Enhancing the Performance of Random Lasers

Effects of Localised Surface Plasmons and Resonance Energy Transfer

Judith M. Dawes

1,2

, Wan Zakiah Wan Ismail

1,2,3

, Ewa M. Goldys

1,4

and David W. Coutts

1,2

MQ Photonics, Department of Physics and Astronomy, Macquarie University, Balaclava Road, Sydney, 2109, Australia

ARC Centre of Excellence Centre for Ultrahigh-bandwidth Devices for Optical Systems, Sydney 2109, Australia

Faculty of Science and Technology, Islamic Science University of Malaysia, Nilai, 71800, Negeri Sembilan, Malaysia

ARC Centre of Excellence Centre for Nanoscale BioPhotonics, Sydney, 2109, Australia

Keywords: Random Lasers, Localised Surface Plasmons, Nanoparticles.

Abstract: We investigate the effect of different gain media and different scattering media in random lasers. We

demonstrate an increase in the emission intensity and efficiency of random lasing by incorporating gold rather

than dielectric alumina nanoparticles. There is a trade-off between enhancing the random laser performance

due to the localised surface plasmon resonance field effects and reduction in performance due to fluorescence

quenching by the gold nanoparticles. We use fluorescence resonant energy transfer between dye molecules to

extend the wavelength range of emission.

1 INTRODUCTION

Random lasers offer interesting behaviour compared

with standard (resonant cavity-based) lasers as they

incorporate highly scattering materials combined

with optical gain (Wiersma, 2008). Thus the laser

output typically has reduced coherence, and broader

linewidth than for a comparable standard cavity-

based laser (Wan Ismail et al., 2014). However, these

lasers exhibit typical threshold behaviour and

spatially distributed emission, with a relatively broad

angular range of emission. The lasers can be used in

a range of applications including as broadband – low

coherence sources for Optical Coherence

Tomography, and for probing the properties of the

scattering materials themselves (such as in

biosensing). Here, we describe methods to enhance

the emission intensity or reduce the threshold of

random lasers based on dye solutions with metal and

dielectric scattering particles. We employ

combinations of dyes to extend the available range of

emission wavelengths from these systems.

2 EXPERIMENTS

The random laser solutions were prepared in

methanol, using specified concentrations of titania

nanoparticles (average diameter 200 nm, Sigma

Aldrich), alumina nanoparticles (average size of 150

nm, Sigma Aldrich) and gold nanoparticles (average

diameter 60 nm, Ted Pella) (Wan Ismail et al., 2015).

For the random lasers based on fluorescence

resonance energy transfer, titania, (200 nm, 1×10

-3

) is added to a methanol solution of Rhodamine

6G (5×10

-4

to 2×10

-3

M) and Oxazine 17 (5×10

-4

(Sigma Aldrich). Random lasers based on localized

surface plasmon effects incorporated gold

nanoparticles at varying concentrations (from 3 x 10

to 1 x 10

-3

) with methanol solutions of

rhodamine dyes (10

-3

M). The random laser

suspensions were ultrasonically mixed to break up

aggregates immediately before the laser experiments.

For the laser experiments, the suspensions were

placed in a 1 cm quartz cuvette containing a piece of

teflon to suppress back-face reflections.

The pump source for the experiments was a Q-

switched frequency-doubled Nd:YAG laser operating

at 10 Hz pulse repetition rate with 4 ns pulse width.

The front face of the random laser cuvette was

irradiated at an incident angle of 30

to the normal to

the front face with the pump light focussed using a 10

cm focal length lens to produce an excitation area of

1 mm diameter at the cuvette. The emission light at

an angle of 45

to the cuvette’s front face was

collected by a lens and delivered to a fibre-coupled

spectrometer (Ocean Optics USB2000 + UV-VS-ES

160

Dawes, J., Ismail, W., Goldys, E. and Coutts, D.

Enhancing the Performance of Random Lasers - Effects of Localised Surface Plasmons and Resonance Energy Transfer.

DOI: 10.5220/0005744001580161

In Proceedings of the 4th International Conference on Photonics, Optics and Laser Technology (PHOTOPTICS 2016), pages 160-163

ISBN: 978-989-758-174-8

with ~1 nm spectral resolution).

3 RESONANCE ENERGY

TRANSFER

3.1 Extended Operating Wavelength

Range of Random Dye Lasers

Figure 1: The peak emission intensity of Oxazine/

Rh6G/titania random lasers with different dye ratio

combination; (a)1:1 (b)1:2 (c)1:4. The lasing threshold is

observed for the oxazine emission peak when the emission

intensity increases nonlinearly with the pump energy

density.

Using combinations of fluorescent dyes, we can

design effective energy transfer from a donor

molecule to an emitter molecule by ensuring strong

spectral overlap of the emitter absorption spectrum

with the emission spectrum of the donor (Cerdan et

al., 2012). This can extend the operational

wavelength of a laser for example (Alee et al., 2013).

We have investigated various dye combinations and

concentrations to explore the efficiency of the energy

transfer. Here we demonstrate near-IR emission

beyond 700 nm from a 532 nm pump laser via

resonant energy transfer from Rhodamine 6G to

Oxazine dye, as an example.

Random lasing emission beyond 700 nm is

achieved by combining two dyes with scatterers.

Oxazine dye is a less efficient dye for random lasers

excited with 532 nm green light but with the addition

of Rhodamine 6G (Rh 6G), Oxazine can reach laser

threshold. We obtain the most efficient transfer in the

weakly scattering regime (with a scattering length of

order 1 mm).

Figure 1 shows laser operation for a series of

random lasers with Rhodamine 6G (5 x 10

-4

to 2×10

M) and oxazine (5×10

-4

M) incorporating titania

nanoparticles (1×10

cm) as scatterers. The dye

mixtures are in the ratios: 1:1, 1:2 and 1:4 for a

mixture of Oxazine: Rh 6G. Figure 2 shows emission

spectra from the lasers below and above laser

threshold.

Figure 1 shows that the random laser threshold for

Oxazine emission reduces gradually when the dye

ratio increases. Increasing the concentration of Rh 6G

increases the Oxazine lasing threshold due to the

competition between Rh 6G emission and Oxazine

emission. By providing high gain to the Rh 6G, the

laser is driven to emit at the Rh 6G emission

wavelength and this disrupts the energy transfer

process to the Oxazine, leading to an increased lasing

threshold.

4 LOCALISED SURFACE

PLASMON RESONANCE

4.1 Random Lasers based on

Rhodamine / Gold Compared with

Rhodamine / Alumina

When metallic (gold) nanoparticles are added to

random lasers incorporating Rhodamine 640 or

Rhodamine 6G dyes, we observe a combination of

resonance energy transfer with localized field

enhancement which leads to increased emission

a) 1:1OxazinetoRh6G

)1:2OxazinetoRh6G

c)1:4OxazinetoRh6G

Oxazineemissionpeak

Rh6Gemissionpeak

Enhancing the Performance of Random Lasers - Effects of Localised Surface Plasmons and Resonance Energy Transfer

161

intensity and decreased laser threshold (Sen et al.,

2007). However if there is strong spectral overlap of

the gold particles with the dye, excitation of the gold

nanoparticles quenches the dye fluorescence,

reducing the emission intensity. This may be

overcome using specific nanoparticles or dye

combinations (Xiaoyu et al., 2013).

Figure 2: The emission spectra of Rh 6G (2×10

-3

M) with

oxazine (5×10

-4

M) and titania (1×10

cm) random lasers

below (3 mJ/cm

) and above (8 mJ/cm

) laser threshold.

Table 1 shows the lasing thresholds for Rh 640 / gold

and Rh 6G / gold random lasers, indicating that the

lowest lasing threshold occurs for 8×10

-3

of gold

nanoparticle concentration in both cases. The

threshold increases in the weakly scattering regime

for gold nanoparticle concentrations below this

concentration, and also increases in the diffusive

scattering regime above this concentration. For

similar particle concentrations (3×10

-3

), the

lasing threshold of the Rh 640 / gold random lasers is

~18 mJ/cm

, considerably lower than that for Rh 640

/ alumina random lasers (~43 mJ/cm

), shown in

Table 2. Likewise, the lasing threshold of the Rh 6G

/ gold random lasers (~21 mJ/cm

) is also

considerably lower than that for Rh6G / alumina

random lasers (~40 mJ/cm

The decrease of the lasing threshold in these

Rhodamine random lasers with the addition of gold

nanoparticles is attributed to enhanced fluorescence

from localised surface plasmon effects. Emission

from both the Rhodamine dyes is absorbed by the

gold nanoparticles. This leads to a concentration of

the local electric field induced by excited surface

plasmons at the gold nanoparticle surfaces. The

excitation at the particle surface gives a concentrated

local electric field with increased absorption by the

dye and thus more amplification. The increase in the

lasing threshold for higher gold nanoparticle

concentrations is attributed to fluorescence

quenching of the dye molecules due to non-radiative

surface energy transfer from the excited dye to gold

nanoparticles.

The scattering mean free path, l

s at a pump

wavelength of 530 nm for random dye lasers with

alumina ranges from 0.35 mm, in the diffusive

scattering regime (sample size > l

s > λ) to 11.6 mm,

in the weakly scattering regime (l

s ⩾ sample size).

The lasing threshold decreases when the scattering

mean free path is decreased. In the Rh 640 / alumina

and Rh 6G / alumina random lasers, the lasing

threshold reduces with increasing alumina

concentration and there is no additional loss for high

alumina concentrations.

Table 1: Lasing threshold for Rh 640 and Rh 6G (10

-3

random lasers with various concentrations of gold

nanoparticles.

Gold

nanoparticle

concentration

(cm

-3

)

Rh 640 Laser

threshold

mJ/cm

Rh 6G Laser

threshold

mJ/cm

3x 10

27 28

3x10

18 21

8x10

13 15

3x10

21 28

1x10

26 32

Table 2: Lasing threshold for Rh 640 and Rh 6G (10

-3

random lasers with various concentrations of alumina

nanoparticles.

Alumina

nanoparticle

concentration

(cm

-3

)

Rh 640 Laser

threshold

mJ/cm

Rh 6G Laser

threshold

mJ/cm

3x 10

No lasing No lasing

3x10

43 40

3x10

35 33

1x10

31 24

In the weakly scattering and diffusive scattering

regimes, the scattering length l

s for a wavelength of

530 nm for random dye lasers with gold nanoparticles

varies from 0.42 mm to 111.1 mm, respectively. This

is roughly as large as the size of the lasing region.

5 CONCLUSIONS

We demonstrate that random laser performance can

be improved with addition of moderate

concentrations of metallic nanoparticles (substituting

for dielectric nanoparticle scatterers), and by

selecting appropriate dyes for efficient radiative

energy transfer. We examine the effect of localised

surface plasmons and Fluorescence Resonance

500 550 600 650 700 750 800

0.0

0.2

0.4

0.6

0.8

1.0

Normalized emission intensity

Wavelength(nm)

Below threshold

Above threshold

PHOTOPTICS 2016 - 4th International Conference on Photonics, Optics and Laser Technology

162

Energy Transfer (FRET) on random laser

performance incorporating Rhodamine dyes with

alternative dyes and metallic nanoparticles.

ACKNOWLEDGEMENTS

Funding and support by the authors’ university and

the Australian Research Council Centres of

Excellence Program CE140100003 and CE11E0091

is gratefully acknowledged.

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