ARTICLE

Received 7 Jun 2013 | Accepted 15 Jan 2014 | Published 12 Feb 2014

T. Boulier1, M. Bamba2, A. Amo1,3, C. Adrados1, A. Lemaitre3, E. Galopin3, I. Sagnes3, J. Bloch3,C. Ciuti4, E. Giacobino1 & A. Bramati1

The generation of squeezed and entangled light elds is a crucial ingredient for the implementation of quantum information protocols. In this context, semiconductor materials offer a strong potential for the implementation of on-chip devices operating at the quantum level. Here we demonstrate a novel source of continuous variable squeezed light in pillar-shaped semiconductor microcavities in the strong coupling regime. Degenerate polariton four-wave mixing is obtained by exciting the pillar at normal incidence. We observe a bistable behaviour and we demonstrate the generation of squeezing near the turning point of the bistability curve. The conned pillar geometry allows for a larger amount of squeezing than planar microcavities due to the discrete energy levels protected from excess noise. By analysing the noise of the emitted light, we obtain a measured intensity squeezing of 20.3%, inferred to be 35.8% after corrections.

DOI: 10.1038/ncomms4260

Polariton-generated intensity squeezing in semiconductor micropillars

1 Laboratoire Kastler Brossel, Universit Pierre et Marie Curie, Ecole Normale Suprieure and CNRS, UPMC Case 74, 4 place Jussieu, 75252 Paris Cedex 05, France. 2 Department of Physics, Osaka University, 1-1 Machikaneyama, Toyonaka, Osaka 560-0043, Japan. 3 Laboratoire Photonique et Nanostructures, CNRS, Route de Nozay, 91460 Marcoussis, France. 4 Laboratoire Matriaux et Phnomnes Quantique, Universit Paris Diderot et CNRS, Btiment Condorcet, 10 rue Alice Domon et Lonie Duquet, 75205 Paris Cedex 13, France. Correspondence and requests for materials should be addressed to A.B. (email: mailto:[email protected]

Web End [email protected] ).

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While very efcient sources of non-classical light, essentially based on bulk nonlinear crystals, have been developed in the last 20 years, the quest for

integrated quantum sources is a major challenge for the cutting edge research activity in the eld of quantum information technologies.

Successful examples in the discrete variable regime are represented by efcient single and entangled photons sources in semiconductor quantum dots13. Photon antibunching and squeezing were theoretically predicted and experimentally demonstrated in pioneering resonance uorescence experiments47. In strong contrast, despite several theoretical proposals8,9, the continuous variables regime has seen so far only very few experimental achievements1012 of squeezed states of light in semiconductor materials.

Here, for the rst time in this type of systems, we achieve a high degree of intensity squeezing exploiting an effective Kerr effect for microcavity polaritons. Let us note that, due to the giant polariton nonlinearities13, the power range used here (520 mW) is two orders of magnitudes lower than in previous experiments10. These results open the way to the implementation of ultra-low threshold quantum devices integrated in a semiconductor platform.

Exciton-polaritons are half-light half-matter bosonic particles arising from the strong coupling between excitons and photons in semiconductor microcavities14. They exhibit strong nonlinearities due to the Coulomb interactions of their excitonic part, responsible for the rich variety of quantum effects recently unveiled15, ranging from BoseEinstein condensation16 and superuidity17,18 to more complex phenomena such as dark and bright solitons19,20, magnetic monopole-like half-solitons21, half-vortices22 and vortex lattices23.

The great potential of polaritons for non-classical elds generation was recognized very soon after the experimental demonstration of the coherent nonlinear optical response of microcavity polaritons allowing for the observation of parametric amplication and oscillation in such systems2426. Especially interesting is the case of degenerate polariton four-wave mixing in which the strong nonlinearities originating in the polariton polariton interactions allow describing the polariton system as an effective Kerr medium whose refractive index depends on the light intensity12,27,28. Kerr media are well known to be very efcient sources of quadrature-squeezed light. Indeed, quadrature squeezing of about 4% was observed in a planar semiconductor microcavity, by using degenerate polariton four-wave mixing in 2004 (ref. 11). Despite several attempts with specically designed planar microcavity samples, signicant improvements of this rst result were prevented by the excess noise coming from the intrinsic multimode nature of the emission in a planar microcavity, which is characterized by a continuum of polariton modes and is favourable to the coupling with lattice phonons. Very recently, it has been predicted29 that a large amount of squeezing could be achieved by quantizing the in-plane polariton eld modes via a geometric connement (strong localization limit29). This tight connement separates the modes energetically, severely reducing any nonlinear multimode coupling responsible for increased excess noise and reduced quantum effects. In this paper, we apply this method in a controlled way making use of semiconductor micropillars30,31 and we demonstrate up to 20.3% of directly measured squeezing in the amplitude quadrature of the emitted light.

ResultsExperimental conguration. In our set-up, the pillars are fabricated by etching a l GaAs microcavity containing two

GaAsInGaAs quantum wells, resulting in a polariton Rabi splitting of about 4 meV. The cavity nesse is of the order of 700, which gives a 0.1 meV polariton linewidth. Figure 1 shows the energy separation of the polariton modes due to the nite size of the pillar. As shown in Fig. 2a, the cavity mirrors are asymmetric with the bottom Bragg mirror twice thicker than the top one (30 pairs of Al0.1Ga0.9As Al0.95Ga0.05As versus 15 pairs for the top

mirror), optimizing the cavity for experiments in reection conguration. The cavity is wedged in one direction, providing a large choice of cavityexciton detuning by selecting pillars placed in different positions on the chip. We can choose the shape and size of the micropillars in order to engineer the spatial distribution of the conned modes and their energy separation. Figure 2b shows the large square-shaped pillars (width of 20 mm) and small square or round-shaped pillars (width from 6 mm to 2 mm) available on the studied sample.

The pillars are cooled down to 5 K in a cryostat mounted in reection conguration and excited with a CW single-mode Ti:Sa laser tuned to be quasi-resonant with the ground-state level of the lower polariton branch. The laser is frequency locked to a FabryPerot cavity and its intensity is stabilized by means of an electro-optical modulator. The laser was veried to be at the shot noise for frequencies above 1 MHz. The spatial mode is ltered by a ve meters long single-mode optical bre shielded against thermal uctuations. The laser beam is focused by a microscope objective treated with a near-infrared optimized coating and excites the sample at normal incidence. Upstream of the microscope objective, a motorized l2 plate coupled with a polarizing beam splitter (PBS) allows us to nely control the pump power on the sample and a l4 plate placed between the beam splitter and the objective ensures that the light coming on the sample is circularly polarized. With the polarized beam splitter, the l4 plate forms an optical circulator since the light re-emitted from the sample was measured to be 95% circularly polarized, as expected from spin conservation. The light reected from the cavity is thus collected and sent to the detectors.

The shape of the laser spot on the sample is Gaussian with a waist of 5.5 mm, well matched to the round pillars with a diameter of 6 mm. In the studies presented here, we hence use a round micropillar of 6 mm, which ensures an optimal mode matching between its polaritonic ground state and the focalized excitation

1,473 1

0.75

0.45

0.25

0

1,472 1,471 1,470 1,469 1,468

Energy (meV)

1,467 1,466 1,465 1,464 1,463 1,462

5 3.75 2.5 1.25 0k (m1)

1.25

2.5 3.75 5

Figure 1 | Energy modes separation. Dispersion curve for the 6 mm circular pillar used in the experiment ( 5 meV cavity detuning), obtained with a

non-resonant pumping at 1, 550 meV. The lower polariton branch with several spatial modes and the weakly excited upper branch are visible. The modes are energetically separated and squeezing is protected against multimode nonlinear coupling.

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Coherent state

Squeezed state

TiSa laser

PBS 1

/4

Spectrum analyser

Photodiode 1

+

Telescope + spatial filter

/2

/4

/2

Local oscillator

Mirror

Piezoelectric

PBS 2

Photodiode 2

Objective

Removable beam blocker

Micropillar sample in cryostat

Figure 2 | Sample and set-up. (a) Principle of squeezed light production with a pillar-shaped microcavity. The microcavity is made of a pair of quantum wells (white-red-white layers) sandwiched by two Bragg mirrors (alternation of light blue and dark blue layers); the green layer is the substrate. The orange beam represents the pump laser arriving on the sample at normal incidence, slightly blueshifted with respect to the energy of the lower polariton branch. The red beam represents the squeezed light emitted by the squeezed polariton eld present in the microcavity. (b) Image of the sample obtained with scanning electron microscopy. The different shapes and sizes of the pillars are visible. The scale bar corresponds to 100 mm. (c) Scheme of the experimental set-up for the noise detection. The higher squeezing values were measured with the balanced detection set-up, realized by blocking the local oscillator with the beam blocker. The choice of adding ( ) or subtracting ( ) the photodiodes signals determines the measurement: intensity

noise ( ) or shot noise ( ). To measure the noise quadratures of the eld one unblocks the local oscillator and set the mixer to ( ); in this case, the shot

noise is measured by blocking the light reected from the microcavity. PBS: polarizing beam splitter; l2, l4: half-wave, quarter-wave plate.

laser. The re-emitted light is collected by the same microscope objective and sent through a telescope and a spatial lter, allowing us to select only the light coming out of the pillar or some specic region if needed. As shown in Fig. 2c, the sample emission is collected in a set-up allowing performing both balanced and homodyne detections.

For the balanced detection, the collected light is equally split into two parts by a l2 plate associated to a a polarizing beam splitter (PBS 2) and each beam is collected by a photodiode. The high frequency (HF) outputs of the two identical photodiodes (81% quantum efciency, with home-made low-noise electronics) are added or subtracted with a passive circuit, amplied by a low-noise, HF amplier and sent to a spectrum analyser giving us the spectral noise power (thereafter simply called noise). The choice of addition or subtraction allows us to quickly switch between the measurement of the intensity noise (addition mode) or the shot

noise (difference mode). The common mode rejection of the balanced diodes was 45 dB at 7 MHz.

For the homodyne detection, a portion of the pump laser is mixed on PBS 1 with the light emitted by the micropillar with an orthogonal polarization, and acts as local oscillator. In this case, the HF output of the photodiodes are subtracted and the measured quantity gives the noise in the quadrature of the reected eld that is in phase with the local oscillator. The relative phase between the local oscillator and the reected eld is controlled with a piezoelectric-mounted mirror, allowing measuring all quadratures. The shot noise is measured by blocking the light reected from the microcavity.

For the homodyne set-up, it is important to note that the spatial mode of the sample emission can be strongly distorted by the nonlinear interactions and it is no longer Gaussian-shaped at high polariton densities. For this reason, it was found very

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difcult to achieve the mode matching with the local oscillator necessary to have efcient homodyne detection, except in the special case of very low detuning of the pump laser with respect to the ground-state level of the lower polariton branch (since in this case we have a low density of polariton even above threshold). There, proper homodyne detection was achieved (mode matching of 90%). However, such a low detuning is not optimal and thus the squeezing measured with the homodyne detection is lower than at the optimum detuning.

Intensity squeezing measurements at the optimum pump polariton detuning were performed with the balanced set-up. Figure 3a,b shows the intensity noise measured with a balanced detection: a scan at xed pump power in Fig. 3a and a scan of the noise versus pump power in Fig. 3b for a polaritonlaser detuning D 0.19 meV that we have identied as optimal for squeezing. In

Figs 3 and 4, the spectrum analyser was set to zero frequency span and centred at 7 MHz where the signal-to-noise ratio of the detection is maximum, with a sweep time ranging from 1 s to 20 s depending on the type of measurement. The resolution bandwidth (spectral bandwidth of the measurement) was 300 kHz with a 30 Hz video bandwidth (temporal integration over a 30 Hz bandwidth). For the noise dependence on the pump power (Fig. 3b), the motorized plate controlling the excitation power on the pillar is scanned at the same time as the spectrum analyser. We then compare the measured noise to the shot noise. The protocol involves recording the shot noise in difference mode, immediately switching to addition mode to record the intensity noise and then switching back to shot noise measurement (difference mode again) in order to check its stability. The dark noise was recorded after each measurement by recording the electronic noise when the laser beam is blocked. All the presented noise measurements are obtained by normalizing the noise traces by the shot noise after subtraction of the dark noise from both the noise and the shot noise.

A slight energy detuning between the pump laser and the ground state of the lower polariton branch gives rise to optical bistability12 (see Fig. 3c), characteristic in Kerr nonlinear media. According to theoretical predictions, the best squeezing rate is expected in the vicinity of the turning points of the bistability, as in other nonlinear systems32. We therefore chose to sweep the pump power in the vicinity of the bistable region (noise prole measurement, Fig. 3b) to identify the best working points and we performed noise measurements with a xed pump power corresponding to the maximum of intensity squeezing (steady-state measurement, Fig. 3a).

Squeezing was achieved in a reproducible way in repeated experiments on several different neighbouring pillars. According to previous calculations33, the best squeezing is expected for a slightly negative cavityexciton detuning (04d4 1 meV) in

planar microcavities. Here the spatial connement of pillars tends to enhance the polaritonpolariton nonlinear interactions with respect to planar microcavities due to the increase in polariton density. We hence chose to work at larger negative cavityexciton detuning (d E 5 meV) to have a larger photonic fraction, while

preserving strong enough nonlinearities from the excitonic component.

Experimental and theoretical results. The strongest noise reduction at xed pump power was obtained with the laser energy blue-detuned by about D 0.19 meV from the polariton lower

energy level on a 6 mm pillar with a cavityexciton detuning at dE 5 meV. The measured intensity squeezing is 20.31.5%, as

shown in Fig. 3a. After correction for detection efciency (81%) and transmission losses (T 70%), we infer a squeezing in the

outgoing eld of 35.82.6%.

0.4 8 10 12 14 16 18

1.05

1

Normalized noise

(linear scale)

0.95

0.9

0.85

0.8

0.75

0.7 0 0.2 0.4 0.6 0.8 1

Time (s)

30

Increasing pump power Decreasing pump power

25

Normalized noise (dB)

20

15

10

5

0

5 8 10 12 14 16 18

Pump power (mW)

1

0.9

0.8

Reflectance

0.7

0.6

0.5

Pump power (mW)

Figure 3 | Intensity squeezing and bistability. (a) Squeezed intensity noise at xed pump power near the lower turning point (linear scale), on a 6 mm pillar at cavityexciton detuning of 5 meV and a polaritonlaser detuning

of 0.19 meV. The noise data were normalized with a measurement of the shot noise and a measurement of the dark noise, with S(t) (noise(t)

odark(t)4)/(o shotnoise(t)4 odark(t)4), o...4 being the time

average. The measured noise reduction is 20.31.5% ( 1 dB) below the

shot noise limit before corrections, 35.82.6% after. The dashed green line is the average noise and the red line is the shot noise. (b) Intensity noise (spectral noise power, semi-logarithmic scale) as a function of the pump power for the same pillar under the same conditions as in a. The noise increases smoothly towards a peak just before the bistability threshold, then suddenly drops to form a gap where intensity squeezing is observed, with about the same value as in a. Here also the normalized spectral noise is obtained with three measurements (noise, shot noise and dark noise). In red is the curve obtained by increasing the pump power, in blue is the curve obtained by decreasing the pump power and the green line represents the shot noise (normalized to one). The thick black arrow points to where a was recorded. (c) Bistability curve obtained by plotting the reectance versus the pump power, for the same pillar under the same conditions as in a,b. The colour code is the same as in b. Above the thresholds the transmission is increased, hence a sharp reduction on the reectance.

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12

10

Normalized noise (dB)

8

6

4

2

0

0 2

Local oscillator phase

Figure 4 | Homodyne detection. Experimental measurement of squeezing with homodyne detection for a pumppolariton detuning of 0.10 meVon the same pillar as in Fig. 3. The minima were veried to be in the amplitude quadrature. The squeezing obtained from the average between the values at 0, p and 2 p is 16% ( 0.75 dB) before corrections and 25%

after corrections. The reduced value of the squeezing here is mainly due to the non-optimal laserpolariton detuning.

This result was established with a laser intensity lock reducing the low frequency (0100 kHz) intensity variations to 0.2%. The use of the spatial lter was found not to be crucial, as the laser spot was well matched to the size of the six pillars. On the other hand, excessive spatial ltering led to a reduction of the squeezing, as expected from increasing losses. A coupled exciton photon model with pump, losses and Kerr nonlinearity (described in Methods) predicts a squeezing value under these conditions of about 40%, in agreement with the experimental value.

Effect of the pumppolariton detuning. The values of pump power at which the optimal working points occur as well as the specic shape of the bistability curve depend on D. This parameter is also expected to inuence the intensity noise prole and the squeezing value. The noise dependence on the pump power for the same pillar and parameter values as mentioned above is shown in Fig. 3b. Outside of the bistable region there is an excess noise due to thermal exciton reservoir populated by the pump laser. In the vicinity of the bistability thresholds, this noise undergoes amplication or deamplication due to the nonlinear effects. The intensity noise strongly increases below the bistability thresholds then decreases, as observed in other nonlinear systems15,32,33.

At higher values of D, the pump power required to reach the bistability threshold increases and the noise proles are drastically altered. Indeed a bistable behaviour appears above some critical value of D. For rather large D only the lower turning point (reached by decreasing the pump power) is able to produce intensity squeezing. If D is lower than the critical value, strong nonlinear modications of the noise and reectance can be observed despite the lack of bistable behaviour and the noise curves are the same when increasing or decreasing the pump power. These effects were studied in our experiment by repeating the noise measurements at different polaritonlaser detunings and are discussed in the Supplementary Note 1. Supplementary Figs 1 and 2 show, respectively, the reectance and the noise plots obtained for D 0.10 meV

while Supplementary Figs 3 and 4 show, respectively, the reectance and the noise plots obtained for D 0.21 meV and

Supplementary Figs 5 and 6 show the reectance and the noise plots obtained for D 0.30 meV. The optimal detuning for

squeezing that we present here corresponds to the onset of the bistability behaviour where the hysteresis cycle is very narrow (Fig. 3b).

Homodyne detection. To conrm these ndings, we have measured the noise along all the eld quadratures with the homodyne detection and checked that squeezing occurs only in the amplitude quadrature at the bistability turning points. As previously mentioned, for low D the output of the pillar is nearly Gaussian.

In such conditions, we were able to achieve good mode matching between the local oscillator and the spatial mode emitted by the micropillar (about 90%) and implement an efcient homodyne detection. The path difference between the two beams, set to change linearly with time, determines the measured quadrature. The result is presented in Fig. 4 for a laserpolariton detuning of D 0.10 meV. Squeezing is observed at the minima of the curve

showing the characteristic arches. Let us note that the anti-squeezed quadrature (phase quadrature) exhibits a large excess noise of the order of 12 dB due to thermal noise input. The uctuations and irregularities of the noise arches are due to the fact that the interferometric homodyne set-up is more sensitive to mechanical instabilities. A comparison with the intensity measurements set-up allows checking that the squeezed quadrature indeed corresponds to the amplitude quadrature. The observed squeezing with this set-up was of about 16% (25% inferred after corrections).

DiscussionIn conclusion, we have reported an experimental demonstration of strong enhancement of squeezed light generation with conned polaritons in semiconductor micropillars. The best intensity squeezing was inferred to be 35.82.6% below the shot noise limit and was conrmed by measurements with a homodyne detection set-up. Several original optimizations allowed to reach these results. In particular, the special design of the pillars ensures a near-perfect mode matching between the pump and the polariton eld; the discretization of the polariton energy modes allows for a strong reduction of the excess noise coming from phonon coupling. The reduced reectivity of the upper Bragg mirror relative to that of the bottom mirror enhances the emission of light towards the top of the pillar, optimizing the light collection. Finally the relatively low-quality factor of the cavity increases the radiative to non-radiative losses ratio which, together with the choice of a working point with a high photonic fraction, results in a larger squeezing in the emitted light. These results demonstrate the improvement of intensity-squeezed light and lightmatter elds brought by reduced dimensionality in semiconductor microstructures and open the way to the realization of ultra-low threshold integrated sources for the quantum information-processing technology.

Methods

Theoretical model. Owing to the lateral connement of the micropillar, the polariton modes are well identied and we can selectively pump a polariton mode by tuning the spatial and spectral prole of the pumping light. For the theoretical analysis, we simply consider a single-cavity mode with frequency oc and an exciton state with frequency ox. The Hamiltonian of the coupled system (polariton) in the microcavity is:

^

H0 hoc^ay^a hox

^by^b

^by^by^b^b 1 Here, ^a and ^b are the annihilation operators of a photon and an exciton, respectively, and OR is the coupling strength (vacuum Rabi splitting) between the cavity photon and the exciton. The last term represents a third-order nonlinearity

^by^a

hg 2

hOR

2 ^ay^b

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for the excitons with strength g. The polaritons are subject to an effective Kerr effect through it. In addition, considering the photonic and excitonic reservoirs, the quantum Langevin equations for the cavity photons and the excitons are, respectively, derived as follows:

i @^a

@t oc

ik 2

Table 1 | Parameters.

D xp x

polariton (meV) c (meV) r (mW 1)0.14 0.43 0.20.15 0.40 0.30.19 0.89 0.120.26 0.63 0.06

Table of parameters used in the theory, deduced by tting the experimental data of the reectance.

^

a

OR 2

^b i

p ^

k

ain Fpe io t

2

i @

p ^bin 3

Here, k and g are the dissipation rates of the cavity photon and exciton, respectively. ^ain and ^bin are the input operators from photonic and excitonic reservoirs, respectively, and we assume they have a zero average ^ainh i h

^bini 0

^b@t ox

ig

2

^b

OR 2

^ ^by^b^b i

g

(incoherent input). Instead, we explicitly consider an applied coherent pumping with amplitude Fp and frequency op. Then, the inputoutput relation for the photon operators is expressed as:

^ aout ^ain Fpe io t

k

p ^

a 4

From the above Langevin equations, we rst calculate the mean elds of the cavity photon and exciton induced by the coherent pump. Assuming ^a

h i ae io t

and h

^bi be io t, the steady-state mean elds are as follows:

i @

@t a oc op

ik 2

References

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a

OR 2

b i

k

p Fp 0 5

i @

@t b ox op

b

j j2b 0 6

Once the mean elds are determined, the reectance is calculated via the input output relation as follows:

^

aouth i aoute io t Fp

k

p a

e io

ig

2

OR 2

a g b

7

t

R

^

aout h i

j j2 ^

ain Fpe io t

2

p a

2

Fp

2

8

The intensity noise is calculated by the uctuations around the mean eld value. Dening the uctuation operators as d^a ^aeio t a and d

^b

^beio t b, and

linearizing the corresponding equations, the quantum Langevin equations are rewritten as follows:

i @

@t d^a oc op

ik 2

Fp

k

d^a

OR

2

d^b i

p ^

ain 9

k

i @

@t d

^b ox 2g b

j j2 op

d^b

ig

2

OR

2

d^a gb2d

p ^bin 10

From these equations and the inputoutput relation, we can infer the uctuations d^aout ^aouteio t aout of the output photons. The variance of the

output is expressed as follows:

DN

2 ^ay

out^ay

^by i

g

out^aout^aout

D E

^ ayout^aout

D E2

2 aout

j j2 d^ay

outd^aoutD E

2Re a out

outd^aouti

h i

11

2hd^a

Then, the normalized intensity noise is expressed as follows:

DN

2 ^

ay

out^aout D E

2 d^ay

outd^aoutD E

2Re a out aout

j j

d^aoutd^aout h i

" #

2

12

The correlations of the output are calculated from the ones of input operators.

Here, we assume that the correlation of the photonic input as h^ayint^aint0i

^ aint^aint0

h i 0 (extracavity photon vacuum) while the excitonic reservoir has an incoherent population, namely h

^byint

^bint

0i Nthd(t t0) and

h

^bint

^bint

0i 0. We also assume that there is no correlation between the

photonic and excitonic inputs. Nth represents the thermal noise and is chosen to be linear with the pump power (Nth s Wp(mW), with s the proportionality

constant and Wp the pump power).

Parameters. In the calculations, we have used the following values: d oc

ox

5 meV, OR 4 meV and k 0.11 meV. The other parameters have been

estimated by tting experimental data for several values of D, the pumppolariton detuning and are shown in Table 1. From the theoretical results of this simple model, we observe that the excitonic dissipation rate g tends to increase with D.

This can be explained by an increased population in the excitonic reservoir.

This model is able to reproduce correctly the reectance traces obtained in the experiment, and the intensity noise for pump intensities above the bistability threshold. Note that the prediction of the intensity noise for low pump intensities does not reproduce well the experimental data. This is probably due to the fact that our model does not take disorder effects into account. For very low densities, the disorder becomes the dominant effect, so we cannot capture the corresponding noise behaviour adequately.

Supplementary Fig. 7 shows the comparison between the model and the experiment for the intensity noise at D 0.15 meV. The bistability curve of the

reectance and the corresponding intensity noise dependence on the pump power for a pumppolariton detuning of 0.26 meV are shown in Supplementary Fig. 8 and in Supplementary Fig. 9, respectively.

6 NATURE COMMUNICATIONS | 5:3260 | DOI: 10.1038/ncomms4260 | http://www.nature.com/naturecommunications

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NATURE COMMUNICATIONS | DOI: 10.1038/ncomms4260 ARTICLE

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Acknowledgements

This work was partly supported by the FP7 ITN Clermont4 (235114), by the ANR

projects PNANO-07-005 GEMINI and Quandyde (ANR-11-BS10-001), by the French

RENATECH network and the KAKENHI 24-632 grant. The authors are grateful to J. Ph.

Karr and Q. Glorieux for useful discussions.

Author contributions

All authors contributed to all aspects of this work.

Additional information

Supplementary Information accompanies this paper at http://www.nature.com/naturecommunications

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Competing nancial interests: The authors declare no competing nancial interests.

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How to cite this article: Boulier, T. et al. Polariton-generated intensity squeezing in

semiconductor micropillars. Nat. Commun. 5:3260 doi: 10.1038/ncomms4260 (2014).

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