The Council of the Technion, chaired by Danny Yamin, CEO of Microsoft Israel, appointed three new members from the public sector to the Committee.

Dana Maor, CEO of McKinsey & Co. Tel-Aviv Office, holding an MBA from MIT (Massachusetts Institute of Technology), and graduate of Technion’s Faculty of Computer Science. Between the years 1998-2008, Maor worked at the McKinsey New York offices as a consultant for giant American conglomerates, and in 2006, became a partner in the Consulting Group.

Pinhas Buchris, CEO of Oil Refineries Ltd. (ORL) – in Hebrew Bazan, served as commanding officer for the 8200 Unit holding the position of Brigadier General, and as the General Manager of the Israeli Ministry of Defense. When he was relieved of his duties in the IDF, Buchris became a partner in the APEX Investment Fund in Israel and held the position of Director of various public companies. Buchris completed the Advanced Management Program (AMP) at the Harvard University Business School, graduated from the MBA program of the Israel Branch of the University of Derby Business School, and received his B.Sc. from Technion’s Faculty of Computer Science.

Itzik Torgeman, CEO/Executive Vice President and General Director of the Rashi Foundation, Colonel in the IDF Reserves Corps, served as electronic engineer in a number of technology and administrative roles in the Research and Development Unit of the Intelligence Corps. For his many initiatives and achievments Torgeman was awarded the Israel Security Award in 1988 and the Head of IDF Intelligence Prize for Creative Thinking in 1999, and in 2003 he was awarded an honorary fellowship from the Technion. Torgeman holds a B.Sc. in electrical and electronics engineering, an MBA from the Ben-Gurion University of Beer Sheva/ the Negev, and holds an M.Sc. in Quality Assurance and Reliability from Technion’s Department of Nuclear Engineering.

Danny Yamin, CEO of Microsoft Israel and Chairperson of the Steering Committee of the Technion: “We are filling Technion’s Steering Committee with well-known champions in the Israeli public sector. The future of the country is increasingly hinged on quality technological education, and there is no doubt in my mind that the experience, knowledge and skills of our three new members will contribute greatly to the influence and future of the Technion, and to the scope and quality of its graduates. I congratulate Dana Maor, Pinhas Buchris, and Itzik Torgeman on their appointment to the Committee, and wish them all the best in their new roles they have agreed to take on.”

The Technion and AMIT (Alfred Mann Institute at the Technion) have established a new company for commercialization of stem cell technologies developed for over  a  decade at the stem cell research center headed by Professor Joseph Itskovitz-Eldor from the Bruce and Ruth Rappaport Faculty of Medicine. Professor Itskovitz-Eldor is a pioneer and a world leader in the field of stem cell research.

The company, Accellta, will market technologies  that will enable commercial companies and research laboratories to culture masses of homogenous stem cell lines in a fast and cost-effective manner. The innovative technologies, developed by Professor Itskovitz-Eldor and Dr. Michal Amit, a senior researcher at the stem cell research center, address the need for employing genetic manipulation of the cells; although a highly desirable procedure, the latter is currently associated with poor outcomes. The revolutionary technologies introduced by Accellta enable to successfully manipulate the cells and thus enhance the development of prospective stem cell-based therapies and disease models. In the future the company will also focus on regenerative medicine solutions and stem cell-based therapeutics for currently incurable diseases.

Professor Itskovitz-Eldor, Chair of the Department of Obstetrics and Gynecology at Rambam Health Care Campus and Director of the Stem Cell Center at the Technion, is internationally recognized as one of the founders of the field of stem cell research. In 1998, in collaboration with Professor James Thomson from the University of Wisconsin, he isolated the first human embryonic stem cells (hESCs), which is considered one of the most important scientific breakthroughs in medical history. In the same year, he established the first stem cell research laboratory in Israel, and currently holds the largest number of scientific publications in the field of hESCs.

Since 1998, Professor Itskovitz-Eldor and Dr. Michal Amit have developed advanced stem cell technologies,  including xeno-free and defined growth media, cell culturing scale-up methods,  genetic manipulation techniques and protocols for induced differentiation of the cells into desired cell types; All of which fundamental to screening and testing of new therapeutic compounds. The Technion invested in a broad portfolio of patents to protect these promising inventions .

Accellta will operate in the global stem cell market, estimated at 2 billion dollars and double-digit annual growth. The market comprises mostly of products and services for stem cell research and development, as most stem cell technologies are still in development and have not yet been authorized for clinical use in humans. The stem cell market is expected to skyrocket in the coming years, once treatments currently under clinical evaluation receive approval from health authorities.

The Alfred Mann Institute at the Technion – AMIT, has been operating since 2006 to accelerate the development and commercialization of selected biomedical technologies invented by Technion scientists. The institute was founded by the initiative of American billionaire, Dr. Alfred Mann, who funds its activities and serves as Chairman of the Board of Directors. In addition to Accellta, AMIT also manages four other ventures, three of which have become start-up companies.

According to Professor Itskovitz-Eldor, “The Company’s activities will facilitate the adoption by industrial and clinical entities of some of the world’s most innovative and advanced technologies for culturing pluripotent stem cells (both embryonic and induced). These unique cells have the ability to generate any cell type of the human body.  Our novel methods can also be used as a platform for the production of proteins and antibodies as well as for screening of novel therapeutics across a wide range of  diseases. Accellta has already started establishing collaborations with a number of international companies.”

Cells in the fetal Amnion membrane, which make up part of the amniotic sac, and protects the fetus throughout the pregnancy period, may be a new source for human eggs

Technion researchers from the Bruce and Ruth Rappaport Faculty of Medicine found that cells in the fetal Amnion membrane may be a source of human eggs, according to dissertation of doctoral student Ayelet Evron mentored by the Dean of the Faculty, Professor Eliezer Shalev.

Amnion membranes constitute a part of the inner layer of the amniotic sac, which protects the fetus throughout the pregnancy period. Typically, upon being ruptured during the birth, directly after birth both the expelled placenta and membranes get thrown out.

Amnion membrane cells develop at the very early stages of the life of the fetus (on the eighth day after fertilization) and are known to maintain the plasticity of embryonic cells prior to cellular differentiation. These cells have the potential of joining any one of the cell groups that later develop into different tissues in the body. To date, the capability of Amnion membrane cells to differentiate into germ cells with specific gene markers that develop into human eggs, has never been documented.

The research work was undertaken in collaboration with Dr. Shlomit Goldman at the research laboratory of Women’s Division of Gynecology and Obstetrics in the Emek Medical Center (in Afula). It uncovered for the first time that when growing hamnion membrane cells on growth medium also used in IVF (in vitro fertilization), these cells display specific signs of gene expression like those of germ cells, which develop into human eggs, at both the gene and protein levels, as well as in appearance (resembling large round cells that resemble eggs). Later, the cells express markers that mimic the characteristic of markers in human egg development, which enable division reduction upon entry (division that is essential in human egg development), and remain in this state.

Researchers still face a major challenge – for these cells to be used in substitute of human eggs, they need to properly complete the reduction process upon entry.  Only after finding a solution to this problem it will be possible to check whether or not Amnion membrane cells may be used as a new source for human eggs that would be suitable for women who cannot produce them on their own.

4337 young men and women from Russia to study information technology security at Technion

In October of this year, some 37 young men and women from Russia began their studies in information technology security at Technion. This is a newly established joint project by the university’s Division of Continuing Education & External Studies and “Nativ”. At the end of the five-month course, graduates will receive an Information Security Manager certificate.

Professor Yehudit Dori, the Dean of the Division of Continuing Education & External Studies of the Technion, said that this group includes undergraduate students from Russia and the former Soviet Union. They earned bachelor’s degrees in computer science, economics, information systems and the like, and have come to Technion to obtain their CISM certification, a new five month course taught in Russian.

According to Professor Dori, “In the first group we expected an enrollment of only 20, but 37 came.” She added that, “Right from our first meeting I was very impressed with the high caliber of people in the program, and have since met with them at least once a month. The interaction with the students has been tremendous, and this led me to propose that they stay on for another five months at the Technion, and some 70 % immediately agreed. I offered them an opportunity to set-up a mentoring program as a follow up to the course, which would consist of weekly one to two-day hands-on industry experience in coordination with industrialist Mr. Yehuda Zisapel, who stood at the head of the Technion Alumni Association for six years. This proposition immediately spiked further interest, with 100% in favor for staying on for this mentoring program. All of the students are eligible to make aliyah under The Law of Return.”

At present, Dr. Niva Vengrovitz, a post-doctoral student in the Department of Education in Technology and Science at Technion, is setting-up connections for students in the industry; all of the students placed in the Israeli industry continuing education program will continue to the second phase of the project.

The director of “Nativ” Ms. Naomi Ben Ami, former Israeli ambassador to the Ukraine, said that the Technion course is run through the framework of the MASA Program, which brings thousands of students and academics from the Former Soviet Union to study in Israel.  “We reveal to them a country with much to offer, in terms of knowledge and professional attainment, blended with a Jewish identity,” she emphasized. “Continued Aliyah to Israel is important for us, as is the human quality of our new immigrants. Participants in the Technion course are of especially high caliber.”

The students receive a monthly scholarship, learn at a Hebrew Ulpan, take English conversation lessons, live in the university’s dorm rooms and given guided tours around the country. They are also involved in volunteering works in the community, at retirement homes, kindergartens and charity organizations.

Mr. Oded Raviv, the Head of the Division of Continuing Education & External Studies at Technion, and Ms. Ella Blinderman, the Division’s Project Manager, said that about 80% of the participants in the course are academics, with 30 men and seven women enrolled in the program. “Many of them already notified us of their plans to stay in Israel at the end of the course and are looking into making Aliyah. We have no doubt that by the end of the second stage of the program, which will expand further on technology aspects and expose students to more Hebrew and English – that most of them will decide to settle in Israel permanently,” added Blinderman.

Ms. Irit Frommer-Kfir, the Head of Content and Activity Development at Nativ, said that the first stage of the course was taught entirely in Russian, and that in light of the success of the program – the planning of a follow-up course in March 2013 is in the making. She expressed hope that in the summer of 2013, a course for high-school graduates from Russia will be offered, in cooperation with the Technion International School, to encourage students to enroll into undergraduate engineering studies at the university.

Above: The photo shows course participants, taken by Technion’s Spokesperson’s Office

Applying a conceptual modeling language developed over a decade ago, they depict complex biological systems both diagrammatically and textually in a formal yet intuitive way and at any desired level of detail

Technion researchers modeled the lifecycle of yeast mRNA, which transports genetic code from the nucleus to the ribosome for building proteins. Their novel method makes use of Object-Process Methodology (OPM), a holistic conceptual modeling paradigm that uses objects and processes as the only two building blocks of the universe. OPM, invented over fifteen years ago by Professor Dov Dori from the Faculty of Industrial Engineering and Management, is in advanced stages of becoming the first conceptual modeling language which is an ISO standard.

Recently, Professor Dori has teamed up with Mordechai Choder, a molecular biologist from the Bruce and Ruth Rappaport Faculty of Medicine. Jointly mentoring Ms. Judith Somekh, a PhD candidate about to complete her dissertation, they built a conceptual model consisting of hundreds of objects and processes at eight levels of detail that describes key aspects of the mRNA lifecycle, which is responsible for gene expression. “It’s like a gigantic puzzle with vast amounts of information that has accumulated over years of meticulous research by thousands of researchers”, explains Professor Dori. “The model we built allows for an overall conceptual view of this subsystem and for testing it via qualitative simulation of the model.”

The model is based on dozens of published studies made on many pieces of this “puzzle” that together form an overall picture of major parts of the mRNA lifecycle subsystem. The research paper was published in the open access journal PloS ONE. In the process of building the model, the team – professors Dori and Choder and Judith Somekh – found and classified knowledge gaps in the system. Identifying such gaps can assist scientists in pinpointing specific aspects such as unknown mechanism or substances whose resolution requires design and execution of “wet lab” experimentation to verify or refute conjectured facts, and update the model accordingly. While systems biology has been a subject of much research in recent year, this approach has opened conceptual model-based systems biology as a new research area within systems biology.

1The Technion decides that a lecturer who does not meet the standards of good teaching – can no longer teach required courses

The Yanai Award for Excellence in Academic Education has been awarded to ten Technion lecturers. This is the second year that the award is being awarded for significant contribution to the advancement of academic education, “in tribute and appreciation of the exemplary contribution of the academic faculty members to teaching and learning, and for their efforts to strengthen involvement and sense of belonging of students at the Technion”.

The ten faculty members who received the award this year are: Eli Aljadeff, Yoram Halevi, Yoram Tambour, Oded Rabinovitch, Avigdor Gal, Erez Petrank, Uri Peskin, Gitti Frey, Isaac Keslassy and Yoav Arava.

Technion President Prof. Peretz Lavie said in the festive ceremony that online academic courses have recently become highly popular. “This is indeed a significant revolution in academic education, but these courses cannot replace the strong bond created between a good lecturer and his student”, Prof. Lavie emphasized. “A good teacher gives of himself, reads the body language of his students, supports and guides them. The consistent thread running among the winners of the Yanai Award is love for the student and love for the profession”.

Executive Vice President for Research of the Technion, Prof. Gadi Schuster, disclosed in the ceremony that the Technion has recently resolved that a lecturer who does not meet the standards of good teaching – can no longer teach required courses. Chair of the Technion Student Association, Assaf Zinger, said in response that he is amazed at this decision of the Technion and is thrilled with it, as it is joyous news for all students.

Moshe Yanai, a worldwide data storage pioneer, said that with his donation he wanted to repay the Technion somewhat in tribute and appreciation of the tools for life that the institute has given him during his studies there forty years ago. Having remembered that period as a difficult and even traumatic one at times, he decided, in consultation with Prof. Lavie, to donate 12 million dollars that will be awarded to lecturers who are excellent educators, thus contributing to students at the Technion.  The award, in the amount of NIS 100 thousand per lecturer, will be awarded over twenty years. “This is the second year that the award is being given, and it is highly satisfying to see how the winners, who are excellent educators as is, seem to stir their colleagues to do the same”, said Mosh Yanai in the ceremony.

Above: The winners with Technion President Prof. Peretz Lavie (at the center, to the right of the sign), and with Rachel and Moshe Yanai (at the center, to the left of the sign). Photo: Yoav Bachar, Technion Spokesman.

This is a significant scientific breakthrough that represents an effective solution to a major problem in organic synthesis that has, yet, never been resolved, and which could lead to large-scale reductions in pharmaceutical industry processes

Technion researchers found a novel solution to a major problem in organic synthesis that has to date never been resolved, despite worldwide intensive efforts. The Technion team successfully prepared a new molecular framework possessing a challenging asymmetric center in a single chemical step from easily available starting materials. Until now, by lack of available efficient strategies, very few attempts were made and they were all based on long and tedious approaches. This is a significant scientific breakthrough in synthesis, which could lead to a considerable reduction in the production of pharmaceuticals. This groundbreaking discovery is reported by the popular scientific journal “Nature.”

“Synthetic organic synthesis is a science that deals with the building of complex organic molecules from simpler elements,” explains Professor Ilan Marek from the Schulich Faculty of Chemistry at Technion, whose team of researchers were responsible for this major breakthrough. “One of the greatest applications of this new approach is a quick and efficient synthesis of complex natural materials that may be used in pharmaceutical industry. It must be the goal of the 21st century to accomplish more with less. In today’s society, no one can afford to follow the inefficient route of long and tedious synthesis. We should think organic synthesis differently and I am sure that new transformations that were not possible to perform by conventional methods will soon appear” continues Professor Marek.

Although, there are still molecular frameworks that are extremely challenging to prepare, the real question of the 21st century is no longer “can we synthesize this molecule”, but rather “how can we synthesize it efficiently, using the fewest number of steps, with optimum convergence, with as little as possible functional group transformations, little or no by-products and maximum atom-efficiency and at minimal cost.” Over the years, Professor Marek’s research team developed several innovative new synthetic methods that not only fulfilled these requirements, but also gave solutions to challenging problems in organic synthesis.

One of these critical challenges is the formation of chiral all-carbon quaternary stereogenic centers in acyclic systems. A chiral molecule is a type of molecule that has a non-superposable mirror image. Human hands are perhaps the most universally recognized example of chirality: the left hand is a non-superposable mirror image of the right hand; no matter how the two hands are oriented, it is impossible for all the major features of both hands to coincide. This difference in symmetry becomes obvious if someone attempts to shake the right hand of a person using his left hand, or if a left-handed glove is placed on a right hand. This characteristic is also present in organic molecules and two mirror images of a chiral molecule are called enantiomers.

Many biologically active molecules are chiral, including the naturally occurring amino acids (the building blocks of proteins) and sugars. In biological systems, most of these compounds are of the same chirality and understanding the origin of chirality may shed some light on the origin of life. In many cases, both enantiomers of a specific material can affect the human body in completely different ways, and therefore understanding these chiral molecular characteristics is of great importance for the pharmaceutical and food industries. The most infamous case of medical disaster was caused by a misunderstanding of the different pharmacological characteristics of two enantiomers of the same material, known as Thalidomide which caused severe birth defects. Many infants were born without limbs because the drug Thalidomide, which was administered to their mothers, could in-vivo interconvert the two enantiomers.

In the context of building molecules, the aldol reaction is one of the most versatile carbon-carbon bond formation processes available to synthetic chemists but also a critical biological reaction in the context of metabolism. However, coming back to efficiency, the aldol reaction combines only two components with the creation of only one new carbon-carbon bond per chemical step. As discussed previously, better efficiency is now necessary in organic synthesis in which several new carbon-carbon bonds should be formed. Moreover, the construction of chiral all-quaternary carbon centers could not be achieved in the previously aldol-based methodologies. In the most recent report published in Nature by Professor Marek and his colleagues, a very efficient solution to this problem has been reported through a completely different approach. In a single-pot operation, starting from classical hydrocarbons, the formation of aldol products containing the desired all-carbon quaternary stereocenter have been prepared through the concomitant formation of three new bonds. This groundbreaking discovery represents an innovative solution to a challenging synthetic problem.

For the development of original synthetic approaches, Professor Ilan Marek received the prestigious Royal Society Chemistry Organometallic Award (2011) and in 2012 the Janssen Pharmaceutica Prize for Creativity in Organic Synthesis.

42Scientists from Technion and the University of Colorado, Boulder have taken a closer look at how stars systems and their planets grow old together.

The influence of stellar aging on systems composed of three stars in orbit about each other is particularly intriguing. Binary stars systems where one of the stars is orbited by a planet, react similarly to stellar maturation. Stars and planets in these systems can change orbital partners. In some cases, they may even collide or be expelled from the star system all together. This wild and turbulent scenario may have produced of the brightest star system in the sky, Sirius A and B. These findings raise the possibility that collisions between stars are more common (at least 30 times over) than conventional wisdom has shown.

Most stars either live a solitary existence, or pair up with one other star to make a binary system. However 15 percent of all stars orbit at least two other stars, forming a triple star system. Similarly, planets can be “hosted” by a binary system, which then behave much like a triple star system except that one object is vastly smaller than the other two. The evolution of stars in these systems can generate dramatic outcomes. The aging process of stars involves many major changes: a star can expand to a circumference greater than hundreds of times its original size, and then lose most of its mass in intense winds. At the end of this process the stellar core, a white dwarf, is all that is left behind.  While much work has been devoted to understanding the evolution of single and binary star systems, studies on the evolution of triple stars are novel As is evident in the most recent research of Prof. Hagai Perets from the Faculty of Physics at Technion University, and Dr. Kaitlin Kratter from CU-Boulder, triple-star systems and their evolution are deserving of more interest. “Binary stars are systems that are generally stable,” says Perets. “The triple-star systems, on the other hand, are much more fragile,” and thus susceptible to disruption.

When mass is lost from one star during the ageing process, all of the orbits in the system change. These changes can induce dynamical instability, driving the system into a wild dynamic ‘dance,’ whereby the stars exchange partners until one of them gets expelled from the system altogether. Because the mass losing star begins to swell as it ages, it becomes a large target, significantly increasing its chances of crashing into another star in the midst of its wild ‘dance.’

Ordinarily, stars only collide in dense star clusters (systems with millions of stars packed into a volume of only a few cubic light years; for comparison, within the same volume in the neighbourhood of the Solar system there is only one star – the sun). Even in these dense clusters, the probability of a collision is very low.

“We discovered that when it comes to triple star systems, there is a different picture all together. Star collisions outside of dense star clusters can occur at a rate of 30 times higher in comparison to those coincidental collisions that occur within star clusters,” says Perets.

An answer to a Sirius mystery

According to Perets and Kratter, this type of chaotic evolution may be relevant to one of the best known stars, Sirius – the brightest star in the sky.  Sirius is accompanied by a white dwarf in a binary system, but on a very eccentric orbit. This configuration is unusual for a star in a close orbit to a white dwarf; astronomers normally expect such orbits to be nearly circular, due to the exchange of mass between the stars as they age. The most recent findings show that this strange configuration may be explained if the Sirius binary system is the remnant of a triple system that became unstable and lost a star. “This surprising revelation that the triple evolution scenario we studied could solve the decades old mystery related to our brightest night-time star, Sirius, is very exciting; it appears that Sirius had a much wilder history than we could have ever imagined,” adds Perets.

Planetary “star-hoppers”

What would you do if your neighbourhood started to deteriorate? Would you consider moving to a better neighbourhood? It seems as if planets might make the same decision. Kratter and Perets also investigated systems where one of the three elements is not a star but a planet. Much like the case with three stars, mass loss by the planet-host can drive the planet into an unstable, chaotic orbit. The outcome, says Kratter, is surprising. “A planet can actually change which star it orbits, bouncing back and forth between the two.” Sometimes, such a star-hopper will settle down into a new, stable orbit around the companion star.  More often, this story has an unhappy ending. It is more likely that the planet will collide with one of the two stars during its voyages between the two. Such a collision would obliterate the planet.

41Will serve researches from all universities, as well as the high-tech industry

The Technion has purchased the most advanced scanning electron microscope in Israel, at a cost of 1.3 million dollars. Dean of the Faculty of Materials Science and Engineering, Prof. Wayne D. Kaplan, said that this is a substantial contribution to the learning process at all levels, and that the microscope will serve all researchers in Israel, as well as the high-tech industry.

The microscope has sophisticated detectors that not only provide extremely high resolution, but also provide direct information about the material composition and local defects. It has a heating system with temperatures of up to 1100 degrees Celsius, which allows researchers to carry out manufacturing processes in-situ in the microscope, and to directly characterize changes to a material during a specific manufacturing process. Thus, for example, one can directly see solidification of a molten alloy inside the microscope, or track the mechanism by which thin films break-up or agglomerate into individual particles during thermal treatments. “With this innovative microscope, we can follow the process and discover how to prevent agglomeration, or utilize it”, emphasizes Prof. Kaplan. “Thus we developed, together with Prof. Gadi Eisenstein of the Department of Electrical Engineering, new flash memories with a stability and working range that are not currently available, and that are based on tiny platinum particles 4-5 nanometers in size. We produced these particles at the desired size and form, by following the agglomeration process of a continuous layer inside the microscope. This provides us with engineering criteria that we have not had to date”.

Dr. Alex Berner and Michael Kalina are responsible for the operation of the advanced microscope, which is part of the Technion’s advanced Electron Microscopy Center, and for related training.

Above: Inaugurating the innovative microscope. From right to left: Nobel Laureate in Chemistry Prof. Dan Shechtman, Technion Executive Vice President for Research Prof. Oded Shmueli,  and Prof. Wayne D. Kaplan. Photo: Yoav Becher, Technion Spokesman

40Using the power of the sun and ultrathin films of iron oxide (commonly known as rust), Technion-Israel Institute of Technology researchers have found a novel way to split water molecules to hydrogen and oxygen.  The breakthrough, published this week in Nature Materials, could lead to less expensive, more efficient ways to store solar energy in the form of hydrogen-based fuels.  This could be a major step forward in the development of viable replacements for fossil fuels.

            “Our approach is the first of its kind,” says lead researcher Associate Prof. Avner Rothschild, of the Department of Materials Science and Engineering. “We have found a way to trap light in ultrathin films of iron oxide that are 5,000 thinner than an office paper. This enables achieving high solar energy conversion efficiency and low materials and production costs. ”

Iron oxide is a common semiconductor material, inexpensive to produce, stable in water, and – unlike other semiconductors such as silicon – can oxidize water without itself being oxidated, corroded, or decomposed.  But it also presents challenges, the greatest of which was finding a way to overcome its poor electrical transport properties. “For many years researchers have struggled with the tradeoff between light absorption and the separation and collection of the photogenerated charge carriers before they die out by recombination,” says Prof. Rothschild. “Our light-trapping scheme overcomes this tradeoff, enabling efficient absorption in ultrathin films wherein the photogenerated charge carriers are collected efficiently. The light is trapped in quarter-wave or even deeper sub-wavelength films on mirror-like back reflector substrates. Interference between forward- and backward-propagating waves enhances the light absorption close to the surface wherein the photogenerated charge carriers are collected before recombination takes place.”

The breakthrough could make possible the design of inexpensive solar cells that combine ultrathin iron oxide photoelectrodes with conventional photovoltaic cells based on silicon or other materials to produce electricity and hydrogen.  According to Prof. Rothschild, “these cells could store solar energy for on demand use, 24 hours per day.”  This is in strong contrast to conventional photovoltaic cells, which provide power only when the sun is shining (and not at night or when it is cloudy).

The findings could also be used to reduce the amount of rare elements that the solar panel industry uses to create the semiconductor material in their second-generation photovoltaic cells.  The Technion team’s light trapping method could save 90% or more of rare elements like Tellurium and Indium, with no compromise in performance.