(The talk will be given in English)

Speaker:     Dr. Yasmine Meroz
                     School of Plant Sciences and Food Security, Tel Aviv University

Monday, May 20^th, 2019
15:00 - 16:00

Room 011, Kitot Bldg., Faculty of Engineering

A Framework for Collective Behavior in Plant-Inspired Growth-Driven Systems

Abstract

A variety of biological systems are not motile, but sessile in nature, relying on growth as the main driver of their movement. Groups of such growing organisms can form complex structures, such as the functional architecture of growing axons, or the adaptive structure of plant root systems. These processes are not yet understood, however the decentralized growth dynamics bear similarities to the collective behavior observed in groups of motile organisms, such as flocks of birds or schools of fish. Equivalent growth mechanisms make these systems amenable to a theoretical framework inspired by tropic responses of plants, where growth is considered implicitly as the driver of the observed bending towards a stimulus. We introduce two new concepts related to plant tropisms: point tropism, the response of a plant to a nearby point signal source, and allotropism, the growth-driven response of plant organs to neighboring plants. We first analytically and numerically investigate the 2D dynamics of single organs responding to point signals fixed in space. Building on this we study pairs of organs interacting via allotropism, i.e. each organ senses signals emitted at the tip of their neighbor and responds accordingly. In the case of local sensing we find a rich phase space. This work sets the stage towards a theoretical framework for the investigation and understanding of systems of interacting growth-driven individuals.

https://www.biorxiv.org/content/10.1101/566364v1
 

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You are invited to attend a department seminar

VOLUMETRIC 3D-PRINTED ANTENNAS, MANUFACTURED VIA SELECTIVE POLYMER METTALIZATION

By:

Sergey Kolen
MSc student under the supervision of Prof. Pavel Ginzburg

Abstract

Additive manufacturing paves new ways to the efficient exploration of the third space dimension, providing advantages over conventional planar architectures. In particular, volumetric electromagnetic antennas can demonstrate superior characteristics, outperforming their planar counterparts. Here a new approach to the fabrication of electromagnetic devices is developed and applied to antennas, implemented on curved surfaces. Highly directive and broadband antennas are 3D‐printed on hemispherical supports. The antenna skeleton and the support are simultaneously printed with different polymer materials – PLA mixed with graphene flakes and pure PLA, respectively. Weakly DC‐conductive graphene PLA‐based skeleton is post‐processed and high‐quality conductive copper layer is selectively electrochemically deposited on it. The antenna devices are found to demonstrate radiation performance, similar to that achievable with conventional fabrication approaches. However, additive manufacturing of RF antennas provides superior capabilities of constructing tailor‐made devices with properties, pre‐defined by non‐standardized end users.

On Tuesday, May 28, 2019, 15:00
Room 011, EE-Class Building

You are invited to attend a department seminar

Optical waveguides in porous silicon

by:
Alexander Kellarev
PHD student under the supervision of Prof. Shlomo Ruschin

Abstract

 Planar optical elements have essential application in optical and opto-electronic systems, such as various optical communication devices, as single elements and as parts of optical integrated circuits. Creation of optical waveguides by means of patterned pore filling provides a novel method of fabrication of planar optical elements, which is potentially less complicated than the existing manufacturing methods.
 In this seminar I shall present results of the experimental research on optical properties of porous silicon, how they can be modified in a controlled manner and how local modification of refraction index of porous silicon can be ustilised to fabricate low-loss optical waveguides.

On Thursday, May 16, 2019, 15:00
Room 011, EE-Class Building