You are invited to attend a lecture

By

Lior Kornblum

Center for Research on Interface Structures and Phenomena (CRISP) and Dept. of Applied Physics, Yale University, New Haven, CT, USA

On the subject:

When Functional Oxides Meet Semiconductors

Perovskite oxides of transition metals offer scientists and engineers a theme park of new physics, with complex structure-property relations and a wide scope of useful phenomena. Advances in epitaxial growth techniques bring unprecedented possibilities of atomic engineering of these oxides and their interfaces, with exciting prospects of unravelling their underlying physics and harnessing it towards useful applications. However, fundamental material challenges inhibit the introduction of these materials onto semiconductors and thus into the microelectronics technology.

The potential of the oxides’ functionalities to evolve out of the labs and into technology has received a considerable boost with the pioneering of epitaxial growth approaches for perovskites directly on semiconductors. This combination opens a route to bridge between oxide functionalities and microelectronics. Moreover, interface engineering of oxides on semiconductors can lead to new functionalities, made possible by the coupling between the dissimilar materials.

The formation of a 2 dimensional electron gas (2DEG) is a prominent example of an unexpected phenomenon occurring at the interface of two insulating oxides, with complex underlying physics and potential for technological applications. We demonstrate the first integration of high carrier density oxide 2DEGs on silicon, which brings the useful properties of 2DEGs closer to application in microelectronics. In order to put this claim to the test, we assess the performance of 2DEGs on silicon for high-power devices.

Additional functionality can be obtained by coupling of oxides to semiconductors. This concept will be presented with examples for the investigation of electronic transport across the oxide-semiconductor interface and its prospects for photoelectrocatalysis. Another example is the coupling between a monolayer of a non-ferroelectric oxide and silicon, which leads to interface-induced ferroelectric functionality.

With these examples I hope to provide a glimpse into the prospects and promise of combining functional oxides with semiconductors, and address some of challenges lying ahead.

16 April 2015, at 15:00,

Room 011, Kitot Building

אורית אישטיין

תלמידת המחלקה להנדסה ביו רפואית לתואר שני תרצה בנושא:

Walking through the Axoplasmic Jungle, a Cargo’s Perspective

Neurofilaments (NFs) lie parallel to the longitudinal axis of the axon. Their unique structure includes side-arms that protrude from the NF backbone and have a net charge. Due to their charge, side-arms of neighboring filaments form cross-links thereby forming a dense net-like structure that occupies most of the axon cytoplasm. Therefore, the net creates unavoidable obstacles for motor proteins, transporting essential cargos from one end of the axon to another. Since these cargos reach diameters much larger than the spaces within the net, the motor-cargo complex is expected to encounter these obstacles every few steps. Although there is an abundance of data today regarding the motor's mechanism of movement, the local reciprocal effect between the motor-cargo movement and its surrounding environment has not yet been modeled. For this purpose we developed a physical model in which two coping scenarios are proposed: (1) cross-links are modeled as barriers which require the motor to pay an energy penalty in order to break it. (2) The motor can stretch the cross-links which therefore constitute as an additional friction factor. Each option gives a different prediction regarding the different attributes of the motor-cargo movement such as the step size, step time etc.

Another aspect of the reciprocal effect between motor and environment is the question whether motor-cargo movement can cause sufficient drag force as to cause micro-streams in the intracellular fluid as detected in plant cells.

העבודה נעשתה בהנחיית דר' אורי נבו , המחלקה להנדסה ביו-רפואית, אוניברסיטת תל-אביב