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Railjack Mods (also called Plexus Mods) are applied to the Railjack-modding platfrom called Plexus. They are divided into three categories: Integrated, Battle, Tactical, each category being compatible with the respective mod grid within the Plexus. Integrated mods provide stat bonuses to the Railjack and it's Armaments, and include Railjack Aura mods. Battle Mods provide the Railjack with energy-based abilities, while Tactical Mods provide the Railjack with cooldown-based abilities. Mods in the latter two categories do not drain capacity, but are further divided into Defensive, Offensive, and Super subcategories, each corresponding to a single special slot. They drop in Empyrean missions, and are untransmutable. Visually, Railjack Mods can be identified by their molded alloy trim.
The Inhuman Outbreak soon followed, and S.H.I.E.L.D. had to stand against the implications it caused. Following the exposure and the abrupt end of HYDRA's infiltration of the ATCU, S.H.I.E.L.D. was semi-legalized as the black ops division of Matthew Ellis' administration, with the ATCU serving as S.H.I.E.L.D.'s public face. With HYDRA suffering a crippling blow, S.H.I.E.L.D. became aware of the dark Inhuman, Hive, and soon had to fight against his Inhuman army, which intended to transform all humanity into Inhumans. As the war with Hive reached its end, Lincoln Campbell sacrificed his life to destroy Hive in a nuclear explosion in space.
He chose three mercenaries, Idaho, Lance Hunter, and former agent Isabelle Hartley, to join his team on missions, and a mechanic named Alphonso Mackenzie to assist Billy Koenig in the Playground. The brain damage of Leo Fitz was severe, Jemma Simmons was not with them, and Grant Ward was suicidal and in isolation, refusing to speak to anyone but Skye.[60] Simmons was ordered by Coulson to infiltrate HYDRA's science division acting as his source within HYDRA.[61] Coulson also had Bobbi Morse infiltrate HYDRA in its security division and to keep an eye on Simmons.[62] The first team mission had May, Triplett, and Skye act as back-up for the mercenaries while they attempted to purchase information on an 0-8-4 that a former agent once guarded. The negotiation failed when the Absorbing Man killed the agent and took the file.[63]
At the Playground, Phil Coulson interrogated Gideon Malick, who revealed to him that Hive could control Inhumans' minds. Fearing that one of the Secret Warriors had been swayed by the dark Inhuman, Coulson ordered Alphonso Mackenzie to lock down the base. Coulson kept the information from the Inhumans and asked Leo Fitz and Jemma Simmons to find in Lucio's corpse something to prove Malick was right. The pair found an infection in Lucio's brain. Suddenly, the power in the base was turned off. S.H.I.E.L.D. agents surrounded the Secret Warriors, suspecting that one of them caused the power outage and Malick's death. The team barricaded themselves. Mackenzie found in Lincoln Campbell's locker the Kree Orb. Daisy Johnson led the team into a room where Coulson waited for them. He accused Campbell of being under Hive's control since their first encounter with Hive. Campbell tried to escape but Johnson knocked him out.
In the Lighthouse, Rodriguez realized that the Shrike was made of the same material as the Monoliths that they had encountered. With that knowledge, Benson informed Mackenzie that if the Shrike connected to the Earth's energy lines, the results could be catastrophic. After doing research on the word "Pachakutiq" mentioned by Tinker, Benson requested permission to go to Yucatán and South America to investigate the monoliths origins. All of the sudden, Daisy Johnson contacted the base and landed Zephyr One. She, Piper, and James Davis were greeted by Mackenzie and Rodriguez but they did not return with Jemma Simmons and Leo Fitz. Agent Khan then informed them that May had managed to escape Sarge's captivity and she was heading to the base with Sarge as a captive.[136] Mackenzie and Johnson then updated each other on their missions and what they were up against.[139]
In pixelated silicon radiation detectors that are utilized for the detection of UV, visible, and in particular Near Infra-Red (NIR) light it is desirable to utilize a relatively thick fully depleted Back-Side Illuminated (BSI) detector design providing 100% Fill Factor (FF), low Cross-Talk (CT), and high Quantum Efficiency (QE). The optimal thickness of such detectors is typically less than 300μm and above 40μm and thus it is more or less mandatory to thin the detector wafer from the backside after the front side of the detector has been processed and before a conductive layer is formed on the backside. A TAIKO thinning process is optimal for such a thickness range since neither a support substrate on the front side nor lithographic steps on the backside are required. The conductive backside layer should, however, be homogenous throughout the wafer and it should be biased from the front side of the detector. In order to provide good QE for blue and UV light the conductive backside layer should be of opposite doping type than the substrate. The problem with a homogeneous backside layer being of opposite doping type than the substrate is that a lot of leakage current is typically generated at the sawed chip edges, which may increase the dark noise and the power consumption. These problems are substantially mitigated with a proposed detector edge arrangement which 2D simulation results are presented in this paper.
LMSAL and NIST are developing position-sensitive x-ray strip detectors based on Transition Edge Sensor (TES) microcalorimeters optimized for solar physics. By combining high spectral (E/ delta E approximately equals 1600) and temporal (single photon delta t approximately equals 10 micro s) resolutions with imaging capabilities, these devices will be able to study high-temperature (>l0 MK) x-ray lines as never before. Diagnostics from these lines should provide significant new insight into the physics of both microflares and the early stages of flares. Previously, the large size of traditional TESs, along with the heat loads associated with wiring large arrays, presented obstacles to using these cryogenic detectors for solar missions. Implementing strip detector technology at small scales, however, addresses both issues: here, a line of substantially smaller effective pixels requires only two TESs, decreasing both the total array size and the wiring requirements for the same spatial resolution. Early results show energy resolutions of delta E(sub fwhm) approximately equals 30 eV and spatial resolutions of approximately 10-15 micron, suggesting the strip-detector concept is viable.
X-ray tomography is widely used in materials science. However, X-ray scanners are often based on polychromatic radiation that creates artifacts such as dark streaks. We show this artifact is not always due to beam hardening. It may appear when scanning samples with high-Z elements inside a low-Z matrix because of the high-Z element absorption edge: X-rays whose energy is above this edge are strongly absorbed, violating the exponential decay assumption for reconstruction algorithms and generating dark streaks. A method is proposed to limit the absorption edge effect and is applied on a microelectronic case to suppress dark streaks between interconnections.
We report on the development of position-sensitive transition-edge sensors (PoST's) for future x-ray astronomy missions such as the International X-ray Observatory (IXO), currently under study by NASA and ESA. PoST's consist of multiple absorbers each with a different thermal coupling to one or more transition-edge sensor (TES). This differential thermal coupling between absorbers and TES's results in different characteristic pulse shapes and allows position discrimination between the different pixels. The development of PoST's is motivated by a desire to achieve maximum focal-plane area with the least number of readout channels and as such. PoST's are ideally suited to provide a focal-plane extension to the Constellation-X microcalorimeter array. We report the first experimental results of our latest one and two channel PoST's, which utilize fast thermalizing electroplated Au/Bi absorbers coupled to low noise Mo/Au TES's - a technology already successfully implemented in our arrays of single pixel TES's. We demonstrate 6 eV energy resolution coupled with spatial sensitivity in the keV energy range. We also report on the development of signal processing algorithms to optimize energy and position sensitivity of our detectors.
Soft X-ray absorption near edge spectroscopy (XANES) and extended X-ray absorption fine structure (EXAFS) spectroscopy have been performed at the Mg-, Al- and Si-K edges in order to establish the ability of this spectroscopy to derive structural information in disordered solids such as glasses and gels. Mg- and Al-K XANES are good structural probes to determine the coordination state of these elements in important minerals, glasses and gels. In a CaOsbnd MgOsbnd 2SiO2 glass Mg XANES spectra differ from that found in the crystalline equivalent, with a significant shift of the edge maxima to lower energy, consistent with a CN lower than 6. Mg-EXAFS on the same sample are in agreement and indicate the presence of 5-coordinated Mg with Mgsbnd O distances of 2.01Å. In aluminosilicate gels, Alsbnd K XANES has been used to investigate the [4]Al/Altotal ratios. These ratios increase as the Al/Si ratios decrease. Aluminosilicate and ferric-silicate gels were studied by using Sisbnd K edge XANES. XANES spectra differ significantly among the samples studied. Aluminosilicate gels with Al/Si= 1 present a different Al and Si local environment from that known in clay minerals with the same Al/Si ratio. The gel-to-mineral transformation thus implies a dissolution-recrystallization mechanism. On the contrary, ferric-silicate gel presents a Si local environment close to that found in nontronite which may be formed by a long range ordering of the initial gels. 2b1af7f3a8