You-Qi Lu of Chongqing University and colleagues have observed topological superradiant phases in a quantum Rabi array, revealing a new paradigm exhibiting dispersive edge modes and superradiance-enhanced excitations. The team overcame limitations hindering topology in strongly coupled light-matter systems, previously preventing band-gap closure. Tuning light-atom coupling induces new topological superradiant electric and magnetic phases, displaying chiral edge-mode excitation at opposite boundaries, creating a tunable platform for topological quantum optics.
They have unveiled a new method to manipulate light and matter, generating unusual superradiant phases beyond conventional understanding. Controlling the interaction between light and atoms generates intensified, directional light emission specifically at the edges of a material, differing from previously known models like the Su-Schrieffer-Heeger configuration. You-Qi Lu and colleagues have demonstrated a novel approach to manipulating light and matter, creating topological superradiant phases within a quantum Rabi array, which functions as a carefully arranged set of atoms interacting with light, similar to a miniature, programmable light-harvesting system.
The team overcame a key obstacle preventing topology in strongly coupled light-matter systems, specifically the inability to close the band gap necessary for topological states to emerge. By tuning the interaction between light and atoms, they induced new electrical and magnetic phases exhibiting chiral edge-mode excitation, where light waves travel along the edges of the material in a single direction. This establishes a tunable platform for topological quantum optics, though the precise conditions required to achieve these phases and the potential for practical applications remain open questions.
Enhanced chiral edge states via topological superradiance in a quantum Rabi array
A 50-fold amplification of edge state excitations, exceeding that of conventional topological phases, has been achieved, marking a significant advance in light-matter interaction control. This enhancement originates from the realisation of topological superradiant phases within a quantum Rabi array, a system formerly hindered by particle-nonconserving interactions that suppressed strong topological behaviour. The team overcame these limitations by precisely tuning light-atom coupling, inducing novel electric and magnetic phases.
Employing a photonic analogue of the Su-Schrieffer-Heeger model, they engineered a platform exhibiting chiral edge-mode excitation, where light waves propagate unidirectionally along material boundaries, a feature absent in prior systems. Manipulation of light-atom coupling within the quantum Rabi array generates these novel topological superradiant phases, extending beyond the capabilities of conventional topological systems. Adjusting these interactions carefully induced both electric and magnetic phases, each exhibiting chiral edge-mode excitation. Observation of a topological superradiant phase transition was confirmed by a local order parameter and a global topological invariant, signalling a shift from a normal phase to this electromagnetically active state. Ground state energy minimums shift according to coupling strengths, defining distinct superradiant phases, magnetic, electric, and electromagnetic, verified through energy spectrum calculations and the Zak phase, which revealed a change from zero to pi for specific parameter settings.
Engineering topological phases via a quantum Rabi array and Su-Schrieffer-Heeger analogue
A quantum Rabi array, a carefully arranged set of atoms interacting with light, functions similarly to a miniature, programmable light-harvesting system, and was employed to engineer a new light-matter topology. This array provides precise control over the coupling between light and matter, crucial for manipulating energy flow and creating the observed topological phases. Unlike previous approaches, this configuration enabled strong interactions without disrupting the conditions necessary for topological behaviour.
By configuring the array with a photonic analogue of the Su-Schrieffer-Heeger model, a well-known blueprint for creating topological states in materials, resembling a repeating pattern of building blocks with specific asymmetry, the team induced a unique closure of a superradiance-induced band gap. This approach offers greater control over light-matter coupling than previous methods, demonstrating a potential platform for topological quantum optics and enabling strong interactions without disrupting topological behaviour. The ability to finely tune these interactions opens possibilities for designing new quantum optical devices, surpassing conventional designs.
Chiral light emission via topological superradiance advances quantum control
Scientists at Chongqing University have engineered a new method for controlling light and matter, potentially enabling stronger and more efficient quantum devices. This advance relies on carefully balancing the interaction between light and atoms, a delicate process vulnerable to disruption; imperfections or environmental ‘noise’ could destabilise the newly created topological phases. Despite this acknowledged susceptibility to external disturbances, this demonstration of controlled light-matter interactions represents a key step forward.
The creation of novel ‘topological superradiant’ phases, where light and matter combine uniquely to accelerate light emission, offers a pathway towards more stable quantum technologies, exhibiting enhanced light excitation and chiral behaviour, meaning light travels preferentially in one direction. This is vital for building robust components for quantum computers and advanced lasers. The Chongqing University team has demonstrated a new configuration for controlling both light and matter, realising topological superradiant phases within a quantum Rabi array, which acts as a programmable system for manipulating interactions between photons and atoms. This achievement bypasses previous restrictions preventing the creation of topology in strongly coupled light-matter systems, offering a pathway towards new quantum optical devices. The array’s programmability allows for exploration of a wider range of light-matter interactions and topological states.
The researchers successfully demonstrated a novel topological superradiant phase transition within a photonic quantum Rabi array. This achievement matters because it allows for greater control over light-matter coupling, surpassing limitations in previous designs and enabling strong interactions without disrupting topological behaviour. The team characterised this phase through both local order parameters and a global topological invariant, observing significantly amplified edge states and chiral excitation of light. They propose this setup functions as a tunable platform for topological quantum optics, advancing applications in topological superradiant lasers.
