Planetary Defense team project: READI (Roadmap for EArth Defense Initiatives)

Planetary Defense is a complex problem, not well understood by policy makers and the general public. The recent Chelyabinsk incident in Russia created temporary international attention but has failed to effectively stimulate public action. The lack of long-term attention to cosmic hazards has resulted in limited funding to defend our planet. Hence, it is hard to realistically address this challenge and achieve the high test and operational readiness needed for an effective Planetary Defense strategy. To address this problem, we have created a set of recommendations for the development of a Planetary Defense Program, for the purpose of contributing to the protection of Earth from asteroids and comets. The SSP15 READI Project focused on threats for which there is only a short-term warning, specifically a warning of two years or less from detection of the object to impact. We have provided recommendations in five areas of Planetary Defense including detection and tracking, deflection techniques, global collaboration, outreach and education, and evacuation and recovery. We have applied this set of recommendations in a narrative scenario to make our report more impactful and engaging. We contrast optimistic and pessimistic outcomes for a comet threat, differing from each other in terms of the level of readiness achieved during the years leading up to the discovery of the threat. In our optimistic scenario, the deflection system has achieved high test and operational readiness. The world’s governments have realized the importance of being prepared against cosmic hazards and put in place all of the necessary measures for a successful defense, leading to a positive deflection of the comet. In contrast, in the pessimistic scenario no preparation is done before the detection, and the comet strikes a heavily populated area releasing energy equivalent to 80 times the most powerful nuclear bomb ever detonated. The recommendations that we have identified in this report constitute a roadmap to avoid this horrible outcome, and we believe they should be taken seriously and swiftly implemented

Experimental Demonstration of Multi Moiré Structured Illumination Microscopy

Structured illumination microscopy (SIM) improves spatial resolution by folding high-frequency spectral components into the optical system’s passband. While linear SIM is superior in terms of temporal resolution, living-cells imaging compatibility, and overall optical setup simplicity relative to other super-resolution techniques, it is, however, inferior when it comes to spatial resolution enhancement capability. In this letter, we present experimental demonstration of a novel Multi Moiré SIM (MM-SIM) scheme achieving improved lateral resolution enhancement while preserving the inherent advantages of linear SIM. Using MM-SIM, an approximately 4-fold lateral resolution enhancement was achieved, effectively increasing the optical system’s NA from 0.4 to 1.6. The MM-SIM scheme is a simple and robust realization of 4-fold resolution enhancement capable of unleashing the full potential of standing-wave total internal reflection fluorescence structured illumination microscopy (TIRF-SIM) while preserving the inherent advantages of SIM