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Kwek, Leong Chuan
Preferred name
Kwek, Leong Chuan
Email
leongchuan.kwek@nie.edu.sg
Department
Natural Sciences & Science Education (NSSE)
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Scopus Author ID
7006483792
6 results
Now showing 1 - 6 of 6
- PublicationOpen AccessSimulation and detection of photonic Chern insulators in a one-dimensional circuit-QED lattice(American Physical Society, 2015)
;Mei, Feng ;You, Jia Bin ;Nie, Wei ;Fazio, Rosario ;Zhu, Shi-LiangWe introduce a conceptually simple and experimentally feasible method to realize and detect photonic topological Chern insulators with a one- dimensional circuit quantum electrodynamics lattice. By periodically modulating the couplings in this lattice, we show that this one-dimensional model can be mapped into a two-dimensional Chern insulator model. In addition to allowing the study of photonic Chern insulators, this approach also provides a natural platform to realize experimentally Laughlin’s pumping argument. Remarkably, based on the scattering theory of topological insulators and input-output formalism, we find that both the photonic edge state and topological invariant can be unambiguously probed with a simple dissipative few-resonator circuit-QED network.WOS© Citations 45Scopus© Citations 49 215 212 - PublicationOpen AccessPhase diffusion and the small-noise approximation in linear amplifiers: Limitations and beyond(Springer Nature, 2019)
;Chia, Andy ;Hajdušek, Michal ;Fazio, Rosario; Vedral, VlatkoThe phase of an optical field inside a linear amplifier is widely known to diffuse with a diffusion coefficient that is inversely proportional to the photon number. The same process occurs in lasers which limits its intrinsic linewidth and makes the phase uncertainty difficult to calculate. The most commonly used simplification is to assume a narrow photon-number distribution for the optical field (which we call the small-noise approximation). For coherent light, this condition is determined by the average photon number. The small-noise approximation relies on (i) the input to have a good signal-to-noise ratio, and (ii) that such a signal-to-noise ratio can be maintained throughout the amplification process. Here we ask: For a coherent input, how many photons must be present in the input to a quantum linear amplifier for the phase noise at the output to be amenable to a small-noise analysis? We address these questions by showing how the phase uncertainty can be obtained without recourse to the small-noise approximation. It is shown that for an ideal linear amplifier (i.e. an amplifier most favourable to the small-noise approximation), the small-noise approximation breaks down with only a few photons on average. Interestingly, when the input strength is increased to tens of photons, the small-noise approximation can be seen to perform much better and the process of phase diffusion permits a small-noise analysis. This demarcates the limit of the small-noise assumption in linear amplifiers as such an assumption is less true for a nonideal amplifier.WOS© Citations 5Scopus© Citations 6 290 114 - PublicationOpen AccessSqueezing enhances quantum synchronization(American Physical Society, 2018)
;Sameer Sonar ;Hajdušek, Michal ;Manas Mukherjee ;Fazio, Rosario ;Vedral, Vlatko ;Sai VinjanampathyIt is desirable to observe synchronization of quantum systems in the quantum regime, defined by the low number of excitations and a highly nonclassical steady state of the self-sustained oscillator. Several existing proposals of observing synchronization in the quantum regime suffer from the fact that the noise statistics overwhelm synchronization in this regime. Here, we resolve this issue by driving a self-sustained oscillator with a squeezing Hamiltonian instead of a harmonic drive and analyze this system in the classical and quantum regime. We demonstrate that strong entrainment is possible for small values of squeezing, and in this regime, the states are nonclassical. Furthermore, we show that the quality of synchronization measured by the FWHM of the power spectrum is enhanced with squeezing.WOS© Citations 69Scopus© Citations 84 140 145 - PublicationOpen AccessTopological insulator and particle pumping in a one-dimensional shaken optical lattice(American Physical Society, 2014)
;Mei, Feng ;You, Jia Bin ;Zhang, Dan-Wei ;Yang, X. C. ;Fazio, Rosario ;Zhu, Shi-LiangWe propose a simple method to simulate and detect topological insulators with cold atoms trapped in a one-dimensional bichromatic optical lattice subjected to a time-periodic modulation. The tight-binding form of this shaken system is equivalent to the periodically driven Aubry-Andre model. We demonstrate that this model can be mapped into a two-dimensional Chern insulator model, whose energy spectrum hosts a topological phase within an experimentally accessible parameter regime. By tuning the laser phase adiabatically, such one-dimensional system constitutes a natural platform to realize topological particle pumping. We show that the Chern number characterizing the topological features of this system can be measured by detecting the density shift after one cycle of pumping.WOS© Citations 61Scopus© Citations 66 304 243 - PublicationOpen AccessQuantum synchronization in nanoscale heat engines(American Physical Society, 2020)
;Jaseem, Noufal ;Hajdušek, Michal ;Vedral, Vlatko ;Fazio, Rosario; Sai VinjanampathyIn the context of closed quantum systems, when a system prepared in its ground state undergoes a sudden quench, the resulting Loschmidt echo can exhibit zeros, resembling the Fisher zeros in the theory of classical equilibrium phase transitions. These zeros lead to non-analytical behavior of the corresponding rate function, which is referred to as dynamical quantum phase transitions (DQPTs). In this work, we investigate DQPTs in the context of open quantum systems that are coupled to both Markovian and non-Markovian dephasing baths via a conserved quantity. The general framework is corroborated by studying the non-equilibrium dynamics of a transverse-field Ising ring. We show the robustness of DQPT signatures under the action of both engineered dephasing baths, independently on how strongly they couple to the quantum system. Our theory provides insight on the effect of non-Markovian environments on DQPTs.WOS© Citations 29Scopus© Citations 38 118 170 - PublicationOpen AccessPhase-preserving linear amplifiers not simulable by the parametric amplifier(American Physical Society, 2020)
;Chia, Andy ;Hajdušek, Michal ;Nair, R. ;Fazio, Rosario; Vedral, VlatkoIt is commonly accepted that a parametric amplifier can simulate a phase-preserving linear amplifier regardless of how the latter is realized [C. M. Caves et al., Phys. Rev. A 86, 063802 (2012)]. If true, this reduces all phase-preserving linear amplifiers to a single familiar model. Here we disprove this claim by constructing two counterexamples. A detailed discussion of the physics of our counterexamples is provided. It is shown that a Heisenberg-picture analysis facilitates a microscopic explanation of the physics. This also resolves a question about the nature of amplifier-added noise in degenerate two-photon amplification.WOS© Citations 7Scopus© Citations 7 201 157