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resources:p2:start [2014/01/13 17:34] mouradaresources:p2:start [2014/01/15 19:13] egz
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 Figure 1. (a) Effect of supperfluidity of water around spherical sperparamagnetic NPs.(b) fluid properties in absence of magnetic effects Figure 1. (a) Effect of supperfluidity of water around spherical sperparamagnetic NPs.(b) fluid properties in absence of magnetic effects
  
-====== Epilepsy ======+ 
 +**Nanopore** 
 + 
 +Set-up ( which nanoseconds membrane? size of hole? monitoring? , ? (background: Physics? Coil? calculation?) chemical protocol?  
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 + 
 + 
 +====== Epilepsy ====== 
  
 MRI imaging of superparamagnetic particles and rods aggregates in the brain MRI imaging of superparamagnetic particles and rods aggregates in the brain
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 • Evidence of an off-resonance effect of SPMNPs on proton resonance • Evidence of an off-resonance effect of SPMNPs on proton resonance
 • translation of diffusion coefficients into surgical coordinates. • translation of diffusion coefficients into surgical coordinates.
-• Correlation with histopathological findings and intended epilepsy triggering zones  +• Correlation with histopathological findings and intended epilepsy triggering zones 
  
-====== Magnetophoresis & Simulation ======+** Micro-coil and usu=sage of MRI + Injection of nano-particles in rat/mouse**  
 + 
 +======III.  Magnetophoresis & Simulation ======
 Simulation of superparamagnetic nanomaterial interacting with epileptic seizure-like driven uT magnetic fields Simulation of superparamagnetic nanomaterial interacting with epileptic seizure-like driven uT magnetic fields
  
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 References References
  
-[2] A. Anguelouch, R. L. Leheny, and D. H. Reich, "Application of ferromagnetic nanowires to interfacial microrheology," Appl. Phys. Lett. 89, 111914 (2006).+[2] A. Anguelouch, R. L. Leheny, and D. H. Reich, "Application of ferromagnetic nano-wires to interfacial microrheology," Appl. Phys. Lett. 89, 111914 (2006).
  
  
  
 +**Sandwich** 
 +Literature? math? figures..... set-up?
  
  
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 This paper presents the design, optimization and optical characterization of an array electrostatic actuators based MEMS to be used as an adaptive optics component of a portable retinal imaging device. The proposed wave-front corrector is implemented in (CMC) polymump technology and  features an array of cantilevers on which planar reflective gold thin films were deposited for characterization purposes.  The cantilevers relative deflections will be set based on the output of a wave-front analyzer to correct higher order optical aberrations. For the sake of achieving precise wave front correction, three cantilever sizes were implemented on the chip for a total of 64 cantilevers that will serve as actuators of a deformable mirror in future work.  Array of actuators are hindered by the off-plane initial misalignment phenomenon caused by thin films deposition process and mismatches between the cantilevers displacement due to size nonuniformities introduced by the fabrication process. The device total surface is XXX × XXX mm2. The COMSOL simulation of the modeled Large, medium and small size cantilevers predicted maximum deflections of 6, 4 and 2 um respectively at maximum DC voltages of XXX, XXX and XXX respectively. These values are verified by laser interferometry and shown that they can be considerably augmented by omitting the gold deposited layer in future versions of the device.  This paper presents the design, optimization and optical characterization of an array electrostatic actuators based MEMS to be used as an adaptive optics component of a portable retinal imaging device. The proposed wave-front corrector is implemented in (CMC) polymump technology and  features an array of cantilevers on which planar reflective gold thin films were deposited for characterization purposes.  The cantilevers relative deflections will be set based on the output of a wave-front analyzer to correct higher order optical aberrations. For the sake of achieving precise wave front correction, three cantilever sizes were implemented on the chip for a total of 64 cantilevers that will serve as actuators of a deformable mirror in future work.  Array of actuators are hindered by the off-plane initial misalignment phenomenon caused by thin films deposition process and mismatches between the cantilevers displacement due to size nonuniformities introduced by the fabrication process. The device total surface is XXX × XXX mm2. The COMSOL simulation of the modeled Large, medium and small size cantilevers predicted maximum deflections of 6, 4 and 2 um respectively at maximum DC voltages of XXX, XXX and XXX respectively. These values are verified by laser interferometry and shown that they can be considerably augmented by omitting the gold deposited layer in future versions of the device. 
 +
 +**Diagram and description of set-up**
  
  
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 Figure. 2, All ultrasound detection and ablation of breast tumors Figure. 2, All ultrasound detection and ablation of breast tumors
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 +**Magnetic stimulation of nano-particles to generate ultrasonic waves?** 
 +
 +====== Preferences: ======
 +
 +
 +1. BBB: Complete the text and information in above section.
 +2. Sandwich: Complete the text and discussions.
 +3. Interferometry: Experiment
 +4. Cantilever : Design cantilever.
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