Sunday, August 04, 2024

PUBLIC HEALTH PSA

Comprehensive meta-analysis pinpoints what vaccination strategies different countries should adopt



Annenberg Public Policy Center of the University of Pennsylvania





Vaccines are safe and effective, and help reduce death and illness. But global vaccination rates are suboptimal and have trended downward, leaving humanity more vulnerable to vaccine-preventable diseases such as COVID-19, influenza, measles, polio, and HPV.

Identifying interventions that could increase vaccine coverage could help save lives. A new paper from a team led by researchers at the University of Pennsylvania offers the first comprehensive meta-analysis examining what types of vaccine intervention strategies have the greatest effect, and whether different intervention strategies work better in different countries.

“A systematic review and meta-analysis of strategies to promote vaccination uptake,” published August 1, 2024, in Nature Human Behaviour, analyzes the results of 88 eligible randomized-controlled trials testing interventions with 1,628,768 participants from 17 countries. Previous meta-analyses have been much more limited to specific vaccines, specific intervention strategies, or specific populations, and have therefore been unable to compare strategies or consider their relative effectiveness across regions.

“Figuring out which approaches help increase immunization and under what circumstances could help global public health leaders allocate resources more efficiently, and ultimately improve health outcomes,” said co-author Dolores Albarracín, the Amy Gutmann Penn Integrates Knowledge University Professor at the University of Pennsylvania and director of the Communication Science division at the university’s Annenberg Public Policy Center (APPC).

The researchers considered seven types of vaccine intervention strategies: increasing access to vaccination, sending vaccination reminders, providing incentives (e.g., money), supplying information, correcting misinformation, promoting active and passive motivation, and teaching behavioral skills.

Vaccination interventions that work

The researchers found that interventions were associated with an estimated 50 percent higher chance of vaccination than “control” conditions with no intervention. They also found that two interventions were most promising in improving vaccination uptake. There was a moderate effect of interventions to increase access to vaccines, particularly in countries with low access to and quality of health care. There was also a small effect from incentives, and non-significant effects of all other interventions examined. For example, informational and misinformation-correction interventions had no detectable effects on vaccination rates.

Interventions to increase access to vaccines included offering transportation assistance or bringing vaccines to recipients at sites like nursing homes, family homes, and workplaces. These strategies actually tripled the odds of vaccination and had even larger effects in lower income countries with fewer resources and access to health care.

The financial incentive interventions included, for example, a U.S. study that achieved an 85% influenza vaccination rate when physicians were reimbursed $1.60 per dose, compared with a 70% vaccination rate when they were reimbursed $0.80 per dose. However, both in this U.S. study and the estimates from the meta-analysis, the effects of incentives were quite small.

“Public health officials often say that ensuring vaccine access is the first step to promoting immunization,” Albarracín said. “Our meta-analysis provides hard evidence in support of this recommendation, and indicates that this should be a special priority in under-resourced areas with limited access to health care. By contrast, even though misinformation undermines democracy and can be far-fetched, and thus highly salient, correcting it does not ensure health behaviors like vaccination.”

The authors note that there are several important barriers to increasing access in underserved areas, but it is important to understand how crucial this form of intervention is.

In addition to Albarracín, "A systematic review and meta-analysis of strategies to promote vaccination uptake,” published Aug. 1, 2024, in Nature Human Behaviour, was authored by Sicong Liu, formerly a postdoctoral researcher in Albarracín's Social Action Lab at Penn and now a professor at the South China Normal University, Guangzhou, China; Marta Durantini, clinical research director of the Communication Science division at APPC; Christopher Calabrese, a former postdoctoral fellow at APPC and now an assistant professor at Clemson University; and Flor Sanchez, professor at the Universidad Autónoma de Madrid.

 PUBLIC HEALTH PSA

Which strains of tuberculosis are the most infectious?



Shared geographic origin between TB strain and human host could amplify risk for infection



Harvard Medical School





For some forms of tuberculosis, the chances that an exposed person will get infected depend on whether the individual and the bacteria share a hometown, according to a new study comparing how different strains move through mixed populations in cosmopolitan cities.

Results of the research, led by Harvard Medical School scientists and published Aug. 1 in Nature Microbiologyprovide the first hard evidence of long-standing observations that have led scientists to suspect that pathogen, place, and human host collide in a distinctive interplay that influences infection risk and fuels differences in susceptibility to infection.

The study strengthens the case for a long-standing hypothesis in the field that specific bacteria and their human hosts likely coevolved over hundreds or thousands of years, the researchers said.

The findings may also help inform new prevention and treatment approaches for tuberculosis, a wily pathogen that, each year, sickens more than 10 million people and causes more than a million deaths worldwide, according to the World Health Organization.

In the current analysis, believed to be the first controlled comparison of TB strains’ infectivity in populations of mixed geographic origins, the researchers custom built a study cohort by combining case files from patients with TB in New York City, Amsterdam, and Hamburg. Doing so gave them enough data to power their models.

The analysis showed that close household contacts of people diagnosed with a strain of TB from a geographically restricted lineage had a 14 percent lower rate of infection and a 45 percent lower rate of developing active TB disease compared with those exposed to a strain belonging to a widespread lineage.

The study also showed that strains with narrow geographic ranges are much more likely to infect people with roots in the bacteria’s native geographic region than people from outside the region. 

The researchers found that the odds of infection dropped by 38 percent when a contact is exposed to a restricted pathogen from a geographic region that doesn’t match the person’s background, compared with when a person is exposed to a geographically restricted microbe from a region that does match their home country. This was true for people who had lived in the region themselves and for people whose two parents could each trace their heritage to the region.

This pathogen-host affinity points to a shared evolution between humans and microbes with certain biological features rendering both more compatible and fueling the risk for infection, the researchers said.

“The size of the effect is surprisingly large,” said Maha Farhat, the Gilbert S. Omenn, MD ’65, PhD Associate Professor of Biomedical Informatics in the Blavatnik Institute at HMS. “That’s a good indicator that the impact on public health is substantial.”

Why differences matter

Thanks to the growing use of genetic sequencing, researchers have observed not all circulating strains are created equal. Some lineages are widespread and responsible for much of the TB around the world, while others are prevalent only in a few restricted areas. Given that the complex nature of TB transmission in high-incidence settings where people often have multiple exposures to different lineages, researchers have not been able to compare strains under similar conditions and have been left to speculate about possible explanations for the differences between strains.

Many factors increase the risk of contracting tuberculosis from a close contact. One of the best predictors of whether a person will infect their close contacts is bacterial load, measured by a test called sputum smear microscopy, which shows how many bacteria a person carries in their respiratory system.

But the new study showed that for geographically restricted strains, whether a person has ancestors who lived where the strain is common was an even bigger predictor of infection risk than bacterial load in the sputum. In the cases analyzed in the study, this risk of common ancestry even outweighed the risk stemming from having diabetes and other chronic diseases previously shown to render people more susceptible to infection.

The findings add to a growing body of evidence of the importance of paying attention to the wide variation between different lineages of tuberculosis and to the details of how different lineages of tuberculosis interact with different host populations.

Previous studies have shown that some genetic groups of TB are more prone to developing drug resistance and that TB vaccines appear to work better in some places than others. There is also evidence that some treatment regimens might be better suited to some strains of TB than others.   

“These findings emphasize how important it is to understand what makes different strains of TB behave so differently from one another, and why some strains have such a close affinity for specific, related groups of people,” said Matthias Groeschel, research fellow in biomedical informatics in Farhat’s lab at HMS; resident physician at Charité, a university hospital in Berlin; and the study’s first author.

In addition to the analysis of clinical, genomic, and public health data, the researchers also tested the ability of different strains of TB to infect human macrophages, a type of immune cell that TB hijacks to cause infection and disease. The researchers grew cells from donors from different regions. Once again, cell lines from people with ancestry that matched the native habitat of a restricted strain of tuberculosis bacteria were more susceptible to the germs than cells from people from outside the area, mirroring the results of their epidemiologic study.

Until now, most experiments of the interaction between human immune cells and TB have not compared how TB interacts with cells of hosts from different populations or places, the researchers said.

While this experiment was not designed to capture insights about the mechanism underlying the affinity between human and TB populations sharing geographic backgrounds, it highlights the importance of using multiple strains of TB and cells from diverse populations to inform treatment and prevention. It also points to the need for more basic research to understand the genomic and structural differences in how bacterial and host cells interface, the researchers said.

“It's so important to appreciate that the great diversity of human and tuberculosis genetics can significantly impact how people and microbes respond to one another and to things like drugs and vaccines,” Farhat said. “We have to incorporate that into the way we think about the disease.”

“We’re at the very beginning of appreciating the importance of that diversity,” Groeschel said. “There’s so much more to learn about how it might impact the efficacy of drugs, vaccines, and the course that disease takes in different strains.”

Advances in gene sequencing create a new puzzle

While the closely related but distinct genetic groups of tuberculosis were discovered with more traditional methods of genotyping, the widespread use of whole genome sequencing by public health departments around the world allowed doctors and researchers to better profile TB germs and track outbreaks and drug resistance genetically.

The realization that highly localized stains didn’t spread well to other regions led researchers to speculate that regionally constrained strains were less infectious than widespread strains. Since the constrained strains persisted within their limited ranges, some researchers speculated that localized populations of the bacteria may have coevolved with their human hosts, making different human populations more susceptible to different types of TB. This could also mean, researchers hypothesized, that different strains of TB would have different susceptibility to different treatments and vaccines. For example, structural differences in the shape of the bacteria might prevent some drugs from binding effectively with bacteria from different strains.

Until recently, these hypotheses were nearly impossible to test, given the differences between cultural and environmental conditions that might affect infection rates in different communities and other parts of the world. Furthermore, the fact that the constrained stains strayed from home so rarely made it challenging to gather enough data to measure differences across strains.

Multidisciplinary science cracks the case

To overcome these obstacles, the research team collaborated with public health departments and research teams from the U.S., the Netherlands, and Germany to assemble a massive database integrating tuberculosis case reports, pathogen genetic profiles, and public health records of infection rates among close contacts. The analysis also incorporated demographic details about the social networks of infected people to assess how the different genetic lineages of tuberculosis spread in other populations. In total, the study included 5,256 TB cases and 28,889 close contacts.

“This study is a great example of why it’s so important for researchers to collaborate with many different kinds of partners,” said Groeschel. “We were able to merge public health data from three big cities and use the powerful computational biology tools that we have access to in academic medicine to answer a complicated question that has important implications for public health and evolutionary biology, vaccine development, and drug research.”

Authorship, funding, disclosures

Additional authors include Roger Vargas Jr of HMS; Francy Pérez-Llanos and Susanne Homolka of  Research Center Borstel, Borstel, Germany; Roland Diel of University Medical Hospital Schleswig-Holstein; Vincent Escuyer and Kimberlee Musser of the Wadsworth Center, New York State Department of Health; Shama Ahuja, Lisa Trieu, Jeanne Sullivan Meissner, and Jillian Knorr of the New York City Department of Health and Mental Hygiene, Bureau of Tuberculosis Control; Dick van Soolingen and Don Klinkenberg of the National Tuberculosis Reference Laboratory, Center for Infectious Disease Control, National Institute for Public Health and the Environment (RIVM), Bilthoven, The Netherlands; Peter Kouw of the Department of Infectious Diseases, Public Health Service, Amsterdam, The Netherlands; Wojciech Samek of the Department of Electrical Engineering and Computer Science, Technical University Berlin and the Department of Artificial Intelligence, Fraunhofer Heinrich Hertz Institute, Berlin, Germany; Barun Mathema of the Mailman School of Public Health, Columbia University; and Stefan Niemann of the German Center for Infection Research, Partner Site Hamburg-Lübeck-Borstel-Riems, Borstel, Germany.

This work was funded by the U.S. National Institutes of Health/National Institute of Allergy and Infectious Diseases (grant R21AI154089), the German Research Foundation (GR5643/1-1), the BIH Charité Junior Digital Clinician Scientist Program funded by the Charité – Universitätsmedizin Berlin, the Berlin Institute of Health at Charité (BIH), the Leibniz Science Campus EvoLUNG (grant W47/2019), the German Research Foundation under Germany’s Excellence Strategy – EXC 2167 Precision Medicine in Inflammation, and the German Ministry of Education and Research (BMBF) for the German Center of Infection Research (DZIF).

 

Tipping (POINT) risks from overshooting 1.5 °C can be minimised if warming is swiftly reversed




Potsdam Institute for Climate Impact Research (PIK)




Human-made climate change can lead to a destabilisation of large-scale components of the Earth system such as ice sheets or ocean circulation patterns, the so-called tipping elements. While these components will not tip over night, fundamental processes are put into motion unfolding over tens, hundreds or thousands of years. These changes are of such a serious nature that they should be avoided at all costs, the researchers argue. In their new study, they assessed the risks of destabilisation of at least one tipping element as a result of overshooting 1.5 °C. Their analysis shows how crucial it is for the state of the planet to adhere to the climate objectives of the Paris Agreement. It further emphasises the legacy of today’s climate (in)action for centuries to millennia to come.

“While timescales to 2300 or beyond may seem far away, it is important to map out tipping risks to the best of our abilities. Our results show how vitally important it is to achieve and maintain net-zero greenhouse gas emissions in order to limit these risks for the next hundreds of years and beyond,“ explains co-lead author Tessa Möller, scientist at IIASA and PIK. “Our calculations reveal that following current policies until the end of this century would lead to a high tipping risk of 45 percent of at least one of the four elements tipping by 2300.”

Exceeding 2 °C global warming strongly increases tipping risks

“We see an increase in tipping risk with every tenth of a degree of overshoot above 1.5 °C. But if we were to also surpass 2 °C of global warming, tipping risks would escalate even more rapidly. This is very concerning as scenarios that follow currently implemented climate policies are estimated to result in about 2.6 °C of global warming by the end of this century,” says Annika Ernest Högner from PIK, who co-lead the study.

“Our study confirms that tipping risks in response to overshoots can be minimised if warming is swiftly reversed. Such a reversal of global warming can only be achieved if greenhouse gas emissions reach at least net-zero by 2100. The results underline the importance of the Paris Agreement’s climate objectives to limit warming to well below 2 °C even in case of a temporary overshoot above 1.5 °C,“ says study author Nico Wunderling of PIK.

The four tipping elements analysed in the study are pivotal in regulating the stability of the Earth’s climate system. So far, complex Earth system models are not yet able to comprehensively simulate their non-linear behaviour, feedbacks, and interactions between some of the tipping elements. Therefore, the researchers used a stylised Earth system model to represent the main characteristics and behaviour and thereby systematically include relevant uncertainties in tipping elements and their interactions. 

"This analysis of tipping point risks adds further support to the conclusion that we are underestimating risks, and need to now recognise that the legally binding objective in the Paris Agreement of holding global warming to ‘well below 2°C’, in reality means limiting global warming to 1.5°C. Due to insufficient emission reductions, we run an ever increasing risk of a period overshooting this temperature limit, which we need to minimise at all costs, to reduce dire impacts to people across the world,” concludes PIK director and author of the study Johan Rockström.

Article:
Tessa Möller, Annika Ernest Högner, Carl-Friedrich Schleussner, Samuel Bien, Niklas H. Kitzmann, Robin D. Lamboll, Joeri Rogelj, Jonathan F. Donges, Johan Rockström & Nico Wunderling (2024): Achieving net zero greenhouse gas emissions critical to limit climate tipping risks. Nature Communications. [DOI: 10.1038/s41467-024-49863-0]

Weblink to the article, once published:
https://www.nature.com/articles/41467-024-49863-0

 COLORADO

Research catalogs greenhouse gas emissions tied to energy use for interbasin water transfers



Colorado State University




Much of the water in the West is transported across vast geographical areas by large infrastructure projects known as interbasin water transfers. Two of these projects in particular make up 85% of all energy-related greenhouse gas emissions associated with U.S. interbasin transfers — one in Arizona and the other in California — according to the new research published this week in the journal Nature Water.

The project in Arizona is known as the Central Arizona Project and in California it’s the State Water Project.

“You hear a lot about these big projects and how much energy they use,” said Avery Driscoll, a doctoral student in CSU’s Department of Soil and Crop Sciences and the paper’s lead author. “We were curious how much of that was actually attributable to agriculture and what the emissions impact was.”

In gathering and analyzing data from 2018 to 2022, Driscoll excluded the portions of interbasin transfers that are used for non-irrigation sources such as municipal water supplies. During the five years of data Driscoll reviewed, approximately 41% of the Central Arizona Project and about 34% of California’s State Water Project went to ag.

Colorado’s largest interbasin water transfer project, the Colorado-Big Thompson project, or CBT, was third on the list. However, it accounted for a much smaller portion of the energy-related greenhouse gas emissions comparatively, roughly 6%. From 2018 to 2022, about 45% of the CBT project, which is operated by Northern Water, was used for agriculture.

Driscoll reviewed data for 106 projects, with the Arizona, California and Colorado projects accounting for 91% of the energy use tied to irrigation from interbasin transfers. “Although energy use for interbasin transfers is the dominant emissions source in only 15 counties,” the study’s authors wrote, “the emissions impact is substantial in those locations.”

“I was surprised it was so consolidated,” Driscoll said. “I think it’s also a testament to the fact that a lot of these transfers aren’t being used for irrigation because it’s expensive.” She added, “Farmers are not going to pay as much as municipalities for the water, so it’s just less feasible to be using trans-basin water for irrigation.”

A full irrigation emissions picture

The new paper in Nature Water builds on earlier work by Driscoll and her co-authors published in Nature Communications. That paper cataloged energy use tied specifically to on-farm groundwater pumping in the U.S., which is nearly four times more emissions-intensive than surface water irrigation. Groundwater use accounts for 79% of irrigation-related emissions despite providing only 49% of U.S. irrigation water.

These two papers combined represent the “most comprehensive national-scale analysis of irrigation related emissions” available, according to the study’s authors.

“Irrigation is an essential climate change adaptation strategy, but we’re showing here that irrigation presents some important tradeoffs with our greenhouse gas mitigation goals,” said CSU Associate Professor Nathan Mueller, a co-author on the study. “On the other hand, irrigation allows for incredible boosts in crop productivity, so we need to recognize the considerable benefits of irrigation while attempting to minimize the greenhouse gas costs.”

In addition to water transfer projects, the Nature Water paper also catalogs irrigation-related greenhouse gas emissions associated with groundwater degassing and nitrification. For these two categories, the impact tended to vary greatly based on location.

Groundwater degassing refers to the natural process by which dissolved gases release into the atmosphere after groundwater is applied to a field. The study’s authors found that groundwater degassing was “the dominant emissions source in 55 counties (10% of irrigated land), including much of the Lower Mississippi River Valley region.” 

Irrigating farmland can also cause increased amounts of nitrous oxide, a potent greenhouse gas, to be released into the atmosphere through a natural biological process called denitrification. The study found that nitrous oxide emissions were the dominant source of irrigation-related emissions in only 7% of U.S. counties.

Driscoll and Mueller view this accounting as being applicable in many contexts, including to help inform national emissions and reduction efforts as well as current greenhouse gas accounting frameworks.

“Greenhouse gas emissions from agriculture are complicated because they involve so many different mechanisms, and we found that irrigation-related emissions are no exception,” Mueller said. “The good news is that we can address most of these emissions through relatively straightforward changes to our energy and agricultural systems — electrifying and decarbonizing pumping systems along with the grid.”

HKUST engineering researchers crack the code to boost solar cell efficiency and durability




Hong Kong University of Science and Technology

Prof. Lin and his team 

image: 

Assistant Professor Lin Yen-Hung of the Department of Electronic and Computer Engineering and the State Key Laboratory of Advanced Displays and Optoelectronics Technologies (right), Electronic and Computer Engineering PhD student CAO Xueli (center), and Senior Manager of the State Key Laboratory of Advanced Displays and Optoelectronics Technologies Dr. Fion YEUNG (left)

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Credit: HKUST



Photovoltaic (PV) technologies, which convert light into electricity, are increasingly applied worldwide to generate renewable energy. Researchers at the School of Engineering of the Hong Kong University of Science and Technology (HKUST) have developed a molecular treatment that significantly enhances the efficiency and durability of perovskite solar cells. Their breakthrough will potentially accelerate the large-scale production of this clean energy.

A key to the solution was their successful identification of critical parameters that determine the performance and lifespan of halide perovskites, a next-generation photovoltaic material which has emerged as one of the most promising materials in PV devices for its unique crystal structure. The findings have been published in Science.

Led by Assistant Professor LIN Yen-Hung of the Department of Electronic and Computer Engineering and the State Key Laboratory of Advanced Displays and Optoelectronics Technologies, the research team investigated various ways of passivation, a chemical process that reduces the number of defects or mitigates their impact in materials, thereby enhancing the performance and longevity of devices comprising these materials. They focused on the “amino-silane” molecular family for passivating perovskite solar cells.

“Passivation in many forms has been very important in improving the efficiency of perovskite solar cells over the last decade. However, passivation routes that lead to the highest efficiencies often do not substantially improve long-term operational stability,” Prof. Lin explained the problem.

For the first time, the research team showed how different types of amines (primary, secondary, and tertiary) and their combinations can improve perovskite films’ surfaces where many defects form. They achieved this using both “ex-situ” (outside the operating environment) and “in-situ” (within the operating environment) methods to observe molecules’ interactions with perovskites. From there, they identified molecules that substantially increase photoluminescence quantum yield (PLQY), i.e. the quantity of photons emitted during materials excitation, indicating fewer defects and better quality.

“This approach is crucial for the development of tandem solar cells, which combine multiple layers of photoactive materials with different bandgaps. The design maximizes the use of the solar spectrum by absorbing different parts of sunlight in each layer, leading to higher overall efficiency,” Prof. Lin elaborated on the application.

In their solar cell demonstration, the team fabricated devices of medium (0.25 cm²) and large (1 cm²) sizes. The experiment achieved low photovoltage loss across a broad range of bandgaps, maintaining a high voltage output. These devices reached high open-circuit voltages beyond 90% of the thermodynamic limit. Benchmarking against about 1,700 sets of data from existing literature showed that their result was among the best reported to date in terms of efficiency in energy conversion.

Even more critically, the study demonstrated remarkable operational stability for amino-silane passivated cells under the International Summit on Organic Solar Cells (ISOS)-L-3 protocol, a standardized testing procedure for solar cells. Approximately 1,500 hours into the cell aging process, the maximum power point (MPP) efficiency and power conversion efficiency (PCE) remained at high levels. For the best-passivated cells to decrease to 95% of their initial values, the champion MPP efficiency and the champion PCE were recorded at 19.4% and 20.1% respectively – among the highest (when factored for the bandgap) and the longest metrics reported to date.

Prof. Lin emphasized that their treatment process not only boosts the efficiency and durability of perovskite solar cells, but is also compatible with industrial-scale production.

“This treatment is similar to the HMDS (hexamethyldisilazane) priming process widely used in the semiconductor industry,” he said. “Such similarity suggests that our new method can be easily integrated into existing manufacturing processes, making it commercially viable and ready for large-scale application.”

The team included Electronic and Computer Engineering PhD student CAO Xue-Li, Senior Manager of the State Key Laboratory of Advanced Displays and Optoelectronics Technologies Dr. Fion YEUNG, along with collaborators from Oxford University and the University of Sheffield.

Amino-silane molecules and their fabrication and optoelectronic properties 

More electricity from the sun



Surface modification for more effective textured perovskite/silicon tandem solar cells



Wiley




A coating of solar cells with special organic molecules could pave the way for a new generation of solar panels. As a research team reports in the journal Angewandte Chemie, this coating can increase the efficiency of monolithic tandem cells made of silicon and perovskite while lowering their cost—because they are produced from industrial, microstructured, standard silicon wafers.

In solar cells, light “knocks” electrons out of a semiconductor, leaving behind positively charged “holes”. These two charge carriers are separated from each other and can be collected as current. Tandem cells were developed to better exploit the entire spectrum of sunlight and increase solar cell efficiency. Tandem cells are made of two different semiconductors that absorb different wavelengths of light. Primary contenders for use in this technology are a combination of silicon, which absorbs mostly red and near-infrared light, and perovskite, which very efficiently uses visible light. Monolithic tandem cells are made by coating a support with the two types of semiconductor, one on top of the other. For a perovskite/silicon system, this is usually achieved by using silicon wafers that are produced by the zone melting process and have a polished or nanostructured surface. However, these are very expensive. Silicon wafers produced by the Czochralski process with micrometer-scale pyramidal structural elements on their surfaces are significantly cheaper. These microtextures result in better light capture because they are less reflective than a smooth surface. However, the process of coating these wafers with perovskite results in many defects in the crystal lattice, which affect the electronic properties. Transfer of the released electrons is impeded, and electron-hole recombination increasingly occurs through processes that do not emit light. Both the efficiency and the stability of the perovskite layer are decreased.

Headed by Prof. Kai Yao, a Chinese team at Nanchang University, Suzhou Maxwell Technologies, the CNPC Tubular Goods Research Institute (Shaanxi), the Hong Kong Polytechnic University, the Wuhan University of Technology, and Fudan University (Shanghai) has now developed a strategy for surface passivation that allows the surface defects of the perovskite layer to be smoothed out. A thiophenethylammonium compound with a trifluoromethyl group (CF3-TEA) is applied by a dynamic spray coating process. This forms a very uniform coat—even on microtextured surfaces.

Due to its high polarity and binding energy, the CF3-TEA coating very effectively weakens the effects of the surface defects. Nonradiative recombination is suppressed, and the electronic levels are adjusted so that the electrons at the interface can be more easily transferred to the electron-capturing layer of the solar cell. Surface modification with CF3-TEA allows perovskite/silicon tandem solar cells based on common textured wafers made of Czochralski silicon to attain a very high efficiency of nearly 31% and maintain long-term stability.

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About the Author

Dr Kai Yao is a Professor at Nanchang University (China) with appointments in Institute of Photovoltaics. His research interest is in the field of organic–inorganic hybrid materials for optoelectronic applications. He is also Director of emerging photovoltaic technologies research group at the Nanchang University.

 

Scientists call on Government to change policies to boost nature on UK solar farms





Lancaster University
solar 

image: 

Solar farms that are properly designed and well managed could maximise environmental benefits and deliver dual outcomes for climate and nature if supported by appropriate public policies

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Credit: Hollie Blaydes




Solar farms in the UK could bring benefits for nature as well as provide low carbon energy - but unless policies change, potential benefits for nature could be squandered, scientists argue. 

As well as providing low carbon energy, solar farms could offer vital space for nature to thrive if the solar industry is incentivised to locate, construct and manage sites appropriately, a team of researchers and industry experts say in a new paper published in the British Ecological Society’s Journal of Applied Ecology

The UK’s solar farms currently generate approximately 8.6 GW – enough to meet around one sixth of the country’s peak electricity demand. To meet its international climate commitments, some estimates show that the UK will need to install in the order of 70,000 hectares of solar farms by the mid 2030s. 

“If located in the right places and managed correctly, solar farms have great potential to restore degraded habitats and help meet the UN’s Sustainable Development Goals to halt and reverse biodiversity loss, although not every species may benefit,” said Professor Alona Armstrong of Lancaster University and co-author of the paper. “Some in the solar industry embed nature benefits into the design of solar farms and their management, but this approach is not universal.” 

Professor Piran White of the University of York and co-author of the paper added: “There is considerable potential for more solar farms to be managed for the benefit of nature, so that existing solar farms and any new solar farms, such as those recently approved by the new Government, can contribute to mitigating the ecological crisis as well as the climate crisis.” 

Previous research by some of the scientists behind the paper has shown that pollinating insects can benefit from solar farms managed for biodiversity, and that these benefits can also spill out into surrounding areas if the crops are pollinator-dependent. 

However, under current policies, the UK risks missing out on biodiversity benefits that could be delivered by solar farms because existing public financial incentives aimed at increasing biodiversity on agricultural land currently exclude solar farms. In addition, there is much potential to incentivise private funding to boost biodiversity on solar farms. 

“Renewable energy, together with strategic land use and management, is essential to address the climate and nature crises,” said Hing Kin Lee, of NextEnergy Capital and co-author of the paper. “The right cross-sectoral policies and incentives can enhance nature on solar farms, providing long-term stable returns and measurable environmental benefits.” 

The paper’s authors call on Government to identify opportunities to change policies that currently address climate and biodiversity separately. 

Dr Fabio Carvalho, a Senior Research Associate at Lancaster University and lead author of the paper, said: “In order to deliver dual benefits for climate and nature, solar farms not only need to be well managed, but also supported by appropriate public policies that take a more coherent joined-up approach. 

“Unless policies aimed at boosting biodiversity on agricultural land include solar farms, we risk missing opportunities to enhance nature through land use change for solar farms, and perhaps even exacerbate the biodiversity crisis if solar farms are not properly built and managed.” 

The authors set out several recommendations in their paper including: 

  • Ensuring solar farms can access public financial incentives that encourage sustainable land use 
  • Implementing land use policies that incentivise private funding 
  • Embedding solar farms in biodiversity-inclusive planning policies and decision making 
  • Creating indicators and metrics that guide the development and assessment of public policies 
  • Building equity and clarity into the responsibilities and benefits for all actors involved 

The recommendations are outlined in full in the paper ‘Integrated policymaking is needed to deliver climate and ecological benefits from solar farms’ 

Authors of the paper are: Fabio Carvalho, Hollie Blaydes, Lucy Treasure, Stuart P. Sharp and Alona Armstrong of Lancaster University; Hing Kin Lee and Kristina Vucic of NextEnergy Capital; Laura Harrison and Piran White of the University of York; Hannah Montag and Tom Clarkson of Clarkson & Woods Ecological Consultants; and Jonathan Scurlock of the National Farmers’ Union. 

 The research was supported by the UK Energy Research Centre (UKERC) funded by the UK Research and Innovation Energy Programme and the Knowledge Transfer Partnership (KTP) funded by UKRI through Innovate UK with the support of co-funders.