4,259 research outputs found
Scalar-Top Masses from SUSY Loops with 125 GeV mh and precise Mw, mt
We constrain the masses of scalar-tops (stop) by analyzing the new precision
Tevatron measurement of the W-boson mass and the LHC/Tevatron indications of a
Higgs boson of mass 125.5+-1 GeV. Our study adopts Natural SUSY with low
fine-tuning, which has multi-TeV first and second generation squarks and a
light Higgsino mixing parameter mu=150 GeV. An effective Lagrangian calculation
is made of mh to 3-loops using the H3m program with weak scale SUSY parameters
obtained from RGE evolution from the GUT scale in the Natural SUSY scenario.
The SUSY radiative corrections to the Higgs mass imply maximal off-diagonal
elements of the stop mass-matrix and a mass splitting of the two stops larger
than 400 GeV.Comment: 18 pages, 5 figures, Phys. Lett. B 718 (2013) 1024-103
Not Just Another Drop in the Human Rights Bucket: The Legal Significance of a Codified Human Right to Water
The 2006 Israel-Lebanese Conflict: A Case Study for Protection of the Environment in Times of Armed Conflict
Design Improvement for the Smart DC Wall Plug
The DC smart wall plug is a subsystem within the Cal Poly DC House Project. The previous version faces challenges supplying DC voltage to meet household appliances’ nominal values. Specifically, it can only output the minimum required voltage for DC appliances to operate, resulting in unwanted power loss. In addition, the maximum output voltage is rated at 15V, which is insufficient to power most DC appliances. This design improvement project incorporates NFC technology as a solution to overcome the power loss and a new buck converter configuration to increase the output voltage range. Additionally, the new design introduces short-circuit and reverse polarity protection. Packaging the DC wall plug within an enclosure brings the final design to a production-ready stage. Eventually, the smart plug will reside in a DC House
MINLP Optimization Algorithm for the Synthesis of Heat and Work Exchange Networks
This paper introduces a new optimization model for the simultaneous synthesis of heat and work exchange networks. The work integration is performed in the work exchange network (WEN), while the heat integration is carried out in the heat exchanger network (HEN). In the WEN synthesis, streams at high-pressure (HP) and low-pressure (LP) are subjected to pressure manipulation stages, via turbines and compressors running on common shafts and stand-alone equipment. The model allows the use of several units of single-shaft-turbine-compressor (SSTC), as well as helper motors and generators to respond to any shortage and/or excess of energy, respectively, in the SSTC axes. The heat integration of the streams occurs in the HEN between each WEN stage. Thus, as the inlet and outlet streams temperatures in the HEN are dependent of the WEN design, they must be considered as optimization variables. The proposed multi-stage superstructure is formulated in mixed-integer nonlinear programming (MINLP), in order to minimize the total annualized cost composed by capital and operational expenses. A case study is conducted to verify the accuracy of the proposed approach. The results indicate that the heat integration between the WEN stages is essential to enhance the work integration, and to reduce the total cost of process due the need of a smaller amount of hot and cold utilities.The financial supports by the Brazilian agency “Coordenação de Aperfeiçoamento de Pessoal de NĂvel Superior – CAPES” (process nÂş 10758/12-7), and the Spanish Ministry of Science and Innovation and Ministry of Economy and Competitiveness (under project CTQ2012-37039-C02-02) are gratefully acknowledged
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