Electron Confinement Effect of Laser Dyes within Dendritic Structures

doi:10.4236/jeas.2011.11001

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Journal of Encapsulation and Adsorption Sciences, 2011, 1, 1-6

doi:10.4236/jeas.2011.11001 Published Online March 2011 (http://www.scirp.org/journal/jeas)

Electron Confinement Effect of Laser Dyes

within Dendritic Structures

Francisco Márquez1,* María José Sabater2

1School of Science and Techn ol o gy , Turabo University, 00778PR, USA.

2Universidad P ol i técni c a de Val enci a -C .S.I.C., Av. Naranjos s/n, 46071-Valencia, Spain

E-mail address: fmarquez@suagm.edu

Received February 19, 2011; revised March 18, 2011; accepted March 25, 2011

Abstract

Dendrimers are a novel class of nanometric-size macromolecules with a regular tree-dimensional like array

of branch units [1,2]. Their synthetic availability in a wide range of sizes combined with their peculiar archi-

tecture makes them versatile building blocks for a wide range of potential applications [3]. Some years ago,

Meijer and co-workers reported that the modification of terminal amine functionalities of a fifth generation

poly(propyleneimine) dendrimer (DAB-dendr-(NH2)64) with bulky substituents, (typically N-t-BOC pro-

tected phenylalanine), results in the formation of the so-called “dendritic box” (DAB-dendr-(NH-t-

BOC-L-Phe)64) [4]. Within this macromolecular structure it is possible to encapsulate a variety of guest mo-

lecules due to the existence of internal cavities in the core. The photophysical properties of the guests can be

modulated by the innovative electron confinement effect. In this respect, we wish to report that the emission

frequency of organic dyes can be easily modulated by encapsulation in a dendritic box. The emission bands

of dye molecules incorporated into a dendrimer can effectively be red shifted with respect to their emission

in solution and contrary to other confined spaces of considerable hardness, the magnitude of this shifting can

be regulated under appropriate experimental conditions. This peculiar effect could have unprecedented ap-

plications in the development of supramolecular devices relating to the frequency tuning of organic laser

dyes.

Keywords: Dendrimer, Confinement, Dyes

1. Introduction

The electron confinement effect, that has been experi-

mentally observed in organic guests included within zeo-

lite hosts, is based on the concept that the molecular or-

bitals of the adsorbates inside the host cavities are not

extended over all the space, as they are in the gas phase,

but instead are forced to limit within a reduced and regu-

lar space [5]. This confinement effect is stronger as the

size of the confined guest approaches the cavity dimen-

sions, producing an energy increase of all molecular or-

bitals [6].

The HOMO has been predicted to be more sen-

sitive that the LUMO, and the predicted effect is a reduc-

tion of the HOMO-LUMO energy gap that is reflected in

the optical properties of the guest, particularly the ba-

thochromic shift of the fluorescence emission [6].

In principle, the polar or non-polar nature of the den-

dritic shell can establish different interactions with sol-

vents and this property is expected to alter the size of the

dendritic box in a specific way. Thus, we envisaged that

a chemical consequence of this is that solvation effects

could lead to either an enlargement or a reduction of the

original macromolecular dimensions by changing the

solvent polarity. This would leave no alternative but to

temporarily deform the size of the dendritic cavities in-

side. As a consequence, guest molecules incorporated

within the dendritic cavities might interact differently

with the dendritic walls influenced by the solvent envi-

ronment. When the dendritic cavity and the guest dimen-

sions are closer, the interactions can be sufficiently im-

portant as to experience strong repulsions. Such should

be the case when solvents of opposite polarity to the

dendritic system are employed. This stronger interaction

may modify the HOMO-LUMO energy gap of the guest

resulting in appreciable modifications of the photo-

physical properties of the guest. This concept, which has

been documentarily confirmed by theoretical predictions

and recent experimental results, is a reflection of the con-

F. MARQUEZ ET AL

finement effect imposed by the host [5,6].

In order to test the validity of these assumptions, we

studied the photophysics of several dye molecules in-

corporated into a “dendritic box” of a fifth generation

poly (propyleneimine) dendrimer (DAB-dendr-(NH-t-

BOC-L-Phe)64). These experiments were conducted in

solvents of pronounced different polarity and the photo-

physical data were compared to those of dye molecules

in neat solvents.

2. Experimental

For the investigation presented here, three dye molecules

(Bengal Rose 1, Rhodamine B 2 and Congo Red 3) were

encapsulated in three different dendritic boxes con-

structed from a fifth generation poly (propylene imine)

dendrimer with 64 terminal amine groups [DAB-

dendr-(NH-t-BOC-L-Phe)64] and a L-phenylalanine de-

rivative.

The dendritic box was synthesized according to a pre-

viously reported procedure [4b]. Hence, in a typical pro-

cedure 36 mg of Rose Bengal (3.5 x 10-5mol) or 24.5 mg

of Red Congo (3.5 x 10-5 mol) and 16.9 mg of Rhoda-

mine B (3.5 x 10-5 mol) was added to a solution of 50 mg

of dendrimer DAB-dendr-(NH-t-BOC-L-Phe)64 (64 end

amine groups) in 5 mL of CH2Cl2 with 1 mL of trie- thy-

lamine and the solutions were stirred for 24 h at room

temperature. Then 161 mg of N-tBOC-L-phenylalanine

N-hydroxy-succinimide ester was added and the solu-

tions were stirred overnight. Dilution to approx. 50ml

with dichloromethane was followed by washing with

water and saturated Na2CO3 solution. The organic layer

was dried with MgSO4 and the solvent was evaporated

under vacuum to afford the dye-doped dendrimer. In

cases where the dyes were poorly soluble in water, the

dendrimer was purified by dialysis until no traces of free

dye were detected by HPLC.

Dye-doped dendrimers were characterized by ma-

trix-assisted laser desorption ionisation time-of-flight

mass spectroscopy (MALDI-TOF-MS), 1H and 13C nu-

clear magnetic resonance (NMR), ultraviolet and infrared

spectroscopy and by cryo-Scanning Electron Micros-

copy.

3. Results and Discussion

The concentration of encapsulated guests was estimated

by elemental analysis by determining the chlorine and

sulfur content for compounds 1 and 2 respectively. The

loading of compound 3 was estimated by UV/vis spec-

troscopy. In all cases, the loading level of the dye incor-

porated into the dendritic structure was ca. 3 dye mole-

cules per dendrimer.

The excitation and emission spectra of pure 1 in etha-

nol were recorded at room temperature. The emission

spectrum consisted of a sharp and featureless band

around 574 nm and a small shoulder at ca. 620 nm. Sim-

ilar spectra could be obtained when the spectra were reg-

istered in the less polar solvents dichloromethane and

n-hexane (see Figure 1).

Interestingly, when the same dye molecule was en-

capsulated within the dendrimer, a progressive red shift-

ing of the band could be measured when the medium po-

larity was reduced (from 8 nm in dichloromethane to 37

nm in n-hexane) (see Figure 2a).

As for 1, common organic solvents such as ethanol,

dichloromethane and n-hexane exerted hardly any no-

ticeable influence on the emission spectra of pure dyes 2

and 3. Nevertheless, and as expected, the emission spec-

tra of 2 and 3 when incorporated into the dendritic box

underwent a remarkable red shifting (see Figure 2 b-c).

The fluorescence band of the dye 2 incorporated into the

dendritic structure displayed a maximum bathocromic

shift of ca. 30 nm. However, the most spectacular red

shift was observed in the case of the dye 3-doped den-

drimer in which a red shift of ca. 200 nm was measured

in n-hexane with respect to the emission spectrum re-

corded in ethanol.

The loading level of the dyes incorporated into the

dendritic structures was similar in all cases and for this

reason an explanation to these experimental results

should be found in the increase of the spatial restrictions

imposed to the dye, leading to an enhancement of the

observed electron confinement effect. To rationalize

these results it is necessary to consider that non polar

solvents such as n-hexane can cause a dramatic shrink-

age of the original size of the macromolecule. In addition,

the non-polar character of the solvent may induce a much

closer association of the dye-doped dendrimers or even

its aggregation (Figure 3 displays a simulation of the dye

1-doped dendrimer indicating the possible equilibrium in

polar and non-polar solvents). The combination of both

phenomenons can paradigmatically lead to an effective

reduction of the internal dendritic cavities where the

guest molecules are located, hence inducing changes in

the frontier orbitals of the dyes to an extent that will de-

pend on the degree of interaction exerted by the branches

of the macromolecule. This stronger confinement is re-

flected by the notable reduction of the energy gap

S0→S1* and consequently by a bathocromic shift of the

emission spectra of the guests. Obviously, this effect is

stronger when a host-guest tight fit occurs (a requirement

that can be achieved when non-polar solvents as

n-hexane are used).

Finally, the room temperature fluorescence lifetimes

for the dyes incorporated into the dendritic structures

F. MARQUEZ ET AL

Bengal Rose

intensity(a.u.)

550 600 650 700

wavelength(nm)

Figure 1. Emission spectra at room temperature of Bengal Rose in different solvents: (a) Ethanol, (b) Dichloromethane and

wavelength(nm)

1 2 3 1 2 3 (c)

×5

550 600 650 700 600 700 400 500 600

1 2 3 (b)

×4

(a)

×3

intensity(a.u.)

Figure 2. Emission spectra at room temperature of Bengal Rose (a), Rhodamine B (b), and Congo Red (c) included within the

dendritic structure in different solvents: (1) Ethanol, (2) Dichloromethane and (3) N-hexane.

(a) (b)

Figure 3. Theoretical Simulation of the equilibrium experimented by three dendritic structures with three molecules of Ben-

gal Rose incorporated within the structure, in non polar (a) and polar (b) solvent.

were adjusted to single-exponential functions. Figure 4

shows the fluorescence decays obtained for Rhodami-

neB@dendrimer in different solvents. These constants,

which were lower than the ones measured for the pure

dye in ethanol ( = 5.1ns) decreased substantially from

ethanol (3.1 ns) to dichloromethane (1.1 ns) and

n-hexane (0.5 ns). This kinetic behaviour resulting from

the orbital-confinement effect enhances the non radiative

F. MARQUEZ ET AL

CPS

Time

(

nsec

)

Figure 4. Normalized fluorescence decays of RhodamineB@dendrimer in different solvents: (●) Ethanol, (▪) Dichloromethane

and (▲) N-Hexane, after excitation at the maximum absorption wavelength.

×2

(a) (b)

100nm 100nm

Figure 5. Cryo-Scanning electron microscopy of a sample of doped dendrimer (Bengal Rose@dendrimer) in n-hexane (a) and

ethanol (b). From this figure can be derived the different aggregation state depending on the solvent polarity.

Emission Waveelength (nm)

600

550

500

450

400

350

0 4 8

Polarity Index

Figure 6. Fluorescence emission of Congo Red@dendrimer in different solvents: n-hexane (1), carbon tetrachloride (2), tolu-

ene (3), dichloromethane (4), 1-4 dioxane (5), ethanol (6), acetonitrile (7), water (8).

F. MARQUEZ ET AL

deactivation pathway due to the closer proximity be-

tween the lowest excited singlet states.

Experimental evidence of this dynamic equilibrium

observed in dendrimers exposed to different polarity

environments has been obtained from cryo-SEM

(cryo- scanning electron microscopy). Cryo-SEM was

the method of choice for investigating the dendritic

structures in different solvents because the samples

were in solution. This technique can be a particularly

useful method for studying new types and interaction

modes among solvents and dendrimers. This study

was performed on the dye 1-doped dendrimer in

ethanol and n-hexane. Samples were cooled to -170˚C

and subsequently analysed (see Supplementary Infor-

mation for experimental details). Figure 5 displays the

results obtained by cryo-SEM indicating that increas-

ing the polarity (in going from n-hexane to ethanol)

substantially modifies both the molecular dimension

and aggregation state of the doped dendrimers.

Other confined spaces that can affect the guest-host

relationships similarly, in this case through the hardness

of their walls, are the zeolite framework [6].

In fact, it

has been reported that the photophysical properties of

several probe molecules such as naphthalene or anthra-

cene within pure silica zeolites are strongly affected by

the zeolite host [6].

The magnitude of this shifting ap-

pears in theory to be lower than the one attained in this

case for our dye-doped dendrimer. Even more, the ab-

sorption of a guest included in a dendritic box does not

involve the disadvantage of light scattering typical of in-

organic opaque solids, thus leading to much more effi-

cient photochemical and photophysical processes.

To sum up, the ability of the dendrimers to create con-

fined microenvironments in determined experimental

conditions can be taken as an easy way to modify the

emission spectrum of dye molecules trapped in their cav-

ities. This may have important implications from the

technological point of view since dye-doped dendrimers

can serve to enlarge the frequency range of laser dyes

simply by choosing a solvent or a mixture of solvents of

suitable polarity. What is more, the ability of these

dye-doped dendrimers to modify the emission frequency

range simply by changing the medium polarity may have

interesting applications in the development of new su-

pramolecular devices. This is clearly exemplified in

Figure 6, where the fluorescence emission wavelength

of the dye 3-doped dendrimer in different solvents is

plotted. As can be seen there, the fluorescence emission

is clearly correlated with the polarity of the solvents and

this effect may only be justified as due to the confine-

ment effect of the dye.

4. Acknowledgements

Generous financial support from NASA (Grant NAG10-

335) is gratefully acknowledged. Financial support from

US Department of Energy through the Massey Chair

project at University of Turabo is also acknowledged.

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