Current Event Articles: August 2021

Monday, August 30, 2021

New Report Shows Technology Advancement and Value of Wind Energy

Berkeley Lab research finds that societal value of wind is far in excess of costs

MEDIA RELATIONS | (510) 486-5183 | AUGUST 30, 2021

(Credit: inakiantonana/iStock)

Wind energy continues to see strong growth, solid performance, and low prices in the U.S., according to a report released by the U.S. Department of Energy (DOE) and prepared by Lawrence Berkeley National Laboratory (Berkeley Lab). With levelized costs of just over $30 per megawatt-hour (MWh) for newly built projects, the cost of wind is well below its grid-system, health, and climate benefits.

“Wind energy prices – particularly in the central United States, and supported by federal tax incentives – remain low, with utilities and corporate buyers selecting wind as a low-cost option,” said Berkeley Lab Senior Scientist Ryan Wiser. “Considering the health and climate benefits of wind energy makes the economics even better.”

Key findings from the DOE's annual “Land-Based Wind Market Report” include:

Wind comprises a growing share of electricity supply. U.S. wind power capacity grew at a record pace in 2020, with nearly $25 billion invested in 16.8 gigawatts (GW) of capacity. Wind energy output rose to account for more than 8% of the entire nation’s electricity supply, and is more than 20% in 10 states. At least 209 GW of wind are seeking access to the transmission system; 61 GW of this capacity are offshore wind and 13 GW are hybrid plants that pair wind with storage or solar.

Wind project performance has increased over time. The average capacity factor (a measure of project performance) among projects built over the last five years was above 40%, considerably higher than projects built earlier. The highest capacity factors are seen in the interior of the country.

Turbines continue to get larger. Improved plant performance has been driven by larger turbines mounted on taller towers and featuring longer blades. In 2010, no turbines employed blades that were 115 meters in diameter or larger, but in 2020, 91% of newly installed turbines featured such rotors. Proposed projects indicate that total turbine height will continue to rise.

Low wind turbine pricing has pushed down installed project costs over the last decade. Wind turbine prices are averaging $775 to $850/kilowatt (kW). The average installed cost of wind projects in 2020 was $1,460/kW, down more than 40% since the peak in 2010, though stable for the last three years. The lowest costs were found in Texas.

Wind energy prices remain low, around $20/MWh in the interior “wind belt” of the country. After topping out at $70/MWh for power purchase agreements executed in 2009, the national average price of wind has dropped. In the interior “wind belt” of the country, recent pricing is around $20/MWh. In the West and East, prices tend to average $30/MWh or more. These prices, which are possible in part due to federal tax support, fall below the projected future fuel costs of gas-fired generation.

Wind prices are often attractive compared to wind’s grid-system market value. The value of wind energy sold in wholesale power markets is affected by the location of wind plants, their hourly output profiles, and how those characteristics correlate with real-time electricity prices and capacity markets. The market value of wind declined in 2020 given the drop in natural gas prices, averaging under $15/MWh in much of the interior of the country; higher values were seen in the Northeast and in California.

The average levelized cost of wind energy is down to $33/MWh. Levelized costs vary across time and geography, but the national average stood at $33/MWh in 2020—down substantially historically, though consistent with the previous two years. (Cost estimates do not count the effect of federal tax incentives for wind.)

The health and climate benefits of wind in 2020 were larger than its grid-system value, and the combination of all three far exceeds the current levelized cost of wind. Wind generation reduces power-sector emissions of carbon dioxide, nitrogen oxides, and sulfur dioxide. These reductions, in turn, provide public health and climate benefits that vary regionally, but together are economically valued at an average of $76/MWh-wind nationwide in 2020.

The domestic supply chain for wind equipment is diverse. For wind projects recently installed in the U.S., domestically manufactured content is highest for nacelle assembly (over 85%), towers (60% to 75%), and blades and hubs (30% to 50%), but is much lower for most components internal to the nacelle.

Berkeley Lab’s contributions to this report were funded by the U.S. Department of Energy’s Wind Energy Technologies Office.

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Founded in 1931 on the belief that the biggest scientific challenges are best addressed by teams, Lawrence Berkeley National Laboratory and its scientists have been recognized with 14 Nobel Prizes. Today, Berkeley Lab researchers develop sustainable energy and environmental solutions, create useful new materials, advance the frontiers of computing, and probe the mysteries of life, matter, and the universe. Scientists from around the world rely on the Lab’s facilities for their own discovery science. Berkeley Lab is a multiprogram national laboratory, managed by the University of California for the U.S. Department of Energy's Office of Science.

DOE's Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit energy.gov/science.

www.lbl.gov

Thursday, August 26, 2021

ABPDU Celebrates a Decade of Bio-Innovation

The scale-up facility takes a look back at its success enabling the bioeconomy

MEDIA RELATIONS | (510) 486-6376 | AUGUST 18, 2021

A panoramic view of laboratory space inside the ABPDU facility, located in Emeryville, CA. (Credit: Roy Kaltschmidt/Berkeley Lab)

-By Emily Scott

Ten years ago, Lawrence Berkeley National Laboratory announced the opening of a brand new, 15,000-square-foot facility full of stainless steel state-of-the-art bioprocessing equipment – what we now know as the Advanced Biofuels and Bioproducts Process Development Unit, or ABPDU, was officially open for business.

Funded by the U.S. Department of Energy’s Bioenergy Technologies Office, ABPDU set out to provide a boost to the development of advanced biofuels – renewable fuels that produce at least 50% less greenhouse gas emissions than fossil fuels. ABPDU’s facility would serve as an industry-scale proving ground for biofuel discoveries made at lab bench-scale.

At the same time, the world of biotechnology was booming. A wave of new startups emerged, aiming to use the power of biology to create sustainable, bio-based products to replace those made with fossil fuels. Over time, ABPDU evolved to meet the needs of this industry, collaborating with companies and academic partners developing various bioproducts that affect our everyday lives.

Building up the bioeconomy

Over the years, ABPDU has helped dozens of collaborators scale-up innovative biotechnologies and transition them to the marketplace – from skis made with algae oil and sustainable indigo dye to waste-derived biofuel precursors and even COVID-19 testing and treatment technologies.

By utilizing ABPDU’s capabilities, small companies and startups don’t have to spend time and money building up their own facilities. Instead, they take advantage of ABPDU’s equipment and expertise to prove their technologies can scale to an industry level and generate prototype materials – important milestones to demonstrate to potential investors.

ABPDU has served as a resource for the Department of Energy (DOE) Bioenergy Research Centers, which are research partnerships focused on improving and scaling up advanced biofuel and bioproduct production processes, and collaborated with over 65 industry partners. Many of these partners have set up their own labs or pilot plants, secured additional funding, and launched their own products as a direct result of working with ABPDU.

“Working with ABPDU to validate our company’s technology and bioprocess at the pre-pilot scale, along with generating samples, has directly contributed to an agreement with a large strategic partner and traction with investors,” said Harshal Chokhawala, CEO and founder of ZymoChem, a biotech company that collaborated with ABPDU to scale up the production of a chemical made from renewable sources.

ABPDU has collaborated with over 65 industry partners, many of whom have gone on to secure funding from investors. For 29 of these companies, ABPDU was crucial to their success in generating prototypes and/or raising private investments. (Credit: Emily Scott/Berkeley Lab)

Training the next generation of bioprocess engineers

Over the last ten years, ABPDU has also become a desirable place to train for future careers in the bioeconomy. Working at ABPDU has jump-started the careers of dozens of scientists and engineers of various career stages, and has also provided early hands-on experience for college and high school student interns. Several internship alumni and former employees have gone on to work in the biotech industry, stating that the learning opportunities and mentorship they received at ABPDU were key to their success.

“I can’t stress enough how special and unique ABPDU is,” said Hunter Zeleznik, a former research associate at ABPDU who is now a strain development fermentation research associate at LanzaTech. “To be immersed in that environment and be exposed to so many different things is so valuable.”

Currently, the biotech industry faces a pressing need for experienced people who can bring bio-based products to market. To help meet this demand, ABPDU and UC Berkeley collaborated on the creation of a new course that gives students hands-on experience with bioprocessing equipment, preparing them for careers in the biopharmaceutical, industrial biotech, or food tech industries.

Part of UC Berkeley’s Master of Bioprocess Engineering program, the course takes place at ABPDU’s facility, where ABPDU staff train students on how to use equipment and perform bioprocessing experiments.

“Students at most universities usually don’t have the opportunity to work with the larger-scale equipment that we have at ABPDU,” said Deepti Tanjore, director of ABPDU. “This course provides students with a unique learning experience that you won’t be able to find elsewhere.”

A bright, sustainable future

As the field of biotechnology continues to grow at a rapid pace, ABPDU plans to evolve and adapt to meet the needs of this industry.

“We are well positioned to be able to take on new challenges as the biotech industry continues to innovate,” said Tanjore. “We regularly gather feedback from our industry partners and work to respond to this feedback, providing services and resources that prevent them from re-inventing the wheel and help them succeed.”

The U.S. bioeconomy, which is centered around reducing our dependence on fossil fuels, is valued at nearly $1 trillion and is poised to grow substantially, said Mary Maxon, who recently began a professional leave of absence from her position as Berkeley Lab’s Associate Laboratory Director for Biosciences.

“Through collaboration with ABPDU’s uniquely trained staff, companies can de-risk, scale, and optimize new processes quickly and flexibly,” Maxon said. “As innovations such as recyclable carbon sources expand the range of possibilities for a future circular economy, ABPDU is an increasingly valuable partner to bring these opportunities to market.”

These innovations will ensure that ABPDU can assist in achieving the goals of the broader bioeconomy.

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www.lbl.gov

LED Material Shines Under Strain

Berkeley Lab researchers devise a simple tactic to increase the efficiency of LED devices

MEDIA RELATIONS | (510) 486-5183 | AUGUST 26, 2021

Applying mechanical strain on this atomically thin, transparent monolayer semiconductor results in a material with near 100% light-emission efficiency. (Credit: Ali Javey/Berkeley Lab)

– By Rachel Berkowitz

Smartphones, laptops, and lighting applications rely on light-emitting diodes (LEDs) to shine bright. But the brighter these LED technologies shine, the more inefficient they become, releasing more energy as heat instead of light.

Now, as reported in the journal Science, a team led by researchers at Lawrence Berkeley National Laboratory (Berkeley Lab) and UC Berkeley has demonstrated an approach for achieving near 100% light-emission efficiency at all brightness levels.

Their approach focuses on stretching or compressing a thin semiconductor film in a way that favorably changes its electronic structure.

The team identified just how the semiconductor’s electronic structure dictated interaction among the energetic particles within the material. Those particles sometimes collide and annihilate each other, losing energy as heat instead of emitting light in the process. Changing the material’s electronic structure reduced the likelihood for annihilation and led to a near-perfect conversion of energy to light, even at high brightness.

“It’s always easier to emit heat than emit light, particularly at high brightness levels. In our work we have been able to reduce the loss process by one hundredfold,” said Ali Javey, a faculty senior scientist at Berkeley Lab and professor of electrical engineering and computer sciences at UC Berkeley.

LED performance depends on excitons

The Berkeley team’s discovery was made using a single, 3-atom-thick layer of a type of semiconductor material, called a transition metal dichalcogenide, that was subjected to mechanical strain. These thin materials have a unique crystal structure that gives rise to unique electronic and optical properties: When their atoms are excited either by passing an electric current or shining light, energetic particles called excitons are created.

Excitons can release their energy either by emitting light or heat. The efficiency with which excitons emit light as opposed to heat is an important metric that determines the ultimate performance of LEDs. But achieving high performance requires precisely the right conditions.

“When the exciton concentration is low, we had previously found how to achieve perfect light-emission efficiency,” said Shiekh Zia Uddin, a UC Berkeley graduate student and co-lead author on the paper. He and his colleagues had shown that chemically or electrostatically charging single-layered materials could lead to high-efficiency conversion, but only for a low concentration of excitons.

For the high exciton concentration at which optical and electronic devices typically operate, though, too many excitons annihilate each other. The Berkeley team’s new work suggests that the trick to achieve high performance for high concentrations lay in tweaking the material’s band structure, an electronic property that controls how excitons interact with each other and could reduce the probability of exciton annihilation.

“When more excited particles are created, the balance tilts toward creating more heat instead of light. In our work, we first understood how this balance is controlled by the band structure,” said Hyungjin Kim, a postdoctoral fellow and co-lead author on the work. That understanding led them to propose modifying the band structure in a controlled way using physical strain.

High-performance under strain

The researchers started by carefully placing a thin semiconductor (tungsten disulfide, or WS₂) film atop a flexible plastic substrate. By bending the plastic substrate, they applied a small amount of strain to the film. At the same time, the researchers focused a laser beam with different intensities on the film, with a more intense beam leading to a higher concentration of excitons – a high “brightness” setting in an electronic device.

Detailed optical microscope measurements allowed the researchers to observe the number of photons emitted by the material as a fraction of the photons it had absorbed from the laser. They found that the material emitted light at nearly perfect efficiency at all brightness levels through appropriate strain.

To further understand the material’s behavior under strain, the team performed analytical modelling.

They found that the heat-losing collisions between excitons are enhanced due to “saddle points” – regions where an energy surface curves in a way that resembles a mountain pass between two peaks – found naturally in the single-layer semiconductor’s band structure.

Applying the mechanical strain led the energy of that process to change slightly, drawing the excitons away from the saddle points. As a result, the particles’ tendency to collide was reduced, and the reduction in efficiency at high concentrations of charged particles ceased to be a problem.

“These single-layer semiconductor materials are intriguing for optoelectronic applications as they uniquely provide high efficiency even at high brightness levels and despite the presence of large number of imperfections in their crystals,” said Javey.

Future work by the Berkeley Lab team will focus on using the material to fabricate actual LED devices for further testing of the technology’s high efficiency under increasing brightness.

Eran Rabani, a faculty scientist at Berkeley Lab and professor of chemistry at UC Berkeley, and Naoki Higashitarumizu, a postdoctoral fellow at UC Berkeley, also contributed to the work.

This research was supported by the DOE Office of Science.