News & Events


What Is the Future of Wind Energy?


Humans have used windmills to capture the force of the wind as mechanical energy for more than 1,300 years. Unlike early windmills, however, modern wind turbines use generators and other components to convert energy from the spinning blades into a smooth flow of AC electricity. In this video, John Dabiri, Centennial Professor of Aeronautics and Mechanical Engineering discusses the future of wind energy technology. [Caltech story]

Tags: research highlights GALCIT MCE John Dabiri

CE10 Aims to Develop the Roadmap Toward a 50 Percent Reduction in U.S. Global Warming Gas Emissions by 2032


How do we cut U.S. global warming gas emissions by 50 percent within the next 10 years? This question represents the bold target set by President Biden in 2020 to secure U.S. leadership on clean energy technologies by the end of the decade. However, with energy production and consumption in the U.S. intertwined among political, ideological, and technological complexities, the path toward a cleaner energy future remains unclear. The Caltech Energy 10 Project (CE10) aims to define the ambitious but achievable solutions needed to cut U.S. global warming gas emissions in half by 2032. Visit the CE10 website for more detail, a full schedule of speakers, and a link to register for the public program. [Caltech story]

Tags: research highlights

Professor Goddard and Team Find the Simplest Form of a Catalyst


William A. Goddard, Charles and Mary Ferkel Professor of Chemistry, Materials Science, and Applied Physics, is part of research team which finds that an electron is the simplest form of a catalyst. A catalyst is a substance that speeds up a chemical reaction by lowering the barriers from reactants to products. Traditionally, most catalysts contain transition metal as the source of activity. The most recent Nobel Prize in chemistry was awarded to Benjamin List and David W.C. MacMillan for the discovery of pure organic compounds as catalyst for asymmetric organic synthesis. Is there any catalyst simpler than small organic compounds? Yes, in an article published in the latest edition of Nature, a team of Northwestern University and Caltech discovered that an electron itself can play the role of catalyst for the process of molecular recognition. [Nature Article]

Tags: APhMS research highlights William Goddard

Chaining Atoms Together Yields Quantum Storage


Engineers at Caltech have developed an approach for quantum storage that could help pave the way for the development of large-scale optical quantum networks. "The ability to build a technology reproducibly and reliably is key to its success," says graduate student Andrei Ruskuc. "In the scientific context, this let us gain unprecedented insight into microscopic interactions between ytterbium qubits and the vanadium atoms in their environment." The new system relies on nuclear spins—the angular momentum of an atom's nucleus—oscillating collectively as a spin wave. This collective oscillation effectively chains up several atoms to store information. "Based on our previous work, single ytterbium ions were known to be excellent candidates for optical quantum networks, but we needed to link them with additional atoms. We demonstrate that in this work," says Andrei Faraon, Professor of Applied Physics and Electrical Engineering. [Read the paper] [Caltech story]

Tags: APhMS EE research highlights MedE KNI Andrei Faraon Andrei Ruskuc

Professor Anandkumar Tackles COVID-19 with AI


A pair of papers coauthored by Anima Anandkumar, Bren Professor of Computing and Mathematical Sciences, were selected as finalists for the 2021 Association for Computing Machinery (ACM) Gordon Bell Special Prize for High Performance Computing-Based COVID-19 Research. The purpose of the award is to recognize the innovative parallel computing contributions towards the solution of the global crisis. "All the six finalists this year had some component in their calculations that used AI," Anandkumar says. "This has enabled unprecedented understanding of the coronavirus that would not have been possible with conventional tools." [Caltech story]

Tags: research highlights CMS Animashree Anandkumar

Nano-architected Material Refracts Light Backward—An Important Step Toward One Day Creating Photonic Circuits


A newly created nano-architected material exhibits a property that previously was just theoretically possible: it can refract light backward, regardless of the angle at which the light strikes the material. "Negative refraction is crucial to the future of nanophotonics, which seeks to understand and manipulate the behavior of light when it interacts with materials or solid structures at the smallest possible scales," says Julia R. Greer, Ruben F. and Donna Mettler Professor of Materials Science, Mechanics and Medical Engineering; Fletcher Jones Foundation Director of the Kavli Nanoscience Institute. [Caltech story]

Tags: APhMS research highlights MedE MCE Harry Atwater Julia Greer Victoria Chernow Siying Peng Ryan Ng

Professor Wennberg Named as AAAS Fellow


Paul O. Wennberg, R. Stanton Avery Professor of Atmospheric Chemistry and Environmental Science and Engineering; Executive Officer for Environmental Science and Engineering; Director, Ronald and Maxine Linde Center for Global Environmental Science, has been named as a fellow of the American Association for the Advancement of Science (AAAS) for major scientific advances in atmospheric chemistry. AAAS Fellows are a distinguished cadre of scientists, engineers, and innovators who have been recognized for their achievements across disciplines, from research, teaching, and technology, to administration in academia, industry, and government, to excellence in communicating and interpreting science to the public. [Caltech story]

Tags: honors ESE Paul Wennberg

Wennberg Lab Shows How Wildfire Smoke Increases Ozone Pollution


Using data gathered from a specially equipped jet that spent a month flying through and studying wildfire plumes, scientists have a better understanding now of how wildfire smoke impacts air quality. "Of course it is well known that wildfires lower air quality. But it's important to understand the chemical and physical mechanisms by which they do so that we can more effectively forecast how individual fires will impact the communities downwind of them," says Paul O. Wennberg, R. Stanton Avery Professor of Atmospheric Chemistry and Environmental Science and Engineering; Executive Officer for Environmental Science and Engineering; Director, Ronald and Maxine Linde Center for Global Environmental Science. [Caltech story]

Tags: research highlights ESE Paul Wennberg Lu Xu

Gunnarson and Dabiri Teach AI to Navigate Ocean with Minimal Energy


Engineers at Caltech, ETH Zurich, and Harvard are developing an artificial intelligence (AI) that will allow autonomous drones to use ocean currents to aid their navigation, rather than fighting their way through them. "When we want robots to explore the deep ocean, especially in swarms, it's almost impossible to control them with a joystick from 20,000 feet away at the surface. We also can't feed them data about the local ocean currents they need to navigate because we can't detect them from the surface. Instead, at a certain point we need ocean-borne drones to be able to make decisions about how to move for themselves," says John Dabiri, Centennial Professor of Aeronautics and Mechanical Engineering. [Caltech story]

Tags: research highlights GALCIT MCE John Dabiri Peter Gunnarson

Controlling Light with a Material Three Atoms Thick


Scientists can control light more precisely than ever with a material only three atoms thick and constructed from so-called black phosphorous. In the lab of Harry Atwater, Otis Booth Leadership Chair, Division of Engineering and Applied Science; Howard Hughes Professor of Applied Physics and Materials Science; Director, Liquid Sunlight Alliance, three layers of phosphorous atoms were used to create a material for polarizing light that is tunable, precise, and extremely thin. Black phosphorous tech could revolutionize telecommunications by vastly improving light signals sent through fiber-optic cables. The technology could also open the door to a light-based replacement for Wi-Fi, something researchers in the field refer to as Li-Fi. "Increasingly, we're going to be looking at light-wave communications in free space," Atwater says. "Lighting like this very cool-looking lamp above my desk doesn't carry any communication signal. It just provides light. But there's no reason that you couldn't sit in a future Starbucks and have your laptop taking a light signal for its wireless communication rather than a radio signal. It's not quite here yet, but when it gets here, it will be at least a hundred times faster than Wi-Fi." [Caltech story]

Tags: APhMS research highlights Harry Atwater KNI