise determination of the degree of functionalization and quantification of physisorbed aromates, detaching around their boiling point, alongside covalently bonded ones (cleavage over 200 °C). While the presence of some side products like phenol‐ or biphenyl species could be excluded, residual surfactant and minor amounts of benzene could be identified. A concentration‐dependent experiment shows that the degree of functionalization increases with the logarithm of the concentration of applied diazonium salt, which can be exploited to precisely adjust the amount of aryl addends on the nanotube sidewall, up to 1 moiety per 100 carbon atoms.

show abstract

Section: Resultsmentioning

confidence: 77%

Controlling the Degree of Functionalization: In‐Depth Quantification and Side‐Product Analysis of Diazonium Chemistry on SWCNTs

Schirowski

Hauke

Hirsch

2019

Chemistry A European J

Self Cite

View full text Add to dashboard Cite

show abstract

“…[30] Zusammenfassend resultiert die reduktive kovalente Funktionalisierung von BP mit Alkylhalogeniden unter Ver-Abbildung 3. Dies steht im Gegensatz zur neutralen Reaktionsroute (Abbildung SI 22).…”

Section: Seit2014hatderzweidimensionale(2d)schwarzephosphorunclassified

Gitteröffnung durch reduktive kovalente Volumen‐Funktionalisierung von schwarzem Phosphor

et al. 2019

Self Cite

View full text Add to dashboard Cite

Eine chemisch-reduktive Volumen-Funktionalisierung von dünnlagigem schwarzem Phosphor (BP) wurde unter Verwendung von BP-Interkalationsverbindungen entwickelt. Durche ffektive reduktive Aktivierung wurde die kovalente Funktionalisierung des geladenen BP mit Alkylhalogeniden erreicht. Die kovalente Funktionalisierung wurde umfassend mit mehreren spektroskopischen Methoden sowie DFT-Rechnungen nachgewiesen;e sl iegt ein hçherer Funktionalisierungsgrad als bei neutralen Funktionalisierungsreaktionen vor. Seit2014hatderzweidimensionale(2D)schwarzePhosphor(BP) wegen seiner hohen p-Typ-Ladungsträgermobilitätu nd seiner modifizierbaren, direkten Bandlücke große Aufmerksamkeit auf sich gezogen. [1][2][3][4][5][6][7][8][9] Im Unterschied zu Graphen besteht BP aus gewellten Schichten, die ausschließlich aus einem 2D-s-System gebildet werden und in denen jedes P-Atom ein freies Elektronenpaar aufweist. Während seine bemerkenswerten physikalischen und Materialeigenschaften bereits intensiv untersucht wurden, bleibt seine Chemie nahezu unerforscht. [10][11][12] Mittlerweile wurde eine erste Reihe von Vorschriften zur nicht-kovalenten Funktionalisierung verçffentlicht, die hauptsächlich darauf abzielen, die Instabilitätv on BP gegen Wasser und Sauerstoff zu verbessern. [13][14][15][16][17] Abgesehen von diesen Ansätzen gilt die kovalente Funktionalisierung der Oberfläche als eines der vielversprechendsten Konzepte zur Modifizierung der chemischen und physikalischen Eigenschaften von 2D-Nanomaterialien. [18,19] In diesem Sinne wurden bisher nur wenige Arbeiten, wie die Funktionalisierung einzelner Flocken mit Diazoniumsalzen [20] oder die nasschemische Funktionalisierung von zuvor hergestellten Flocken mit Nukleophilen [21][22][23] sowie mit freien Kohlenstoffradikalen, [24] publiziert. Der Grund hierfürl iegt wahrscheinlich in der niedrigen Reaktivitätv on neutralem BP bei diesen Reaktionen. In diesem Zusammenhang wird die direkte kovalente Funktionalisierung oftmals verhindert, da die BP-Schichten durch eine hohe Va n-der-Waals-Energie zusammengehalten werden. Ausd iesem Grund muss eine effektive nasschemische Funktionalisierungssequenz erst noch gefunden werden. Eine eindeutige Bestimmung der kovalenten Bindung und ihres Einflusses auf die chemische Struktur der BP-Schichten ist zudem zur systematischen Untersuchung der Reaktivitätvon BP erforderlich.Wirh aben uns die bekannte reduktive Graphenchemie, die auf der Verwendung von Graphit-Interkalationsverbindungen (GICs) beruht, zunutze gemacht. [18,[25][26][27] Als ersten Erfolg in dieser Richtung haben wir 2017 die Herstellung von BP-Interkalationsverbindungen (BPICs) mit Alkalimetallen (K und Na) beschrieben. [28] Dies ebnet den Wegz ur Erforschung der reduktiven Route basierend auf der Nutzung von

show abstract

“…Thef irst step in the reaction between the HBC-dianion and alkyl iodide is aSET from the HBC dianion to the alkyl iodide.T his fast process has been reported in the chemistry of fullerenes, [32] carbon nanotubes, [33][34][35][36][37][38] and particularly for the reductive alkylation and arylation of graphene. [15,21] TheSET is avery fast process which leads to the anion radical of the corresponding alkyl iodide and subsequently releases an iodide,w hile the simultaneously formed alkyl radical RC attacks ac arbon atom of the HBC anion radical just generated. DFT calculations of the corresponding reaction coordinate show that this process is highly exergonic and has virtually no activation barrier.…”

Section: à (First Step) This Step Is Coupled To Ar Edox-equilibrium mentioning

confidence: 99%

“…[12][13][14][15][16][17][18][19][20][21] This reductive approach allows the generation of alarge variety of covalent adducts,including alkylated, arylated, and hydrogenated graphene derivatives, which exhibit comparatively high degrees of addition. Together with the reductive bulk functionalization, the addition chemistry of graphenides deposited on surfaces [18][19][20][21] has been investigated. Thek ey point is the use of negatively charged graphites,t he so called graphite intercalation compounds (GICs), as starting materials.InGICs,alkaline metals, such as potassium, are placed between the individual carbon sheets and the graphene layers are reductively activated by electron transfer from the metal intercalates.Ageneral feature of reductive graphene functionalization protocols seems to be an inhomogeneous distribution of addends on the surface and leads to the formation of islands of highly functionalized areas next to intact nanographenes.T his distribution has been demonstrated, for example,b yh ighresolution transmission-electron microscopy (HRTEM) of polyarylated graphene, [11] and fluorescence spectroscopy of hydrogenated graphene.…”

mentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Highly Regioselective Alkylation of Hexabenzocoronenes: Fundamental Insights into the Covalent Chemistry of Graphene

et al. 2017

Self Cite

View full text Add to dashboard Cite

Hexa-peri-hexabenzocoronides (HBC) was successfully used as am odel system for investigating the complex mechanism of the reductive functionalization of graphene.The well-defined molecular HBC system enabled deeper insights into the mechanism of the alkylation of reductively activated nanographenes.The separation and complete characterization of alkylation products clearly demonstrate that nanographene functionalization proceeds with exceptionally high regio-and stereoselectivities on the HBC scaffold. Experimental and theoretical studies lead to the conclusion that the intact basal graphene plane is chemically inert and addend binding can only take place at either preexisting defects or close to the periphery.The chemistry of two-dimensional (2D) materials is currently an emerging field located at the interface between chemistry,p hysics,a nd materials science.T he archetype of such planar architectures is graphene, [1] as ingle sheet of graphite,w hich represents ah exagonal network of sp 2 -configured carbon atoms.C ovalent functionalization [2][3][4][5][6][7][8] of graphene allows the combination of its unique properties [9,10] with those of other classes of compounds.T he chemical consequence of the covalent addend binding is the rehybridization of the carbon atom, to which the addend is bound, from its initial sp 2 to an sp 3 configuration. This process can also be considered as an introduction of basal plane defects which lead to the modification of the electronic (band structure), optical, and mechanical properties.I nc ontrast, the covalent addition chemistry offers the opportunity to improve the solubility and processability,thus facilitating the manufacturing processes required for practical applications.Another highly appealing aspect of covalent graphene functionalization is the desire to discover fundamental reactivity principles within the largely unexplored realm of 2D chemistry.T he most efficient method for covalent graphene functionalization is the treatment of negatively charged graphenide sheets with electrophiles,amethod we introduced afew years ago, [11] and which since then, has been continuously improved. [12][13][14][15][16][17][18][19][20][21] This reductive approach allows the generation of alarge variety of covalent adducts,including alkylated, arylated, and hydrogenated graphene derivatives, which exhibit comparatively high degrees of addition. Together with the reductive bulk functionalization, the addition chemistry of graphenides deposited on surfaces [18][19][20][21] has been investigated. Thek ey point is the use of negatively charged graphites,t he so called graphite intercalation compounds (GICs), as starting materials.InGICs,alkaline metals, such as potassium, are placed between the individual carbon sheets and the graphene layers are reductively activated by electron transfer from the metal intercalates.Ageneral feature of reductive graphene functionalization protocols seems to be an inhomogeneous distribution of addends on the surface and leads to the formation o...

show abstract

Unifying Principles of the Reductive Covalent Graphene Functionalization

Cited by 54 publications

References 42 publications

Controlling the Degree of Functionalization: In‐Depth Quantification and Side‐Product Analysis of Diazonium Chemistry on SWCNTs

Controlling the Degree of Functionalization: In‐Depth Quantification and Side‐Product Analysis of Diazonium Chemistry on SWCNTs

Gitteröffnung durch reduktive kovalente Volumen‐Funktionalisierung von schwarzem Phosphor

Highly Regioselective Alkylation of Hexabenzocoronenes: Fundamental Insights into the Covalent Chemistry of Graphene

Contact Info

Product

Resources

About