SCHOOL OF MECHANICAL ENGINEERING SEMINAR

Wednesday, June 1, 2022 at 14:30

Wolfson Building of Mechanical Engineering, Room 206

Optimization of Flow and Reaction Models for Capturing Gas-Phase Cellular Detonation Properties in Premixed Mixtures

Naor Zadok

M.Sc. student of Dr. Yoram Kozak

Detonation is a type of combustion wave involving a supersonic exothermic front that drives a shock wave. This process creates very high pressure and temperature gradients, and releases vast amounts of energy in short time periods. In particular, gas-phase detonations in premixed fuel and oxidizer mixtures are characterized by unsteady and unstable behavior, which can involve complex cellular structures.

It is today well-established that detonation properties for a given gaseous mixture, such as the detonation wave speed and the typical cellular patterns, are vital for various engineering applications. For instance, development of highly efficient detonation-based engines and improved safety measures for fuel storage facilities.

The ability to predict the behavior of gas-phase detonation waves via numerical simulations can assist the development of the above-mentioned applications. However, typical detonation simulations are multidimensional and involve complex chemistry reaction mechanisms. This leads to extremely high computational costs per simulation, and significantly limits the number of possible simulations. Simplified single-step reaction models allow performing these simulations with a considerably lower computation cost, and therefore more simulations can be conducted in a given time.

In the present study, we will develop a new numerical framework that can efficiently calibrate flow and simplified single-step reaction models to mimic detonation properties derived by detailed chemical mechanisms. This framework is based on an evolutionary algorithm coupled with a set of non-linear algebraic equations for detonation properties. We will also present a new model that can predict the detonation cell length and width for single-step reaction multidimensional detonation simulations. This model will allow us tuning and optimizing the flow and reaction rate parameters based on experimental detonation cell size data for any given premixed mixture.

In the future, we intend to utilize the proposed framework for conducting multidimensional reactive flow simulations of different novel energy conversion and propulsion systems.

Join Zoom Meeting https://us02web.zoom.us/j/82108132163?pwd=Z2h4UzNzUS9mbXplT0lMU1pZenFEQT09

סטודנטים וסטודנטיות של מדעי המחשב, הנדסת חשמל ומדעים דיגיטליים להיי-טק,

חברת Paloalto  מגיעה בפעם הראשונה ליום זרקור בבית הספר.

בואו לפגוש את נציגי החברה, לשמוע הרצאה מרתקת ממנהל בכיר בחברה וגם על הזדמנויות תעסוקה עבורכם.

מתי: יום רביעי, 25/5/2022 בין השעות 16:00-18:30.
ההרצאה תתקיים בשעה 17:00 בבניין צ'קפוינט, אולם 001.

הרשמה בקישור: הרשמה ליום זרקור חברת Paloalto 

***אל תפספסו את דוכן השייקים הטעימים ומי שיישאר להרצאה גם יקבל שי קטן.

נושא ההרצאה: איך פורץ הצליח להשיג גישה ל-100 מיליון חשבונות של אחד מהבנקים הגדולים בארה״ב

תיאור ההרצאה: למעבר המואץ לענן יש השלכות אבטחה משמעותיות. חברות משקיעות הרבה מאמצים בשמירה על אבטחת המידע בענן הציבורי. אחד מהנושאים החמים ביותר הוא נושא הזהויות (Identity) של בני אדם ומכונות בענן. הצטרפו אלינו להרצאה בנושא אבטחת הענן וניהול זהויות. בהרצאה נסקור את הבעיות המרכזיות איתן נאלצים להתמודד צוותי אבטחת המידע בענן, ומה עושים כשצריך לנהל עשרות מליונים של הרשאות.

על הדובר: בר שוורץ, מנהל מוצר בכיר בחברת Palo Alto Networks. 
 

LMI Seminar:

Light trapping for broadband absorption of the solar radiation: from nanolenses to light trapping bioinspired by the Fovea Centralis

Dr. Gil Shalev

School of Electrical Engineering

Ben-Gurion University of the Negev

Wednesday  May  25^th,  2022

13:00-14:00

Light refreshments and drinks will be served at 12:30

Auditorium 011, Engineering Classroom Building,  Faculty of Engineering, Tel-Aviv University

Abstract:

 Subwavelength arrays of photoactive materials are important for solar energy applications due to their omnidirectional broadband absorption. Recently, it was suggested and demonstrated how the Yablonovitch 4n2 limit can be surpassed with such systems. We consider three systems of surface silicon subwavelength arrays for light trapping: 1) light trapping bioinspired by the Fovea Centralis (light funnel array paradigm), 2) enhanced light trapping with self-aligned quasi-nanolenses, and 3) light trapping governed by deep subwavelength sidewall decorations. We show that such light trapping approaches conclude an enhancement, in omnidirectional and broadband absorption of the solar spectrum, that is dozens of percent higher compared with state-of-the-art systems. The underlying light trapping mechanisms differ and ranges from refraction, light concentration, scattering, and photon tunneling. The research work is supported with far-field spectroscopy, near-field microscopy and numerical calculations.

Marko, G. et al. (2019). Nano Energy, 61, 275–283. https://doi.org/10.1016/j.nanoen.2019.04.082

Prajapati, A.et al. (2020). Nano Energy, 70, 104521, https://doi.org/10.1016/j.nanoen.2020.104521

Chauhan, A., et al. (2021). Solar RRL, 5(12).

Bio:  Dr. Gil Shalev is a senior faculty member with the school of electrical and computer engineering, Ben-Gurion university of the Negev. His main research interests involve the exploration of novel field-effect devices for bioelectronics and biosensors, light trapping and the broadband absorption of the solar radiation based on arrays of nanostructures for various photonic and photovoltaic applications, and carrier extraction from nano-scaled devices. He gained his scientific education and experience in Tel-Aviv University in Israel and in the Max-Planck Institute for the science of light in Erlangen, Germany.