Torque Ripple Minimizing of Uniform Slot Machines with Delta Rotor via Subdomain Analysis

Since the slot opening is large in the uniform slot machine, the torque ripple generated by overlapping or misaligning with the rotor cavity is remarkably large in the case of interior permanent magnet (IPM) machine. In this work, it is observed that the magnitude of torque ripple depends strongly on the phase difference between air-gap field harmonics: The ripple is minimized when the two dominant harmonic components cancel each other. Based on this fact, a condition is developed to minimize torque ripple by adjusting the q-flux channel width and d-flux barrier width. The torque ripple minimizing solution is found from a level chart made by subdomain time-stepping analysis. Finite element analysis (FEA) also gives a very similar minimizing solution. A prototype machine is manufactured, and its performances are validated through experiments.

Enhanced photocatalytic activity, transport properties and electronic structure of Mn doped GdFeO3 synthesized using the sol–gel process

Mn doping reduced the band gap to 1.72 eV from 2.18 eV which is confirmed from electronic structure calculations. GdFe0.7Mn0.3O3 exhibits 99% Rh-B degradation at 25 minutes. The multiple oxidation states of Fe and Mn enhances the conductivity and Mn doping reduces the barrier width which facilitates the charge transfer process.

Fractional Young double-slit numerical experiment with Gaussian wavepackets

In the present work, we consider the transmission properties of a Gaussian wavepacket when transmits through few double and multi-slit systems in a fractional medium. For this purpose, we have solved the two-dimensional fractional Schrodinger equation utilizing a split-step Fourier method. Then, we have investigated the effects of different parameters such as the number of slits, slit width, barrier width, layer width, layer heights, fractional order, and wavepacket width on the transmission coefficient, and wavepacket evolution.

Inter and intra band impurity-related absorption in (In,Ga)N/GaN QW under composition, size and impurity effects

In this paper, we theoretically investigate the impacts of Internal well composition, size and impurity's position on the inter valence-conduction bands and intra conduction band optical absorption in GaN/(In,Ga)N/GaN hetero-structure. Based on the numerically finite element method (FEM), the impurity's related Schrödinger equation is solved for the finite potential barrier considering the dielectric constant and effective-mass mismatches between the well and its surrounding matrix. Our results show that the absorption is strongly governed by the dipole matrix element and initial and final implied states transition energies. For a fixed barrier width, the absorption spectra are found red-shifted (blue-shifted) with increasing the well width (In-concentration). It is also shown that the impurity's absorption phenomenon is more pronounced for the off-center case compared to the on-center one. We conclude that the proper control of these parameters is required to best understanding of the optical absorption for solar cell applications.

Numerical simulation of trans-critical flows in open channels using a FVM scheme

The present study makes efforts to simulate the behavior of fully developed stationary shocks, caused by the incidence of supercritical flow with a cross-barrier in an open channel. The numerical solution of nonlinear governing shallow flow equations has been implemented by the application of a second-order Roe TVD scheme. The obtained results from numerical experiment are compared with some measured in a laboratory setup. It can be deduced by comparison of the flow depths in numerical and measured experiments in three different cases of cross-barrier width of 6, 12 and 16 cm that the numerical scheme of Roe is a robust and capable method for simulation of complicated stationary shocks in shallow water flow.

Binding of Factor VIII to D'D3 and A2 Domains of Von Willebrand Factor Facilitates Mechanical Unraveling of the A2 Domain

Background: Proteolytic cleavage of von Willebrand factor (VWF) by a plasma metalloprotease ADAMTS13 is critical for normal hemostasis. Our previous studies demonstrate that binding of coagulation factor VIII (FVIII) through its light chain to VWF significantly accelerates the proteolytic cleavage of VWF by ADAMTS13 under fluidic shear. However, the mechanism underlying the FVIII-cofactor activity enhancing VWF proteolysis by ADAMTS13 under shear is not fully understood. Present study aims to test a hypothesis that FVIII binding to the D'D3 and/or other adjacent domains may facilitate a mechanic-induced conformational change in the central A2 domain of VWF, resulting in an increased accessibility and the cleavage of Tyr1605-Met1606 bond by ADAMTS13. Methods: Recombinant B-domainless FVIII and various VWF fragments (D'D3, D'D3A1, D'D3A1A2, and A2) with an Avi-His-tag on their N-termini and a Spy-tag on their C-termini were expressed and affinity-purified to homogeneity. Laser optical tweezers analysis determined the force-induced conformational changes of VWF fragments in the absence or presence of FVIII. Atomic force microscopy (AFM) and surface plasmon resonance (SPR) determined the binding events and kinetics between FVIII and various VWF domains. Results: Laser optical tweezers analysis demonstrated a Gaussian distribution of unfolding extension events upon pulling the single D'D3A1 fragment with the most probable extension distance of 22.8 ± 1.9 nm (mean ± SEM). Addition of 5 nM FVIII to the D'D3A1 or D'D3 fragment resulted in only a small decrease (~25%) or no change in the pulling extension profile. However, two peaks of Gaussian distribution were detected when pulling the D'D3A1A2 with one peak at ~18 nm and the other at ~40 nm. Addition of 5 nM FVIII to the D'D3A1A2 fragment, only one unfolding event was detected with the most probable unfolding extension distance of 24.5 ± 0.4 nm. Moreover, a single Gaussian distribution of unfolding extension profile was detected when pulling an isolated A2 fragment with the most probable unfolding extension of 31 ± 1 nm. Interestingly, addition of 5 nM FVIII resulted in a significant reduction of the most probable unfolding extension to 16.0 ± 0.4 nm, suggesting that FVIII may directly interact with A2 domain. AFM and SPR demonstrated the binding kinetics between FVIII and various VWF fragments. As shown, the intrinsic off-rate (k0) between FVIII and D'D3 was 0.19 ± 0.9 s-1 and the barrier width (Δx‡) between the naive state and the transition state was 1.5 ± 0.2 Å; the k0 between FVIII and D'D3A1A2 was 2.8 ± 1.0 s-1 and the barrier width (Δx‡) between the naive state and the transitional state was 1.7 ± 0.2 Å. Surprisingly, there was a detectable, but relatively weak binding between FVIII and A2 domain using AFM. SPR experiments confirmed the binding of FVIII to D'D3, D'D3A1A2, and A2 with the dissociation constant (KD) of ~2.9 nM, ~5.2 nM and ~1.6 nM, respectively. These results demonstrate that the specific interaction between FVIII and D'D3 or A2 domain. Conclusions: We have demonstrated for the first time using single-molecule force spectroscopy that binding of FVIII to the D'D3 and/or A2 domain of VWF may facilitate the force-induced conformational changes of the A2 domain, resulting in the enhanced proteolysis by ADAMTS13 under force. Our findings shed new light on how FVIII may regulate VWF proteolysis and function under (patho) physiological conditions. Disclosures Zheng: Shire/Takeda: Research Funding; Alexion: Speakers Bureau; Clotsolution: Other: Co-Founder; Ablynx/Sanofi: Consultancy, Speakers Bureau.

Study on microfluidic paper-based analytical device layouts for simultaneous analysis purposes applying colorimetric reactions

In this project, the adequacy of different layouts for Paper-based Analytical Device (μPAD) for simultaneous analysis in mixtures was evaluated through the use of colorimetric reactions in their reactional zones. Hence, the following parameters of the μPAD were varied: width of the hydrophobic barrier, width and length of the hydrophylic channel, shape and dimensions of the reactional zones, and geometry of the device. The analytical system used in this research was based in comercial tests for domestic quality control of pool water with pH measure through Phenol Red deprotonation, and free chlorine determination through o-Toluidine oxidation.