Project Mahathir: ‘Extraordinary’ Population Growth in Sabah

The Malaysian state of Sabah faced an “extraordinary” population growth during the last decades. Illegal immigrants are said to have been issued Malaysian Identity Cards based on false statutory declarations. The so-called “Project Mahathir” changed Sabah’s ethnic make-up as well as the participation in elections. Politicians are said to have made use of “Phantom voters” in order to decide Sabah elections. Finally, with the help of a petition Sabah-based NGO’s demand an investigation into the case: Those who are responsible for the massive influx of illegal immigrants may soon be charged

Robert Browning and music.

Thesis (M.A.)--Boston University N.B.:Page 44 is mislabeled. No content is missing

Non-perturbative theory of spontaneous parametric down-conversion in open and dispersive optical systems

We develop a non-perturbative formulation based on the Green-function quantization method, that can describe spontaneous parametric down-conversion in the high-gain regime in nonlinear optical structures with arbitrary amount of loss and dispersion. This formalism opens the way for description and design of arbitrary complex and/or open nanostructured nonlinear optical systems in quantum technology applications, such as squeezed-light generation, nonlinearity-based quantum sensing, and hybrid quantum systems mediated by nonlinear interactions. As an example case, we numerically investigate the scenario of integrated quantum spectroscopy with undetected photons, in the high-gain regime, and uncover novel gain-dependent effects in the performance of the system

Lithium niobate on insulator: An emerging platform for integrated quantum photonics

Due to its properties, lithium niobate is one of the most suitable material platforms for the implementation of integrated optical quantum circuits. With the commercialization of lithium niobate on insulator (LNOI) substrates in the recent years, the lithium niobate nanostructuring technology has progressed immensely. Now nanostructured LNOI components can be fabricated with a quality on par with any other material platform, and could act as effective building blocks for integrated quantum circuits. The advanced nanostructuring technology combined with its favorable material properties make the LNOI platform a real contender for the realization of large‐scale optical quantum circuits. The aim of this perspective article is to examine the utility of the LNOI platform toward this goal. To do this, first the availability of the individual components that can act as the building blocks for such circuits is investigated. Afterward, a fully on‐chip implementation of a multiplexed source of single photons on the LNOI platform is envisioned, which is a highly challenging task in all material platforms. Based on the performance of the state‐of‐the‐art components on the LNOI platform, the performance of such a device is quantified and the areas in which more progress is needed are pointed out

Second harmonic microscopy of monolayer MoS2

We show that the lack of inversion symmetry in monolayer MoS2 allows strong optical second harmonic generation. Second harmonic of an 810-nm pulse is generated in a mechanically exfoliated monolayer, with a nonlinear susceptibility on the order of 1E-7 m/V. The susceptibility reduces by a factor of seven in trilayers, and by about two orders of magnitude in even layers. A proof-of-principle second harmonic microscopy measurement is performed on samples grown by chemical vapor deposition, which illustrates potential applications of this effect in fast and non-invasive detection of crystalline orientation, thickness uniformity, layer stacking, and single-crystal domain size of atomically thin films of MoS2 and similar materials.Comment: 6 pages, 4 figure

Region C of the Escherichia coli heat shock sigma factor RpoH (σ32) contains a turnover element for proteolysis by the FtsH protease

Transcription of most heat shock genes in Escherichia coli is initiated by the alternative sigma factor σ32 (RpoH). At physiological temperatures, RpoH is rapidly degraded by chaperone-mediated FtsH-dependent proteolysis. Several RpoH residues critical for degradation are located in the highly conserved region 2.1. However, additional residues were predicted to be involved in this process. We introduced mutations in region C of RpoH and found that a double mutation (A131E, K134V) significantly stabilized RpoH against degradation by the FtsH protease. Single-point mutations at these positions only showed a slight effect on RpoH stability. Both double and single amino acid substitutions did not impair sigma factor activity as demonstrated by a groE-lacZ reporter gene fusion, Western blot analysis of heat shock gene expression and increased heat tolerance in the presence of these proteins. Combined mutations in regions 2.1 and C further stabilized RpoH. We also demonstrate that an RpoH fragment composed of residues 37-147 (including regions 2.1 and C) is degraded in an FtsH-dependent manner. We conclude that in addition to the previously described turnover element in region 2.1, a previously postulated second region important for proteolysis of RpoH by FtsH lies in region C of the sigma facto

Group-index-matched frequency conversion in lithium niobate on insulator waveguides

Sources of spectrally engineered photonic states are a key resource in several quantum technologies. Of particular importance are the so-called factorizable biphoton states, which possess no spectral entanglement and hence, are ideal for heralded generation of high-purity single photons. An essential prerequisite for generating these states through nonlinear frequency conversion is the control over the group indices of the photonic modes of the source. Here, we show that thin-film lithium niobate on insulator (LNOI) is an excellent platform for this purpose. We design and fabricate periodically poled ridge waveguides in LNOI to demonstrate group index engineering of its guided photonic modes and harness this control to experimentally realize on-chip group index matched type-II sum-frequency generation (SFG). Also, we numerically study the role of the top cladding layer in tuning the dispersion properties of the ridge waveguide structures and reveal a distinctive difference between the air and silica-clad designs which are currently among the two most common device cladding configurations in LNOI. We expect that these results will be relevant for various classical and quantum applications where dispersion control is crucial in tailoring the nonlinear response of the LNOI-based devices

Nonlinear quantum spectroscopy with Parity-Time symmetric integrated circuits

We propose a novel quantum nonlinear interferometer design that incorporates a passive PT symmetric coupler sandwiched between two nonlinear sections where signal-idler photon pairs are generated. The PT-symmetry enables efficient coupling of the longer-wavelength idler photons and facilitates the sensing of losses in the second waveguide exposed to analyte under investigation, whose absorption can be inferred by measuring only the signal intensity at a shorter wavelength where efficient detectors are readily available. Remarkably, we identify a new phenomenon of sharp signal intensity fringe shift at critical idler loss values, which is distinct from the previously studied PT-symmetry breaking. We discuss how such unconventional properties arising from quantum interference can provide a route to enhancing the sensing of analytes and facilitate broadband spectroscopy applications in integrated photonic platforms

Resonantly enhanced second-harmonic generation using III-V semiconductor all-dielectric metasurfaces

Nonlinear optical phenomena in nanostructured materials have been challenging our perceptions of nonlinear optical processes that have been explored since the invention of lasers. For example, the ability to control optical field confinement, enhancement, and scattering almost independently, allows nonlinear frequency conversion efficiencies to be enhanced by many orders of magnitude compared to bulk materials. Also, the subwavelength length scale renders phase matching issues irrelevant. Compared with plasmonic nanostructures, dielectric resonator metamaterials show great promise for enhanced nonlinear optical processes due to their larger mode volumes. Here, we present, for the first time, resonantly enhanced second-harmonic generation (SHG) using Gallium Arsenide (GaAs) based dielectric metasurfaces. Using arrays of cylindrical resonators we observe SHG enhancement factors as large as 104 relative to unpatterned GaAs. At the magnetic dipole resonance we measure an absolute nonlinear conversion efficiency of ~2X10^(-5) with ~3.4 GW/cm2 pump intensity. The polarization properties of the SHG reveal that both bulk and surface nonlinearities play important roles in the observed nonlinear process