1,754 research outputs found
Design of Optical/IR Blocking Filters for the Lynx X-Ray Microcalorimeter
The Lynx mission concept, under development ahead of the 2020 Astrophysics Decadal Review, includes the Lynx X-ray Microcalorimeter (LXM) as one of its primary instruments. The LXM uses a microcalorimeter array at the focus of a high-throughput soft x-ray telescope to enable high-resolution nondispersive spectroscopy in the soft x-ray waveband (0.2 to 15 keV) with exquisite angular resolution. Similar to other x-ray microcalorimeters, the LXM uses a set of blocking filters mounted within the dewar that pass the photons of interest (x-rays) while attenuating the out-of-band long-wavelength radiation. Such filters have been successfully used on previous orbital and suborbital instruments; however, the Lynx science objectives, which emphasize observations in the soft x-ray band (<1keV), pose more challenging requirements on the set of LXM blocking filters. We present an introduction to the design of the LXM optical/IR blocking filters and discuss recent advances in filter capability targeted at LXM. In addition, we briefly describe the external filters and the modulated x-ray sources to be used for onboard detector calibration
Corrugated Silicon Platelet Feed Horn Array for CMB Polarimetry at 150 GHz
Next generation cosmic microwave background (CMB) polarization anisotropy
measurements will feature focal plane arrays with more than 600 millimeter-wave
detectors. We make use of high-resolution photolithography and wafer-scale etch
tools to build planar arrays of corrugated platelet feeds in silicon with
highly symmetric beams, low cross-polarization and low side lobes. A compact
Au-plated corrugated Si feed designed for 150 GHz operation exhibited
performance equivalent to that of electroformed feeds: ~-0.2 dB insertion loss,
<-20 dB return loss from 120 GHz to 170 GHz, <-25 dB side lobes and <-23 dB
cross-polarization. We are currently fabricating a 50 mm diameter array with 84
horns consisting of 33 Si platelets as a prototype for the SPTpol and ACTpol
telescopes. Our fabrication facilities permit arrays up to 150 mm in diameter.Comment: 12 pages; SPIE proceedings for Millimeter, Submillimeter, and
Far-Infrared Detectors and Instrumentation for Astronomy V (Conference 7741,
June 2010, San Diego, CA, USA
Stellar GADGET: A smooth particle hydrodynamics code for stellar astrophysics and its application to Type Ia supernovae from white dwarf mergers
Mergers of two carbon-oxygen white dwarfs have long been suspected to be
progenitors of Type Ia Supernovae. Here we present our modifications to the
cosmological smoothed particle hydrodynamics code Gadget to apply it to stellar
physics including but not limited to mergers of white dwarfs. We demonstrate a
new method to map a one-dimensional profile of an object in hydrostatic
equilibrium to a stable particle distribution. We use the code to study the
effect of initial conditions and resolution on the properties of the merger of
two white dwarfs. We compare mergers with approximate and exact binary initial
conditions and find that exact binary initial conditions lead to a much more
stable binary system but there is no difference in the properties of the actual
merger. In contrast, we find that resolution is a critical issue for
simulations of white dwarf mergers. Carbon burning hotspots which may lead to a
detonation in the so-called violent merger scenario emerge only in simulations
with sufficient resolution but independent of the type of binary initial
conditions. We conclude that simulations of white dwarf mergers which attempt
to investigate their potential for Type Ia supernovae should be carried out
with at least 10^6 particles.Comment: 11 pages, 6 figures, accepted for publication in MNRA
Opportunities for Sustainable Packaging Design: Learning from Pregnancy as a Metaphor
Current packaging use within fast-moving consumer goods (FMCG) produces a lot of unwanted waste that must be dealt with at significant cost, with negative environmental impacts. In the UK, annually, 10.8 million tonnes of packaging wastes are created; only 24% of plastic packaging is currently recycled (defra, 2011). Many packaging designers approach sustainable issues by various methods, however, this effort only reduces damage to the environment because the packaging still produces a lot of waste in a short period with less valued object, which has a negative impact on the environment. Some FMCG packaging, e.g. Methodās refillable bottles or Unileverās detergent tablets (Unilever, 2000), is designed to promote more sustainable behaviour. However, consumersā perceptions, behaviour and habits have been attributed (Porter, 1999) to decreases in packaging value, driving less careful behaviour.
The emerging field of design for sustainable behaviour (Lockton et al 2008; Wever et al 2008 ) can be applied to packaging (Wever et al, 2009). However, further knowledge is needed, as designersā intended functions may not match consumersā perceptions and behaviour. Fundamental interconnections need to be articulated, taking a whole system view (Wright and Meadows, 2009). One innovation approach in packaging design involves learning from other disciplines. This paper suggests translating ideas from human biology āpregnancy practicethrough metaphor to take a holistic view of the packaging life cycle
Laser-based three-dimensional manufacturing technologies for rechargeable batteries
Laser three-dimensional (3D) manufacturing technologies have gained substantial attention to fabricate 3D structured electrochemical rechargeable batteries. Laser 3D manufacturing techniques offer excellent 3D microstructure controllability, good design flexibility, process simplicity, and high energy and cost efficiencies, which are beneficial for rechargeable battery cell manufacturing. In this review, notable progress in development of the rechargeable battery cells via laser 3D manufacturing techniques is introduced and discussed. The basic concepts and remarkable achievements of four representative laser 3D manufacturing techniques such as selective laser sintering (or melting) techniques, direct laser writing for graphene-based electrodes, laser-induced forward transfer technique and laser ablation subtractive manufacturing are highlighted. Finally, major challenges and prospects of the laser 3D manufacturing technologies for battery cell manufacturing will be provided
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