Supramolecular Complexation of Carbon Nanostructures by Crown

Feb 16, 2017 - *E-mail: [email protected], http://www.nazariomartingroup.com/. ... In 2015, he obtained an MBA from the IE Business School and started ...
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SUPRAMOLECULAR COMPLEXATION OF CARBON NANOSTRUCTURES BY CROWN ETHERS Luis Moreira, Beatriz M Illescas, and Nazario Martín J. Org. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.joc.6b03030 • Publication Date (Web): 16 Feb 2017 Downloaded from http://pubs.acs.org on February 17, 2017

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The Journal of Organic Chemistry

SUPRAMOLECULAR COMPLEXATION OF CARBON NANOSTRUCTURES BY CROWN ETHERS Luis Moreira,a Beatriz M. Illescas,a Nazario Martína,b,* a

Departamento de Química Orgánica, Facultad de Química, Universidad Complutense de Madrid, E-

28040-Madrid, Spain. b

IMDEA-Nanoscience, C/ Faraday, 9, Campus de Cantoblanco, E-28049-Madrid, Spain

E-mail: [email protected] http://www.nazariomartingroup.com/

TABLE OF CONTENTS

ABSTRACT

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Since their discovery, crown ethers as well as the most recent carbon nanostructures, namely fullerenes,

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carbon nanotubes and graphene, have received a lot of attention from the chemical community.

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Merging these singular chemical structures by non-covalent forces has provided a wealth number of

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unprecedented supramolecular assemblies with new geometrical and electronic properties whose more

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representative examples have been presented in this synopsis organized according to the different nature of

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the carbon nanostructures.

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INTRODUCTION The history of modern supramolecular chemistry and its application in synthetic systems can be traced back to the discovery of crown ethers by Pedersen in 1967.1 Soon afterwards, the extraordinary ability of these cyclic compounds to complex different molecules led to other macrocyclic receptors, namely cryptands (Lehn, 1969)2 and spherands (Cram, 1979).3 These seminal discoveries led to their designers to the Nobel Prize in chemistry “for the development and use of molecules with structure-specific interactions of high selectivity” in 1987, thus starting the so-called “host-guest” chemistry. The relatively easy synthesis and the possibility of modulating their affinity by tuning their substituents, number and type of donor atoms, cavity size and degree of preorganization have made them one of the most versatile assets in the supramolecular chemist’s toolbox.4 On the other hand, carbon nanostructures represent a less-explored field starting with the discovery of fullerenes by Kroto, Smalley and Curl in 1985,5 who received the Nobel Prize in Chemistry in 1996. Soon afterwards, the finding of multiwall single nanotubes (MWCNTs) by Iijima in 1991,6 and the single wall carbon nanotubes (SWCNTs) independently by Iijima and Bethune in 19937,8 became important milestones. More recently, the aforementioned findings have been complemented with the discovery of graphene by Geim and Novoselov in 2004,9 which was awarded with the Nobel Prize in Physics in 2010. Although many different forms of carbon are known,10 we will mainly focus our attention on fullerenes and its endohedral derivatives, carbon nanotubes, carbon nanohorns and graphene (Figure 1).

Figure 1. Main carbon nanostructures considered for supramolecular complexation [from left to right: [60]fullerene, single-wall carbon nanotube (SWCNT), single-wall carbon nanohorn (SWCNH) and graphene].

Given the extraordinary properties of the aforementioned nanostructures, it is not surprising that chemists ACS Paragon Plus Environment

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have combined them together in the search for unprecedented systems. In this JOC synopsis we will

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pinpoint the most relevant examples of their supramolecular complexation by crown ethers.

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FULLERENES Fullerenes are one of the most widely used electron acceptor molecules given their outstanding electronic properties, namely small reorganization energy,11 low reduction potential,12 appreciable absorption cross section throughout the solar spectrum13 and efficient generation of long-lived charge-separated states.14,15 Furthermore, their spherical geometry and remarkable hydrophobicity make them appealing systems for 3D supramolecular interactions. Pristine fullerenes were complexed for the first time with azacrown ethers 1 and 2, bearing long lipophilic chains on the nitrogens (Figure 2). The ability of these systems to act as supramolecular “baskets” was suggested by Effing et al. on sight of the additional stability of the crown ether’s Langmuir-Blodgett films upon addition of fullerenes.16

1

2

Figure 2. Azacrown ethers used to bind fullerenes and scheme of the supramolecular “basket” envisioned for the 1:1 complex.

Following this pioneering work, Mukherjee and co-workers, synthesized a series of crown ethers 3-8 to evaluate their affinity towards fullerenes, finding that larger cavities and preorganized systems led to larger binding constants (Ka) and that complexation occurred with the involvement of an electron-transfer process (Table 1, left).17-20 Liu et al., also observed this size-dependence relationship in a series of selenacrown ethers 9-12 and a better stabilization upon introduction of the heteroatoms (Table 1, right).21 Table 1. Stability constants for a series of 1:1 [60]fullerene•crown ether complexes. Left: crown ethers developed by Mukherjee and co-workers. Right: selenacrown ether developed by Liu et al.

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3

4

5

9

10

log Ka = 2.8

log Ka = 2.2

log Ka = 1.9

log Ka = 3.1

log Ka = 3.3

6

7

8

11

12

log Ka = 3.8

log Ka = 2.9

log Ka = 3.9

log Ka = 3.2

log Ka = 3.2

(rt, CCl4, 1H-NMR / UV-vis)

(rt, CCl4, UV-vis )

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D’Souza et al. further exploited this affinity with molecular receptors 13-15 (Figure 3). Addition of

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porphyrins as a supplementary recognition motif provided new π-π and charge transfer interactions,

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leading to higher affinities. Proximity effects of the crown ethers at different positions of the host molecule

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and the possibility of having cooperative effects between them explained the trend 14 < 15 < 13.

[13•C60]

[14•C60]

[15•C60]

log Ka = 3.9

log Ka = 3.7

log Ka = 3.8

(rt, o-DCB, Fluorescence)

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Figure 3. Crown ether appended free-base porphyrin-fullerene donor-acceptor complexes.

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Notably, stability of [13•C60] could be tuned upon addition of a potassium salt. An excess of it led to a

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decrease of the nucleophility and to an increase on the rigidity of the crown ether moiety, thus weakening

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the complex. Subsequent addition of [18]crown-6 captured the cation, reversing the equilibrium and

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recovering the original complex (Scheme 1).22

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Scheme 1. K+ induced switching of intra to intermolecular association (forward reaction) and [18]crown-6 induced reversible switching (backwards reaction).

More recently, our group designed molecular tweezer 16, appended with two benzo[18]crown-6 ethers in an electron donor 9,10-di(1,3-dithiol-2-ylidene)-9,10-dihydroanthracene (exTTF) scaffold offering both geometrical (concave-convex) and electronic (donor-acceptor) complementarity (Figure 4). The unique combination of these recognition elements led to an extraordinarily high affinity towards fullerenes in spite of the low degree of preorganization of the system.23

[16•C60] log Ka = 6.7 (rt, PhCN, UV-vis) Figure 4. The combination of crown ethers and exTTF as recognition motifs led to robust complexation of C60.

This result spurred our interest in unveiling the nature of supramolecular crown ethers-C60 affinity. As a result, we performed a detailed evaluation of the supramolecular interactions in receptors 17-22 (Scheme 2). The stability of the resulting complexes varied more than three orders of magnitude between 21, the receptor with the larger crown ethers, and 22, lacking them. Noteworthy, aza-crown ether derivatives 18 and 20 exhibited significantly smaller affinities than their oxygen-bearing analogues 17 and 19 due to the less complementary structure conferred by the additional flexibility of nitrogen atoms (Figure 5, left). ACS Paragon Plus Environment

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Additional electrochemical measurements, transient absorption spectroscopy and theoretical calculations

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were carried out, underpinning the experimental findings and prompting to a synergetic interplay of donor-

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acceptor, π–π, n–π and CH···π interactions as the basis for the affinity of our receptors towards C60 (Figure

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5, c).24

17

18

log Ka = 4.8

log Ka = 3.8

19

20

log Ka = 6.7

log Ka = 5.1

21

22

log Ka = 6.9

log Ka = 3.3

(rt, ClPh, UV-vis)

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Scheme 2. Series of exTTF-(crown ether)2 molecular tweezers designed to host C60.

c)

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Figure 5. Side view of the optimized geometries calculated for complexes [19•C60] (a) and [20•C60] (b). The affinity of our

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receptors arises as an interplay of donor-acceptor (black), π–π (green), n–π (red) and CH···π (blue) interactions (c).

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Fullerene derivatives Whereas complexation of pristine fullerenes allows maintaining their electronic conjugation and thus, all their singular properties, it has often been chemically modified in order to increase the number of possible recognition motifs as well as the complementarity and preorganization of the host molecule and, therefore, the stability of the supramolecular complexes obtained.25,26 This becomes critical when working with crown ethers, which are typically highly flexible and need to reorganize themselves at the expense of an entropic cost. To overcome this, chemists have introduced additional recognition motifs to the fullerenes, typically ammonium ions, given their high degree of directionality, selectivity and large binding constants with crown ethers.27 This approach was first used in 1999 by Diederich et al. combining fullerene derivatives 23, embedded with a dibenzo-24-crown-8, and fullerene malonate 24, bearing a dibenzylammonium salt (Scheme 3). Threading of the resulting pseudorotaxane was pH dependent and reversible as supported by fluorescence measurements.28

log Ka = 3.0 (rt, CDCl3-CD3CN 9:1, 1H-NMR) Scheme 3. pH dependent reversible threading of the first supramolecular fullerene dyad.

Soon, this strategy expanded into a series of molecularly interlocked donor-acceptor complexes with welldefined structures. The first one, developed in 2002 by Torres and co-workers, consisted on phthalocyanine-fullerene dyad 25, which exhibited a moderated binding constant in solution (Figure 6). However, the distance between the donor and the acceptor moieties was too large for observing any ACS Paragon Plus Environment

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electronic interaction on the ground state.29 Nevertheless, photochemical investigation showed an effective intracomplex electron transfer mechanism on the excited state.30

25 log Ka = 4.1 (rt, DCM, Fluorescence) Figure 6. Molecular structures of the first [2]pseudorotaxane Pc/C60 dyad.

Similar structures were obtained by combining fullerene derivatives with other electroactive moieties such as triphenylamine,31 porphyrin,32,33 perylene34 or terpyridine.35 In our lab we have also developed some analogous interlocked systems by combining a DB[24]C8fullerene with a series of exTTF-based secondary ammonium salts to obtain complex 26 or the more flexible 27 (Figure 7). UV-vis and CV measurements also revealed negligible electronic communications in the ground state, suggesting that both moieties are not close enough. However, fluorescence analysis suggested an electron transfer from the donor to the acceptor moiety in the excited state.36

26

27

log Ka = 4.1

log Ka = 3.3

(rt, DCM/CH3CN 1:1, Fluorescence) Figure 7. Stability constants of different DB[24]C8 fullerocrown ethers with exTTF derived ammonium salts.

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Given the limitations for obtaining electronic interactions in the ground state with the pseudo-rotaxane approach, chemists soon explored new designs with primary ammonium salts offering stronger interactions. Following this approach, Nierengarten and co-workers developed a cup-and-ball complex conjugating meso-crown porphyrin 28 and fullerene malonate 29. Even though both porphyrin-fullerene and ammonium-crown ether interactions are weak by themselves,37 their cooperative interplay in [28•29] led to a dramatic increase of the overall stability (Scheme 4).38

log Ka = 5.6 (rt, DCM, Fluorescence) Scheme 4. Cooperativity between π-stacking and ammonium-crown ether interactions increased Ka by two orders of magnitude.

In sight of this extraordinary result the cooperative interplay between the different non-covalent interactions was comprehensively analyzed. For this, 29 was complexed with a series of new metalloporphyrin-crown ether receptors, 30-M, generating very stable complexes (Figure 8). Using a methanofullerene was crucial in order to circumvent the low solubility of pristine fullerenes and, therefore, the strong entropic influence of desolvation in the overall complexation stability. Spectroscopical, electrochemical and computational analysis demonstrated the presence of electronic interactions in the ground state which suggested that the origin of π−π interactions stems from dispersion forces in free base porphyrins and from a combination of electrostatic and dispersion interactions in metalloporphyrins. The larger than expected from the trend stability of 30-Co was explained on the base of the strong interaction

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between fullerenes and group 9 metals. Finally, the high value obtained for the effective molarity (EM) of the system, a parameter accounting for the easier formation of an intramolecular reaction over its intermolecular analogous, proved the nice complementarity of the receptor motifs in the [30-Zn•29] (Scheme 5).39

30-M (M = 2H, Co, Ni, Cu, Zn)

log Ka [30-M•29] (rt, DCM, UV-vis)

Figure 8. Host molecule 30-M and its binding constants upon complexation with 29.

Scheme 5. a) The EM (effective molarity) of the system was obtained by evaluating each supramolecular interaction separately based on this scheme. b) The porphyrin-fullerene interaction was assessed by 1H-NMR titration of 30-Zn with the aminoprotected methanofullerene 31 in CDCl3 at rt yielding KI. c) The stability of the ammonium−crown-ether association, KII, was evaluated by 1H-NMR titration of 29 with reference crown ether 32. The overall binding constant, Ka, was obtained by UV-vis titration of 30-Zn with 29 in CHCl3 at rt.

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The stability of these complexes led us to fuse 30-Zn into porphyrin dimer 33, exhibiting two almost orthogonal porphyrin moieties, and into porphyrin tape 34, where they are fully conjugated (Figure 9). The tendency towards ring closing of 30-Zn enabled us to simplify the myriad of internal micro equilibria leading to semicomplexed species into a two-steps process characterized by K1 and K2 . Analysis of factor α evidenced a negative cooperativity in the complexation process, i.e. binding of the first molecule of 29 led to a complex where it was more difficult to bind a second equivalent. This fact was justified by the decrease of the donating ability of the second porphyrin moiety once the first fullerene unit has been added, a phenomenon also observed in other porphyrin dyads.40 Remarkably, the α value of [34•292] was much higher than for [33•292], suggesting that this negative effect was partially compensated by the stabilizing C60-C60 interactions taking place in the more stable syn-disposition of [34•292].39

O

O

RO

O

OR

O

O

O

O

O

ROOR

O

O O NH H O H O O

Ar

Ar O

N

N

N

Zn N

N

Ar

O

H

N Zn

N

O O HN H O

N

O

syn

Ar

and/or O

OR

O

O O RO Ar

Ar O

N O

H O HN O

O

N

H O

N

Zn N

N Zn

N

N

N

O Ar

Ar

O O HN H O H O O

anti

OR O O O

[33•292] log K1 = 8.7 log K2 = 5.4

OR

O

[34•292] log K1 = 6.8 log K2 = 5.4

α = 0.0005

α = 0.04

(rt, DCM, UV-vis) Figure 9. Supramolecular complexes obtained from host molecules 33 and 34 with guest fullerene 29.

This cup-and-ball strategy has also been reproduced in other supramolecular complexes.41,42 Among them we developed system 35 where the planar porphyrin moiety was replaced by the concave surface of an ACS Paragon Plus Environment

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exTTF molecule (Figure 10). The resulting binding constant was even larger than the one found with free base porphyrin 28, thus highlighting the role of the concave-convex complementarity.43

[35•29] log Ka = 6.3 (rt, CHCl3, UV-vis) Figure 10. exTTF also offered π-π interactions as an additional recognition motif while providing better geometrical complementarity.

Alternatively, D’Souza and co-workers developed the so-called “two-point” binding strategy, where axial coordination to the metal atom with a pyridine moiety substituted the π-π stacking between the porphyrin and the fullerene derivatives. This approach enabled obtaining better control over the distances and orientations of the building blocks.44 In addition, the stronger axial coordination interaction contributed more towards the overall stability of the resulting complexes as seen when comparing 36 to 37. This approach, however, hinders the direct contact between the porphyrin and the [60]fullerene (Figure 11).45 Interestingly, it was possible to switch between intra- to intermolecular electron transfer in 37 by addition or extraction of K+ in a similar way than that observed for [13•C60] (Scheme 1).46

36 log Ka = 4.6

37 log Ka = 4.2

(rt, PhCN, Fluorescences) Figure 11. Structure of complex 36, relying on axial coordination and of complex 37, relying on π-stacking.

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More complex supramolecular ensembles constituted by various fullerene derivatives or cofacial organization of porphyrins or phtalocyanines have also been prepared.47-49 ENDOHEDRAL METALLOFULLERENES In spite of their structural resemblance, endohedral metallofullerenes are intrinsically different to their empty analogues, presenting unique properties such as metal-to-cage electron transfer, larger absorptive coefficients in the visible region of the electromagnetic spectrum and a low HOMO-LUMO energy gap.10,50 Unfortunately, their scarce availability has largely hindered their use up to date. In this context, the affinity of La@C82 towards nitrogen containing solvents, enabling its preferential extraction from raw soot, led to the study of its 1:1 supramolecular complexes with azacrown ethers 38-40 and polyamine 41 (Figure 12). As in previous cases, the affinity increased with the number of heteroatoms, whereas the lower affinity of acyclic polyamine 41 in comparison to 39 pointed to the presence of a macrocycle effect. Further electrochemical studies revealed that crown ethers were acting as donor moieties in electron-transfer processes.51-55

38

39

40

41

log Ka = 5.7

log Ka = 6.5

log Ka = 4.5

log Ka = 4.5

(rt, PhNO2, vis-NIR) Figure 12. Receptors designed for the complexation of La@C82.

In order to get further information on the structure, Akasaka and co-workers developed a new series of sulfur derivatives 42-46 including unsaturated crowns 43-45, known to exhibit a rigid structure with the sulfur atoms forced towards the inside of the ring (Figure 13). Vis-NIR spectroscopy and electrochemical studies supported that La@C82 formed weak complexes with 43-46 via an electron transfer process where the metallofullerene was reduced to its anion form. Whereas thia-crown ether 44 exhibited the largest

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binding constant, due to its best complementarity, 46 did not exhibit effective complexation, thus highlighting the importance of the olefinic moiety.56

42 log Ka = 1.7

43 log Ka = 2.0

44 log Ka = 2.1

45 log Ka = 2.0

46 Too weak

(rt, PhNO2, vis-NIR) Figure 13. Receptors designed for the formation of 1:1 complexes with La@C82.

Following these examples, Jeppesen, Fukuzumi and coworkers obtained strong complexation between Li+@C60 and crown ether functionalized monopyrrolotetrathiafulavelene (MPTTF) derivatives 47 and 48 (Figure 14). Binding constants obtained were much higher than those of their crown size related complexes 11•C60 and 12•C60, pinpointing the importance of electrostatic interactions with the endohedral metal. In order to obtain better insights, Li+@C60 was treated separately with TTF and 4’nitrobenzene[24]crown-8 ether, observing interaction only with the crown ether. In addition, as no chargetransfer band was observed for 47•Li+@C60, complexation was proposed to occur through the interactions with the crown ethers, something supported by DFT calculations. Theoretical calculations on 48 evidenced that the larger size of the sulfur atoms took further away the fullerene from the crown ether than in 47, therefore explaining its lower stability.57

47

48

log Ka = 6.3

log Ka = 5.5

49

50

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Figure 14. MPTTFs derivatives designed as receptors for Li+@C60 and reference compounds TTF and 4’nitrobenzene[24]crown-8 ether.

In sight of these results, a new receptor for Li+@C60 consisting in a rigid pentiptycene-based bis(crown ether) host (PBCE), 51, was developed (Figure 15). The electron donor character of the scaffold led to a photoinduced electron-transfer process through a rigid distance in the complex. Interestingly, the assisting role of the Li+ ion inside the cage in the supramolecular recognition is clear when considering that complexation was not observed with C60.58

[51•Li+@C60] log Ka = 4.1 (rt, PhCN, UV-vis) Figure 15. Molecular representation of the complex formed between the PCBE host and the Li+@C60 guest.

CARBON NANOTUBES In contrast to the rich supramolecular chemistry of fullerenes, carbon nanotubes (CNT) have been considerably less explored due to the difficulty in obtaining homogeneous and well-defined structures. This is a pressing problem considering that the outstanding electronic and mechanical properties of single walled CNT (SWCNT) require their effective dispersion, solubilization and separation after overcoming large van der Waals forces between adjacent tubes.59 Whereas solubilization has mainly been achieved by covalent modification of the SWCNT,60-63 this approach implies disturbing their π system and electronic properties. As a result, non-covalent methods have emerged as a useful alternative. In this regard, Wong and coworkers have solubilized oxidized carbon nanotubes, 52, by conjugating the carboxylic groups present at their ends or oxidized defect sites with 2-aminomethyl-18-crown-6 ether, 53, achieving high concentrations of complex 54 in different organic solvents. Given the mild reaction ACS Paragon Plus Environment

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conditions and that the adduct does not appear to form in the presence of standard carbodiimide linker reagents, this interaction arises most likely from a R-COO- +H3N-R ionic interaction between the carboxylate anions and the ammonium group and not through a covalent bond (Scheme 6).64,65

52

53

54

Scheme 6. Synthetic scheme for the SWCNT/crown ether complex 54.

An alternative strategy to disperse SWCNT consists in forming their respective polyelectrolytes, where nanotubes become negatively charged by reduction and subsequently repelled by Coulombic interactions upon addition of polar aprotic solvents. Following this approach, Martí and co-workers studied the impact of complexing these SWCNT polyelectrolytes with [18]crown-6, finding that trapping the potassium cation shielded their charge from their counterions, preventing their combination and increasing the repulsions between nanotubes (Scheme 7). The resulting solubility of the SWCNT was largely increased, exceeding all previously reported values.66,67

Scheme 7. Scheme of the crown-ether-assisted dissolution of SWCNT polyelectrolytes.

Supramolecular interactions have also been used to direct the self-assembly of gold nanowire over CNTs. For this, Sainsbury et al. combined dibenzo[24]crown-8-modified gold nanoparticles, 55, with dibenzylammoniumcation-modified multiwalled carbon nanotube (MWCNT), 56 (Figure 16). As evidenced by several control experiments, the driving force for the formation of the nanowire was the complexation of the MWCNTs with the crown ether moieties to form a surface-confined pseudorotaxane.68 ACS Paragon Plus Environment

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Figure 16. Building blocks used for the self-assembly of a golden nanowire over CNTs.

Planar pyrene derivatives have also been used as supramolecular anchors providing a versatile platform for obtaining SWCNT hybrids where the main interaction is π-stacking,69 which not only aids in the exfoliation of the nanotubes, but also enables linking different molecules on its surface. This approach was used by D’Souza and co-workers to build SWCNT donor-acceptor hybrids were electron transfer occurred in the excited state from a meso-crown porphyrin subunit to the SWCNT in 5770 or from the SWCNT to a more acceptor fullerene derivative in 58 (Scheme 8).71

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Scheme 8. Chemical structure of SWCNT–Pyr–NH3+–crown–porphyrin nanohybrid 57 and of SWCNT–Pyr–NH3+–crown–C60 conjugate 58.

Carbon nanohorns Carbon nanohorns (CNHs) are topologically related to carbon nanotubes as they could be considered a capped version of them with a highly constrained end. However, they are easier to obtain pure due to their metal-free synthesis. In spite of this, their supramolecular properties remain largely unexplored. Some remarkable exceptions are the supramolecular dyads developed by Vizuete et al., which demonstrated that CNHs can act as acceptor systems when confronted to strong electron donating molecules such as ACS Paragon Plus Environment

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porphyrins (59),72 or behave as donor systems when combined with fullerene derivatives (60). Transient absorption spectroscopy allowed determining that, upon excitation, the radical cation of the porphyrin moiety in 59 or the radical anion of the C60 moiety in 60 are formed, which implies that the CNHs can both accept an electron from the donor porphyrin or give an electron to the fullerene unit. As in previous cases, the ammonium-crown ether interaction was critical in obtaining stable complexes (Scheme 9).73

Scheme 9. Electronic transfers in a series of donor-acceptor conjugates where the CNH can act both as a donor, or as an acceptor.

GRAPHENE Surprisingly, whereas all the previous nanostructures can be seen as derivatives from graphene the supramolecular combination between graphene and crown ethers has not been properly addressed so far. This is striking when considering that many of the previous examples could be taken as benchmarks, that there is already a number of covalent conjugates74,75 and that crown ethers have even been embedded within the graphene structure.76

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A notable exception was developed by Wei et al. when using [18]crown-6 adsorbed on the surface of graphene as a molecular anchor for carbon dots (CDs). Interestingly, fluorescence of the CDs was effectively quenched by addition of a solution containing the crown ether-graphene conjugate through a FRET process. Subsequent addition of a potassium salt would decomplex that supramolecular system due to the stronger affinity of [18]crown-6 towards the potassium salt, thus recovering the fluorescence of the CD. In this manner, this system could be used as an effective all-carbon sensor for potassium determination (Scheme 10).77

Scheme 10. Proposed mechanism for the graphene-based metal sensor.

SUMMARY AND OUTLOOKS Along this synopsis, it has been evidenced the extraordinary ability of crown ethers to form supramolecular complexes with different carbon nanostructures and the impact of changing their size and composition in modulating the π-π, n-π, CH-π, dispersion forces and/or charge transfer interactions governing this recognition. Furthermore, adding different substituents can significantly modify the efficiency of the complexation process by adding additional recognition motifs which broaden the scope of complexation. Fullerenes have been, by far, the most widely studied systems for their supramolecular interaction with crown ethers provided their well-defined geometry and electronic properties either in their pristine form or in the wide variety of derivatives prepared along the last three decades.78-80 Interestingly, these studies have been used as a benchmark for further carbon nanostructures such as CNT and graphene. ACS Paragon Plus Environment

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Crown ethers have also been used for complexing supramolecularly CNT, and in a lesser extent CNH and graphene in the search for better solubility and exfoliation properties as well as for their electronic modification by means of photo and/or electroactive molecules, which represents an ease methodology for n- and p-doping of these materials. As with fullerenes, crown ethers have provided a useful and versatile alternative for the non-covalent chemical modification of these carbon nanostructures taking advantage of the rich diversity of weak forces stemming from these complementary molecular systems.

ACKNOWLEDGEMENTS

Financial support by the European Research Council (ERC-320441-Chiralcarbon), the Ministerio de Economía y Competitividad (MINECO) of Spain (project CTQ2014-52045-R), the Comunidad Autónoma de Madrid (PHOTOCARBON project S2013/MIT-2841) and the European Commission (EC) FP/ ITN “MOLESCO” (project no. 606728). L.M. thanks the Obra Social “la Caixa” for a postgraduate fellowship.

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