School of Mechanical Engineering Seminar
January, May 5, 2014 at 15:00
Wolfson Building of Mechanical Engineering, Room 206

Solar electricity with photon-enhanced thermionic emission (PETE)

Prof. Abraham Kribus

School of Mechanical Engineering, Faculty of Engineering

Tel Aviv University, Israel

The efficiencies of photovoltaic and thermal conversion of solar energy are both limited by thermodynamics, and by the complexity required in real conversion devices. A novel third alternative of photon-enhanced thermionic emission (PETE) offers an intriguing synergy of direct photonic conversion together with thermal conversion, and theoretically may reach efficiency exceeding 70%. However, realizing this conversion path requires a major multi-disciplinary effort in semiconductor physics, surface science, thermal science, and systems engineering.
A PETE converter consists of a semiconductor cathode with a bandgap that is matched to the solar spectrum, and an anode separated by a vacuum gap. Illuminating the cathode with concentrated solar radiation increases the conduction band electron population and reduces the energy barrier to electron emission by two mechanisms: increasing temperature due to heating by thermalization, and photo-generation that increases the electron concentration above its equilibrium level. Coating the cathode with a material that lowers the electron affinity can further reduce the barrier to emission. Hence, PETE devices utilize both photonic and thermal processes for energy conversion. The anode receives electrons from the cathode, and is heated by thermalization of these electrons. This waste heat is removed from the anode by an external heat exchanger. It is possible to use this heat to drive a secondary thermal cycle (e.g., heat engine or thermoelectric converter) to generate additional electricity and increase the overall device efficiency. A theoretical analysis of the ideal performance limits shows that under 1,000 suns, efficiency of the two-stage PETE and thermal conversion can exceed 70%, higher than ideal PV cells and higher than ideal thermal conversion. Practical implementation, however, is not easy. Several major challenges related to materials and device engineering will be discussed. Much further research, as well as engineering ingenuity, are needed to resolve both the materials issues and the device level design challenges, on the path to realize the promise of PETE conversion. 

You are invited to attend a guest lecture

By

Christian Rosenberg Petersen

(Visiting the group of Prof. Moshe Tur)

Ph.D. student under the supervision of Prof. Ole Bang

Department of Photonics Engineering, Technical University of Denmark,
DK-2800 Kgs. Lyngby, Denmark

Mid-IR supercontinuum generation in chalcogenide fibers for applications in the molecular fingerprint region

The mid-infrared spectral region is of great interest because most molecules display fundamental vibrational absorptions herein, leaving distinctive spectral fingerprints for applications in e.g. spectroscopy, fluorescence microscopy, optical coherence tomography and hyper-spectral imaging. However, many mid-infrared sources are limited either in brightness, wavelength range or coherence, such as thermal emitters, or inconvenient and bulky, such as synchrotron sources. In this presentation we discuss the development of mid-infrared supercontinuum sources based on chalcogenide fibers, which have recently been demonstrated to cover a wide wavelength range from 1.4 μm to 13.3 μm in just 8 cm of fiber. Development of a compact mid-infrared chalcogenide fiber-based supercontinuum source will have key importance for applications such as early detection of skin cancer, gas sensing and food quality control.

*Published in: Nature Photonics 8, 830–834 (2014)

Wednesday, November 19, 2014, at 13:00

Room 011