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109 results on '"Chowdhury, Sagar"'

1. New design paradigm for highly efficient and low noise photodetector

Author

Chowdhury, Sagar, Rituraj, Krishnamurthy, Srini, and Bhallamudi, Vidya Praveen

Subjects
Physics - Applied Physics, Physics - Optics, Quantum Physics
Abstract

Achieving high quantum efficiency (QE) with low dark count is essential for highly sensitive photodetectors (PDs), including single photon avalanche detectors (SPADs). However, high QE requires a thicker absorber region, which leads to high dark current and noise, which in turn affects the detectivity of PDs and the photodetection efficiency and dark count of SPADs.The holy grail of photodetector and avalanche photodiode designs is to achieve highest QE with thinnest absorber and still enable large avalanche to gain as needed. We have developed a new design paradigm which exploits the coupling between dielectric Mie resonance and transverse propagating waves in thin layers. The Mie resonance launches the incident light at an angle in an ultrathin absorber, and when coupled to transverse waves, the light propagates laterally and is fully absorbed owing to the longer optical path. Consequently, with appropriate choice of materials for a chosen wavelength, a high absorption(~90%) within typically <100 nm absorber thickness is possible. For illustration, we apply our approach to design Si-based detector operating at 810 nm and InGaAs-based detector operating at 1550 nm and predict that the dark current at room temperature is reduced at least by two orders of magnitude. In addition, the lateral distances are often in a few microns and hence these designs can potentially enable avalanching for a large optical gain., Comment: 6 figures

Published
2024

2. Resonant structure for improved directionality and extraction of single photons

Author

Chowdhury, Sagar, Rituraj, Krishnamurthy, Srini, and Bhallamudi, Vidya Praveen

Subjects
Physics - Optics, Quantum Physics
Abstract

Fluorescent atomic defects, especially in dielectric materials, such as diamond are quite promising for several emerging quantum applications. However, efficient light extraction, directional emission, and narrow spectral emission are key challenges. We have designed dielectric metasurface exploiting Mie-resonance and the Kerker condition to address these issues. Our designed diamond metasurface, tailored for nitrogen-vacancy (NV) defect centers in diamond, predicts up to 500x improvement in the collection of 637 nm (zero phonon line) photons over that from the bare diamond. Our design achieves highly directional emission, predominantly emitting in a 20 degree lobe in the forward direction. This makes light collection more efficient, including for fiber-based collection. The predicted results are stable against the position of the emitter placed in the metaelement, thus alleviating the challenging fabrication requirement of precise positioning of the defect center. Equally importantly, our design approach can be applied to enhance single photon emission also from other defects such as SiV, other materials such as hBN, and other sources such as quantum dots., Comment: 10 Pages, 5 figures, 1 table

Published
2024

4. Control of Magnetic Microrobot Teams for Temporal Micromanipulation Tasks

Author

Kantaros, Yiannis, Johnson, Benjamin, Chowdhury, Sagar, Cappelleri, David J., and Zavlanos, Michael M.

Subjects
Computer Science - Robotics
Abstract

In this paper, we present a control framework that allows magnetic microrobot teams to accomplish complex micromanipulation tasks captured by global Linear Temporal Logic (LTL) formulas. To address this problem, we propose an optimal control synthesis method that constructs discrete plans for the robots that satisfy both the assigned tasks as well as proximity constraints between the robots due to the physics of the problem. Our proposed algorithm relies on an existing optimal control synthesis approach combined with a novel sampling-based technique to reduce the state-space of the product automaton that is associated with the LTL specifications. The synthesized discrete plans are executed by the microrobots independently using local magnetic fields. Simulation studies show that the proposed algorithm can address large-scale planning problems that cannot be solved using existing optimal control synthesis approaches. Moreover, we present experimental results that also illustrate the potential of our method in practice. To the best of our knowledge, this is the first control framework that allows independent control of teams of magnetic microrobots for temporal micromanipulation tasks.

Published
2018

5. Soft Capsule Magnetic Millirobots for Region-Specific Drug Delivery in the Central Nervous System.

Author

Mair, Lamar O., Adam, Georges, Chowdhury, Sagar, Davis, Aaron, Arifin, Dian R., Vassoler, Fair M., Engelhard, Herbert H., Li, Jinxing, Tang, Xinyao, Weinberg, Irving N., Evans, Emily E., Bulte, Jeff W.M., and Cappelleri, David J.

Abstract

Small soft robotic systems are being explored for myriad applications in medicine. Specifically, magnetically actuated microrobots capable of remote manipulation hold significant potential for the targeted delivery of therapeutics and biologicals. Much of previous efforts on microrobotics have been dedicated to locomotion in aqueous environments and hard surfaces. However, our human bodies are made of dense biological tissues, requiring researchers to develop new microrobotics that can locomote atop tissue surfaces. Tumbling microrobots are a sub-category of these devices capable of walking on surfaces guided by rotating magnetic fields. Using microrobots to deliver payloads to specific regions of sensitive tissues is a primary goal of medical microrobots. Central nervous system (CNS) tissues are a prime candidate given their delicate structure and highly region-specific function. Here we demonstrate surface walking of soft alginate capsules capable of moving on top of a rat cortex and mouse spinal cord ex vivo , demonstrating multi-location small molecule delivery to up to six different locations on each type of tissue with high spatial specificity. The softness of alginate gel prevents injuries that may arise from friction with CNS tissues during millirobot locomotion. Development of this technology may be useful in clinical and preclinical applications such as drug delivery, neural stimulation, and diagnostic imaging. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Contributors

Author

Chen, Shuxun, primary, Chowdhury, Sagar, additional, Gupta, Satyandra K., additional, Hu, Songyu, additional, Li, Xiaojian, additional, Shakoor, Adnan, additional, Sun, Dong, additional, Thakur, Atul, additional, and Xie, Mingyang, additional

Published
2021
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8. Image-guided Placement of Magnetic Neuroparticles as a Potential High-Resolution Brain-Machine Interface

Author

Weinberg, Irving N., primary, Mair, Lamar O., additional, Jafari, Sahar, additional, Algarin, Jose, additional, Baviera, Jose Maria Benlloch, additional, Baker-McKee, James, additional, English, Bradley, additional, Chowdhury, Sagar, additional, Malik, Pulkit, additional, Watson-Daniels, Jamelle, additional, Hale, Olivia, additional, Stepanov, Pavel Y., additional, Nacev, Aleksandar, additional, Hilaman, Ryan, additional, Ijanaten, Said, additional, Koudelka, Christian, additional, Araneda, Ricardo, additional, Herberholz, Jens, additional, Martinez-Miranda, Luz J., additional, Shapiro, Benjamin, additional, Villar, Pablo S., additional, Krivorotov, Ilya, additional, Khizroev, Sakhrat, additional, and Fricke, Stanley, additional

Published
2018
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9. Magnetic Particle Transport in Complex Media

Author

Mair, Lamar O., primary, Nacev, Aleksandar N., additional, Chowdhury, Sagar, additional, Stepanov, Pavel, additional, Hilaman, Ryan, additional, Jafari, Sahar, additional, Shapiro, Benjamin, additional, and Weinberg, Irving N., additional

Published
2018
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14. Contributors

Author

Amokrane, Walid, primary, Becker, Aaron T., additional, Belharet, Karim, additional, Cappelleri, David, additional, Cheang, U Kei, additional, Choi, Jongeun, additional, Chowdhury, Sagar, additional, Ferreira, Antoine, additional, Fischer, Peer, additional, Han, Jiwon, additional, Jing, Wuming, additional, Julius, Anak Agung, additional, Jung, Sunghwan, additional, Khalil, Islam S.M., additional, Kim, Dal Hyung, additional, Kim, Hoyeon, additional, Kim, MinJun, additional, Kim, Paul Seung Soo, additional, Kumar, Vijay, additional, Milutinović, Dejan, additional, Misra, Sarthak, additional, Ou, Yan, additional, Palagi, Stefano, additional, Park, Jong-Oh, additional, Park, Sukho, additional, Qiu, Tian, additional, Sakar, Mahmut Selman, additional, Steager, Edward B., additional, Walker, Debora, additional, and Wong, Denise, additional

Published
2017
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16. Going Hands-Free: MagnetoSuture™ for Untethered Guided Needle Penetration of Human Tissue Ex Vivo

Author

Mair, Lamar O., primary, Chowdhury, Sagar, additional, Liu, Xiaolong, additional, Erin, Onder, additional, Udalov, Oleg, additional, Raval, Suraj, additional, Johnson, Benjamin, additional, Jafari, Sahar, additional, Cappelleri, David J., additional, Diaz-Mercado, Yancy, additional, Krieger, Axel, additional, and Weinberg, Irving N., additional

Published
2021
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18. Soft Capsule Magnetic Millirobots for Region-Specific Drug Delivery in the Central Nervous System

Author

Mair, Lamar O., primary, Adam, Georges, additional, Chowdhury, Sagar, additional, Davis, Aaron, additional, Arifin, Dian R., additional, Vassoler, Fair M., additional, Engelhard, Herbert H., additional, Li, Jinxing, additional, Tang, Xinyao, additional, Weinberg, Irving N., additional, Evans, Benjamin A., additional, Bulte, Jeff W.M., additional, and Cappelleri, David J., additional

Published
2021
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19. MagnetoSuture: Tetherless Manipulation of Suture Needles

Author

Mair, Lamar O., primary, Liu, Xiaolong, additional, Dandamudi, Bhargav, additional, Jain, Kamakshi, additional, Chowdhury, Sagar, additional, Weed, Jeremy, additional, Diaz-Mercado, Yancy, additional, Weinberg, Irving N., additional, and Krieger, Axel, additional

Published
2020
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23. Magnetically Aligned Nanorods in Alginate Capsules (MANiACs): Soft Matter Tumbling Robots for Manipulation and Drug Delivery

Author

Mair, Lamar, primary, Chowdhury, Sagar, additional, Paredes-Juarez, Genaro, additional, Guix, Maria, additional, Bi, Chenghao, additional, Johnson, Benjamin, additional, English, Bradley, additional, Jafari, Sahar, additional, Baker-McKee, James, additional, Watson-Daniels, Jamelle, additional, Hale, Olivia, additional, Stepanov, Pavel, additional, Sun, Danica, additional, Baker, Zachary, additional, Ropp, Chad, additional, Raval, Shailesh, additional, Arifin, Dian, additional, Bulte, Jeff, additional, Weinberg, Irving, additional, Evans, Benjamin, additional, and Cappelleri, David, additional

Published
2019
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26. Electric-field responsive contrast agent based on liquid crystals and magnetic nanoparticles

Author

Mair, Lamar O., primary, Martinez-Miranda, Luz J., additional, Kurihara, Lynn K., additional, Nacev, Aleksandar, additional, Hilaman, Ryan, additional, Chowdhury, Sagar, additional, Jafari, Sahar, additional, Ijanaten, Said, additional, da Silva, Claudian, additional, Baker-McKee, James, additional, Stepanov, Pavel Y., additional, and Weinberg, Irving N., additional

Published
2018
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27. Platform for Image-Guided Noninvasive Brain Delivery of Magnetic Particles: Concept and Technical Progress

Author

Weinberg, Irving N., primary, Mair, Lamar O., additional, Jafari, Sahar, additional, Chowdhury, Sagar, additional, Baker-McKay, James, additional, English, Brad, additional, Malik, Pulkit, additional, Nacev, Aleksandar, additional, Hilaman, Ryan, additional, Ijanaten, Said, additional, Algarin, Jose, additional, and Benlloch Baviera, Jose M., additional

Published
2018
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28. Magnetically targeted delivery through cartilage

Author

Jafari, Sahar, primary, Mair, Lamar O., additional, Chowdhury, Sagar, additional, Nacev, Alek, additional, Hilaman, Ryan, additional, Stepanov, Pavel, additional, Baker-McKee, James, additional, Ijanaten, Said, additional, Koudelka, Christian, additional, English, Bradley, additional, Malik, Pulkit, additional, and Weinberg, Irving N., additional

Published
2017
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30. Biofilm disruption with rotating microrods enhances antimicrobial efficacy

Author

Mair, Lamar O., primary, Nacev, Aleksandar, additional, Hilaman, Ryan, additional, Stepanov, Pavel Y., additional, Chowdhury, Sagar, additional, Jafari, Sahar, additional, Hausfeld, Jeffrey, additional, Karlsson, Amy J., additional, Shirtliff, Mark E., additional, Shapiro, Benjamin, additional, and Weinberg, Irving N., additional

Published
2017
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34. Magnetically targeted delivery through cartilage.

Author

Jafari, Sahar, Mair, Lamar O., Chowdhury, Sagar, Nacev, Alek, Hilaman, Ryan, Stepanov, Pavel, Baker-McKee, James, Ijanaten, Said, Koudelka, Christian, English, Bradley, Malik, Pulkit, and Weinberg, Irving N.

Subjects
MAGNETIC nanoparticles, ARTICULAR cartilage, DRUG delivery systems
Abstract

In this study, we have invented a method of delivering drugs deep into articular cartilage with shaped dynamic magnetic fields acting on small metallic magnetic nanoparticles with polyethylene glycol coating and average diameter of 30 nm. It was shown that transport of magnetic nanoparticles through the entire thickness of bovine articular cartilage can be controlled by a combined alternating magnetic field at 100 Hz frequency and static magnetic field of 0.8 tesla (T) generated by 1" dia. x 2" thick permanent magnet. Magnetic nanoparticles transport through bovine articular cartilage samples was investigated at various settings of magnetic field and time durations. Combined application of an alternating magnetic field and the static field gradient resulted in a nearly 50 times increase in magnetic nanoparticles transport in bovine articular cartilage tissue as compared with static field conditions. This method can be applied to locally deliver therapeutic-loaded magnetic nanoparticles deep into articular cartilage to prevent cartilage degeneration and promote cartilage repair in osteoarthritis. [ABSTRACT FROM AUTHOR]

Published
2018
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41. PLANNING FOR AUTOMATED OPTICAL MICROMANIPULATION OF BIOLOGICAL CELLS

Author

CHOWDHURY, SAGAR and CHOWDHURY, SAGAR

Abstract

Optical tweezers (OT) can be viewed as a robot that uses a highly focused laser beam for precise manipulation of biological objects and dielectric beads at micro-scale. Using holographic optical tweezers (HOT) multiple optical traps can be created to allow several operations in parallel. Moreover, due to the non-contact nature of manipulation OT can be potentially integrated with other manipulation techniques (e.g. microfluidics, acoustics, magnetics etc.) to ensure its high throughput. However, biological manipulation using OT suffers from two serious drawbacks: (1) slow manipulation due to manual operation and (2) severe effects on cell viability due to direct exposure of laser. This dissertation explores the problem of autonomous OT based cell manipulation in the light of addressing the two aforementioned limitations. Microfluidic devices are well suited for the study of biological objects because of their high throughput. Integrating microfluidics with OT provides precise position control as well as high throughput. An automated, physics-aware, planning approach is developed for fast transport of cells in OT assisted microfluidic chambers. The heuristic based planner employs a specific cost function for searching over a novel state-action space representation. The effectiveness of the planning algorithm is demonstrated using both simulation and physical experiments in microfluidic-optical tweezers hybrid manipulation setup. An indirect manipulation approach is developed for preventing cells from high intensity laser. Optically trapped inert microspheres are used for manipulating cells indirectly either by gripping or pushing. A novel planning and control approach is devised to automate the indirect manipulation of cells. The planning algorithm takes the motion constraints of the gripper or pushing formation into account to minimize the manipulation time. Two different types of cells (Saccharomyces cerevisiae and Dictyostelium discoideum) are manipulated to demon

Published
2013

42. Survey on indirect optical manipulation of cells, nucleic acids, and motor proteins

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Banerjee, Ashis, Chowdhury, Sagar, Losert, Wolfgang, Gupta, Satyandra K., Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Banerjee, Ashis, Chowdhury, Sagar, Losert, Wolfgang, and Gupta, Satyandra K.

Abstract

Optical tweezers have emerged as a promising technique for manipulating biological objects. Instead of direct laser exposure, more often than not, optically-trapped beads are attached to the ends or boundaries of the objects for translation, rotation, and stretching. This is referred to as indirect optical manipulation. In this paper, we utilize the concept of robotic gripping to explain the different experimental setups which are commonly used for indirect manipulation of cells, nucleic acids, and motor proteins. We also give an overview of the kind of biological insights provided by this technique. We conclude by highlighting the trends across the experimental studies, and discuss challenges and promising directions in this domain of active current research., National Science Foundation (U.S.) (Grant No. CMMI- 0835572), National Science Foundation (U.S.) (CPS-0931508)

Published
2011

48. Towards Independent Control of Multiple Magnetic Mobile Microrobots.

Author

Chowdhury, Sagar, Wuming Jing, and Cappelleri, David J.

Subjects
MICROROBOTS, MOBILE robots, MAGNETIC fields
Abstract

In this paper, we have developed an approach for independent autonomous navigation of multiple microrobots under the influence of magnetic fields and validated it experimentally. We first developed a heuristics based planning algorithm for generating collision-free trajectories for the microrobots that are suitable to be executed by an available magnetic field. Second, we have modeled the dynamics of the microrobots to develop a controller for determining the forces that need to be generated for the navigation of the robots along the trajectories at a suitable control frequency. Next, an optimization routine is developed to determine the input currents to the electromagnetic coils that can generate the required forces for the navigation of the robots at the controller frequency. We then validated our approach by simulating an electromagnetic system that contains an array of sixty-four magnetic microcoils designed for generating local magnetic fields suitable for simultaneous independent actuation of multiple microrobots. Finally, we prototyped an mm-scale version of the system and present experimental results showing the validity of our approach. [ABSTRACT FROM AUTHOR]

Published
2016
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