Abstract
Although the phenomenon of Bose–Einstein condensation^{1} is a purely statistical effect that also appears in an ideal gas, the physics of Bose–Einstein condensates (BECs) of dilute gases is considerably enriched by the presence of interactions among the atoms. In usual experiments with BECs, the only relevant interaction is the isotropic and shortrange contact interaction, which is described by a single parameter, the scattering length a. In contrast, the dipole–dipole interaction between particles possessing an electric or magnetic dipole moment is of longrange character and anisotropic, which gives rise to new phenomena^{2,3}. Most prominently, the stability of a dipolar BEC depends not only on the value of the scattering length, a, but also strongly on the geometry of the external trapping potential^{4,5,6,7}. Here, we report on the experimental investigation of the stability of a dipolar BEC of ^{52}Cr as a function of the scattering length and the trap aspect ratio. We find good agreement with a universal stability threshold arising from a simple theoretical model. Using a pancakeshaped trap with the dipoles oriented along the short axis of the trap, we are able to tune the scattering length to zero, stabilizing a purely dipolar quantum gas.
Similar content being viewed by others
Main
In the case of a homogeneous Bose–Einstein condensate (BEC) with pure contact interaction, the existence of a stable ground state depends on the modulus and sign of the interaction. For repulsive interaction (a>0), the BEC is stable, whereas for attractive interaction (a<0), the BEC is unstable. This instability can be prevented by an external trapping potential. The tendency of the gas to shrink towards the centre of the trap is in that case counteracted by the repulsive quantum pressure arising from the Heisenberg uncertainty relation. Detailed analysis^{8} shows that in a harmonic trap with mean frequency , a condensate is stable as long as the number of atoms N stays below a critical value N_{crit} given by
where is the harmonic oscillator length and k is a constant of the order of 1/2. This scaling has been experimentally checked in ref. 9 in a BEC of ^{85}Rb. The dynamics of condensates for N≥N_{crit} has been the subject of several experiments with condensates of ^{7}Li (refs 10, 11) and ^{85}Rb (ref. 12). In refs 13, 14, the collapse of a Bose–Fermi mixture of ^{87}Rb and ^{40}K was investigated. Some aspects of the dynamics such as the soliton train formation in ^{7}Li (ref. 15) and ^{85}Rb (ref. 16) remain the subject of ongoing research.
Being anisotropic and long range, the dipole–dipole interaction (DDI) differs significantly from the contact interaction, which changes the stability conditions in a system with DDI present. Considering a purely dipolar condensate with homogeneous density polarized by an external field, it is found that owing to the anisotropy of the DDI, the BEC is unstable, independent of how small the dipole moment is^{17}. As in the pure contact case, a trap helps to stabilize the system. In the dipolar case, however, it is not only the quantum pressure that prevents the collapse but also the anisotropy of the density distribution imprinted by the trap.
Consider a cylindrically symmetric harmonic trap
with the dipoles oriented along z, and r being the distance from the symmetry axis. As can be intuitively understood from Fig. 1a, in a pancakeshaped trap (aspect ratio λ=ω_{z}/ω_{r}>1), the dipoles predominantly repel each other and the BEC is stable. In contrast, a cigarshaped trap (λ<1, Fig. 1b) leads to mainly attractive forces and hence to a dipolar collapse. Following this simple argument, we expect that in the prolate case a positive scattering length a is needed to stabilize the BEC, whereas in the oblate case, we can even afford a slightly negative a. The dependence of the stability of a dipolar BEC on the trap aspect ratio λ and scattering length a has been extensively studied theoretically^{4,5,6,7}, and is experimentally investigated here.
Our measurements are carried out with a BEC of ^{52}Cr (ref. 18), which is so far the only experimentally accessible quantum gas with observable DDI^{19,20}. To compare contact and dipolar interactions, we introduce a length scale characterizing the magnetic DDI
The numerical prefactor in a_{dd} is chosen such that a homogeneous condensate becomes unstable to local density perturbations for a≤a_{dd} (ref. 21). As chromium has a magnetic dipole moment of μ=6μ_{B} (μ_{B} is the Bohr magneton), a_{dd}≃15a_{0}, where a_{0} is the Bohr radius. Far from Feshbach resonances, a takes its background value a_{bg}≃100a_{0} (ref. 22) and the BEC is stable for any λ. To explore the unstable regime, we thus reduce the scattering length a, which in the vicinity of a Feshbach resonance scales as
with the applied magnetic field B.
To carry out the measurements, we produce a BEC of approximately 25,000 atoms at a magnetic field that is about 10 G above the broadest Feshbach resonance where the scattering length is approximately 85a_{0} and the BEC is stable. Once the BEC is obtained^{20,23}, we adiabatically shape the trapping potential to the desired aspect ratio λ. To be able to vary λ over a wide range, we generate the trapping potential by a crossed optical dipole trap (ODT) and a superimposed onedimensional optical lattice along the z direction (see Fig. 1c and Methods section).
We observe two effects when approaching the zerocrossing of the scattering length: the BEC shrinks in both directions owing to the decreasing scattering length and the ellipticity of the cloud changes as a manifestation of the enhanced dipolar effects^{20}. Finally, when we decrease the scattering length below some critical value a_{crit}, the BEC atom number (determined from a bimodal fit^{24} of the timeofflight absorption images) abruptly decreases (Fig. 2a,b). The disappearance of the BEC around the instability point is shown in Fig. 2c. Although slightly above a_{crit}, we still see an almost pure BEC, for a≃a_{crit} the density shows a bimodal distribution (an anisotropic, dense central peak surrounded by an isotropic gaussian cloud). Just below a_{crit}, the BEC collapses and the density distribution becomes a unimodal, isotropic gaussian. Note that we do not observe the formation of soliton trains as in refs 15, 16. This can be attributed to the fact that as our trap is much tighter than in those references, the initial size of our BEC is smaller than any single soliton observed in refs 15, 16.
The critical scattering length a_{crit} where the condensate vanishes depends strongly on the trap aspect ratio λ. For an isotropic trap (Fig. 2a), the collapse occurs at a≃15a_{0}, whereas the pancakeshaped trap (Fig. 2b) can even stabilize a purely dipolar BEC (a≃0). We repeated this experiment for six different traps (see Table 1), thereby covering a range of two orders of magnitude in the trap aspect ratio λ. To exclude threebody loss processes causing the abrupt decrease in the BEC atom number, we measured the lifetime of the BEC for the different traps just above a_{crit} and found the same lifetime (∼10 ms) for the different scattering lengths.
By fitting to the observed BEC atom numbers (Fig. 2a,b) the threshold function
where N_{0}, a_{crit} and β are fitting parameters, we find the critical scattering length a_{crit}. The simple functional form (2) was empirically chosen as it accounts for the fast decreasing BEC atom number at a≃a_{crit} and for the slow decrease for a≫a_{crit}. The exponent β describing the steepness of the collapse was found to be β≃0.2 for all traps. The values of a_{crit} that are plotted in Fig. 3a mark the experimentally obtained stability threshold of a ^{52}Cr BEC in the plane (λ,a). We observe a clear shift towards smaller a as λ increases. For the most oblate trap (λ=10), we can reduce the scattering length to zero and hence access the purely dipolar regime experimentally.
To get a more quantitative insight into the collapse threshold a_{crit}(λ), we numerically determine the critical scattering length (green curve in Fig. 3a). For this, we use a variational method to minimize the Gross–Pitaevskii energy functional^{1}
where
is the interaction energy of two aligned magnetic dipoles μ, with r being the relative position of the dipoles and θ the angle between r and the direction z of polarization.
Similar to the work presented in refs 4, 5, 6 and 25, we use a cylindrically symmetric gaussian ansatz to evaluate the energy functional (3) with the radial and axial widths σ_{r} and σ_{z} as variational parameters (see the Methods section). To obtain a_{crit}, we lower the scattering length until the energy landscape E(σ_{r},σ_{z}) does not contain any minimum for finite σ_{r} and σ_{z} any more (Fig. 3b–e). Starting with large values a>a_{dd}, we find that E(σ_{r},σ_{z}) supports a global minimum for finite σ_{r} and σ_{z} independently of λ and thus the BEC is stable (Fig. 3b). Going below a∼a_{dd}, the absolute ground state is a collapsed infinitely thin cigarshaped BEC (σ_{r}→0) and the possible existence of a further local minimum (corresponding to a metastable state) is determined by the trap aspect ratio λ (see Fig. 3c, where a_{dd}>a>a_{crit} and Fig. 3d, where a=a_{crit}). Finally, below a∼−2a_{dd} (Fig. 3e), the local minimum vanishes for any λ and the BEC is always unstable^{6,7}.
In spite of the simplicity of our model, we find good agreement between experiment and theory (Fig. 3a). We checked that the different atom numbers and mean trap frequencies that we find for the six traps modify the green curve by much less than the error bars.
The behaviour of the critical scattering length a_{crit} as a function of the aspect ratio λ can be understood considering the limit N a_{dd}/a_{ho}≫1, which is satisfied by our average experimental value of N a_{dd}/a_{ho}≃23. Owing to their linear Nscaling, the kinetic energy and the potential energy (equations (5) and (6) in the Methods section) can be neglected and the total energy E(σ_{r},σ_{z}) is dominated by the interaction term
The function f (ref. 25) of the cloud aspect ratio κ=σ_{r}/σ_{z} arises from the DDI and is discussed in the Methods section.
In this regime, where the stability is solely governed by the competition between the contact and DDI, the critical scattering length (grey curve in Fig. 3a) is implicitly given by
The asymptotic behaviour of the theory curve now becomes apparent: an extremely prolate (oblate) trap forces the cloud shape to also be extremely prolate (oblate) and f takes its extremal value 1 (−2). Hence, we find the asymptotic values a_{crit}=a_{dd} for λ→0 and a_{crit}=−2a_{dd} for . Another particular point is a_{crit}=0, marking the aspect ratio λ_{c} needed to stabilize a purely dipolar BEC. More precisely, as f(1)=0, we search for the trap in which the ground state of a purely dipolar BEC is isotropic. As the DDI tends to elongate the BEC along the z direction and shrink it radially^{26}, it is clear that the desired trap is oblate. Using our model we obtain the criterion λ>λ_{c}≈5.2 for a purely dipolar BEC to be stable, a result that agrees well with the values found in refs 2, 4, 5, 6, 7.
The grey curve in Fig. 3a that we obtain by numerically solving equation (4) shows a universal behaviour in the sense that in the largeN limit a_{crit}(λ) does not depend anymore on the absolute values of the trap frequencies and N. This fact clearly distinguishes the dipolar collapse from the pure contact case (red curve in Fig. 3a), where the λdependence, which is already weak for finite N (ref. 27), completely vanishes in the limit of large N as the stability criterion reads a_{crit}(λ)=0 (see equation (1) and red curve in Fig. 3a). Furthermore, the instability threshold obtained here applies for any dipolar system in a harmonic potential, such as, for example, heteronuclear molecules, where the only difference is the specific value of a_{dd}.
In summary, we experimentally mapped the stability diagram of a dipolar BEC. The dependence on scattering length and trap aspect ratio agrees well with a simple model based on the minimization of the energy of a gaussian ansatz. By using a pancakeshaped trap, we were able to enter the regime of purely dipolar quantum gases. Although the lifetime of the purely dipolar BEC is relatively short (∼10 ms), this work opens up the route to new and exciting physics^{2}. A clear subject for future studies is the dynamics of the dipolar collapse, which might show anisotropic features. Another remarkable property predicted to appear in a dipolar BEC contained in a pancakeshaped trap is the existence of a roton minimum in its Bogoliubov spectrum^{21}. Furthermore, close to the collapse threshold, the existence of structured ground states is predicted^{28,29}, a precursor for the supersolid phase^{30} that is expected to appear in dipolar BECs in threedimensional optical lattices. Finally, a field that has gained increasing interest in the recent past is the study of unusual vortex lattice patterns in rotating dipolar BECs^{31,32}.
Methods
Experimental setup and procedure
To be able to vary λ over a wide range, the trapping potential is generated by a crossed ODT^{20,23} and a further optical lattice (Fig. 1c). The two lattice beams (wavelength λ_{latt}=1,064 nm, waist w_{latt}=110 μm, maximum power per beam P_{latt}=5 W) propagate in the x–z plane under a small angle of ϑ/2=4^{∘} with respect to the x axis. This configuration creates a standing wave along the z axis with a spacing d=λ_{latt}/[2sin(ϑ/2)]=7.6 μm. Owing to the large spacing of the lattice and the small size of the BEC (Thomas–Fermi diameter 2R_{z}^{TF}≃6 μm), we load at most two sites when ramping up the optical lattice. The resulting change in the atom number (at most dividing by 2) changes the theoretical value of a_{crit} by less than a_{0}, which is below the size of our experimental error bars. Tunnelling processes are completely negligible on the timescale of our experiments.
By varying the powers in the beams, we are able to provide nearly cylindrically symmetric traps, with aspect ratios λ between ∼1/10 and ∼10, while keeping the average trap frequency approximately constant. More extreme aspect ratios are not used as for extreme oblate (prolate) traps the radial (axial) confinement becomes too weak to hold the atoms against gravity and remaining magnetic field gradients. The properties of the six traps that were used in the experiment are listed in Table 1. The cylindrical symmetry of the oblate traps in the x–y direction is given by the fact that ω_{x} and ω_{y} are mainly determined by the horizontal ODT beam, whereas ω_{z} is given by the lattice and the vertical beam is not used. For prolate traps, ω_{x} and ω_{y} are again mainly given by the horizontal ODT beam, whereas the vertical beam determines ω_{z} and the lattice is not used. For all traps, except trap 3, we find 0.94<ω_{x}/ω_{y}<1.04. For trap 3, the critical scattering length a_{crit} has been calculated using a gaussian ansatz with the three widths σ_{x,y,z} as variational parameters. The obtained value deviates by less than a_{0} from the value found with the cylindrically symmetric ansatz.
After the BEC is obtained by forced evaporation in the ODT, the trapping potential is shaped in 25 ms to the desired aspect ratio λ. We then ramp the magnetic field within 10 ms to adjust the value of the scattering length. To tune a accurately, we use the broadest of the resonances in ^{52}Cr (ref. 22), which is located at B_{0}≃589 G and has a width of ΔB≃1.5 G (ref. 20). The current providing the magnetic field is actively stabilized with a remaining noise of less than 1×10^{−5} r.m.s., which results in a resolution of Δa∼a_{0} around the zero crossing of the scattering length. After a further holding time of 2 ms, we finally switch off the trap and take an absorption image along the x axis, after a timeofflight of 5 ms. The BEC atom number N and radii R_{y,z} are obtained by fitting the density profile using a bimodal distribution^{23}. The calibration between scattering length and magnetic field is done by solving the hydrodynamic equations for the scattering length a with known N and R_{y,z} (refs 20, 26).
Calculation of the critical scattering length
To obtain an estimate of a_{crit}, we calculate the energy E(σ_{r},σ_{z}) (3) of the cylindrically symmetric gaussian wave function^{4,5,6,25}
with σ_{r} and σ_{z} as variational parameters. Using this ansatz, where , the contributions to the total energy are^{5,6} the zeropoint fluctuations
the potential energy
and the meanfield interaction energy
with
The function f(κ) is a monotonically decreasing function of the condensate aspect ratio κ=σ_{r}/σ_{z} with the asymptotic values f(0)=1 and , arising from the nonlocal term in equation (3) (ref. 25). It vanishes for κ=1, implying that for an isotropic density distribution the magnetic DDI does not contribute to the total energy. As the interaction term (7) scales as N^{2}, it overrules the other terms in the limit N a_{dd}/a_{ho}≫1.
References
Dalfovo, F., Giorgini, S., Pitaevskii, L. P. & Stringari, S. Theory of Bose–Einstein condensation in trapped gases. Rev. Mod. Phys. 71, 463–512 (1999).
Baranov, M., Dobrek, L., Góral, K., Santos, L. & Lewenstein, M. Ultracold dipolar gases—a challenge for experiments and theory. Phys. Scr. T 102, 74–81 (2002).
Menotti, C. & Lewenstein, M. Ultracold dipolar gases. Preprint at <http://arxiv.org/abs/0711.3406> (2007).
Santos, L., Shlyapnikov, G. V., Zoller, P. & Lewenstein, M. Bose–Einstein condensation in trapped dipolar gases. Phys. Rev. Lett. 85, 1791–1794 (2000).
Góral, K. & Santos, L. Ground state and elementary excitations of single and binary Bose–Einstein condensates of trapped dipolar gases. Phys. Rev. A 66, 023613 (2002).
Yi, S. & You, L. Trapped condensates of atoms with dipole interactions. Phys. Rev. A 63, 053607 (2001).
Eberlein, C., Giovanazzi, S. & O’Dell, D. H. J. Exact solution of the Thomas–Fermi equation for a trapped Bose–Einstein condensate with dipole–dipole interactions. Phys. Rev. A 71, 033618 (2005).
Ruprecht, P. A., Holland, M. J., Burnett, K. & Edwards, M. Timedependent solution of the nonlinear Schrödinger equation for Bosecondensed trapped neutral atoms. Phys. Rev. A 51, 4704–4711 (1995).
Roberts, J. L. et al. Controlled collapse of a Bose–Einstein condensate. Phys. Rev. Lett. 86, 4211–4214 (2001).
Sackett, C. A., Gerton, J. M., Welling, M. & Hulet, R. G. Measurements of collective collapse in a Bose–Einstein condensate with attractive interactions. Phys. Rev. Lett. 82, 876–879 (1999).
Gerton, J. M., Strekalov, D., Prodan, I. & Hulet, R. G. Direct observation of growth and collapse of a Bose–Einstein condensate with attractive interactions. Nature 408, 692–695 (2000).
Donley, E. A. et al. Dynamics of collapsing and exploding Bose–Einstein condensates. Nature 412, 295–299 (2001).
Modugno, G. et al. Collapse of a degenerate Fermi gas. Science 297, 2240–2243 (2002).
Ospelkaus, C., Ospelkaus, S., Sengstock, K. & Bongs, K. Interactiondriven dynamics of ^{40}K/^{87}Rb Fermi–Bose gas mixtures in the large particle number limit. Phys. Rev. Lett. 96, 020401 (2006).
Strecker, K. E., Partridge, G. B., Truscott, A. G. & Hulet, R. G. Formation and propagation of matterwave soliton trains. Nature 417, 150–153 (2002).
Cornish, S. L., Thompson, S. T. & Wieman, C. E. Formation of bright matterwave solitons during the collapse of attractive Bose–Einstein condensates. Phys. Rev. Lett. 96, 170401 (2006).
Góral, K., Rza¸żewski, K. & Pfau, T. Bose–Einstein condensation with magnetic dipole–dipole forces. Phys. Rev. A 61, 051601 (2000).
Griesmaier, A., Werner, J., Hensler, S., Stuhler, J. & Pfau, T. Bose–Einstein condensation of chromium. Phys. Rev. Lett. 94, 160401 (2005).
Stuhler, J. et al. Observation of dipole–dipole interaction in a degenerate quantum gas. Phys. Rev. Lett. 95, 150406 (2005).
Lahaye, T. et al. Strong dipolar effects in a quantum ferrofluid. Nature 448, 672–675 (2007).
Santos, L., Shlyapnikov, G. V. & Lewenstein, M. Rotonmaxon spectrum and stability of trapped dipolar Bose–Einstein condensates. Phys. Rev. Lett. 90, 250403 (2003).
Werner, J. et al. Observation of Feshbach resonances in an ultracold gas of ^{52}Cr. Phys. Rev. Lett. 94, 183201 (2005).
Griesmaier, A. Generation of a dipolar Bose Einstein condensate. J. Phys. B 40, R91 (2007).
Ketterle, W., Durfee, D. S. & StamperKurn, D. M. in Bose–Einstein Condensation in Atomic Gases (eds Inguscio, M., Stringari, S. & Wieman, C. E.) 67–176 (Proceedings of the International School of Physics Enrico Fermi, Course CXL, IOS Press, Amsterdam, 1999).
Giovanazzi, S., Görlitz, A. & Pfau, T. Ballistic expansion of a dipolar condensate. J. Opt. B 5, 208–211 (2003).
Giovanazzi, S. et al. Expansion dynamics of a dipolar Bose–Einstein condensate. Phys. Rev. A 74, 013621 (2006).
Gammal, A., Frederico, T. & Tomio, L. Critical number of atoms for attractive Bose–Einstein condensates with cylindrically symmetrical traps. Phys. Rev. A 64, 055602 (2001).
Ronen, S., Bortolotti, D. C. E. & Bohn, J. L. Radial and angular rotons in trapped dipolar gases. Phys. Rev. Lett. 98, 030406 (2007).
Dutta, O. & Meystre, P. Groundstate structure and stability of dipolar condensates in anisotropic traps. Phys. Rev. A 75, 053604 (2007).
Góral, K., Santos, L. & Lewenstein, M. Quantum phases of dipolar bosons in optical lattices. Phys. Rev. Lett. 88, 170406 (2002).
Cooper, N. R., Rezayi, E. H. & Simon, S. H. Vortex lattices in rotating atomic Bose gases with dipolar interactions. Phys. Rev. Lett. 95, 200402 (2005).
Zhang, J. & Zhai, H. Vortex lattices in planar Bose–Einstein condensates with dipolar interactions. Phys. Rev. Lett. 95, 200403 (2005).
Acknowledgements
We would like to thank L. Santos, G. V. Shlyapnikov and H.P. Büchler for stimulating discussions and M. Fattori for his contributions in earlier stages of the experiment. We acknowledge financial support by the German Science Foundation (SFB/TR 21 and SPP 1116) and the EU (MarieCurie fellowship contract MEIFCT2006038959 to T.L.).
Author information
Authors and Affiliations
Contributions
T.K., T.L., J.M. and B.F. carried out the experimental work and data analysis, T.K. and T.L. did the calculations on the theoretical model and A.G. and T.P. were responsible for project planning.
Corresponding author
Rights and permissions
About this article
Cite this article
Koch, T., Lahaye, T., Metz, J. et al. Stabilization of a purely dipolar quantum gas against collapse. Nature Phys 4, 218–222 (2008). https://doi.org/10.1038/nphys887
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/nphys887
This article is cited by

Bloch oscillations and matterwave localization of a dipolar quantum gas in a onedimensional lattice
Communications Physics (2022)

Bose—Einstein condensates with tunable spin—orbit coupling in the twodimensional harmonic potential: The groundstate phases, stability phase diagram and collapse dynamics
Frontiers of Physics (2022)

Frontiers in multidimensional selftrapping of nonlinear fields and matter
Nature Reviews Physics (2019)

Control of tunneling in an atomtronic switching device
Communications Physics (2018)

The phase diagram and stability of trapped Ddimensional spinorbit coupled BoseEinstein condensate
Scientific Reports (2017)