Iodine-stabilized single-longitudinal-mode laser enhances atmospheric sensing and environmental monitoring

Hefei Institutes of Physical Science, Chinese Academy of Sciences

Facebook

XLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

Schematic diagram of the all-solid-state single-longitudinal continuous-wave 1064nm laser

view more 

Credit: LIU Pan

Recently, the research team led by Prof. ZHANG Tianshu at the Anhui Institute of Optics and Fine Mechanics, the Hefei Institutes of Physical Science of the Chinese Academy of Science developed a compact all-solid-state continuous-wave (CW) single-longitudinal-mode (SLM) laser with high frequency stability using iodine-based frequency locking, advancing its application in atmospheric remote sensing and environmental monitoring.

The related achievements were published in Optics and Laser Technology.

CW SLM lasers are widely used in areas such as laser amplification, gravitational wave detection, and quantum optics. They also play a key role in atmospheric remote sensing and environmental monitoring. These applications require not only SLM laser output but also high frequency stability, which current semiconductor and fiber lasers struggle to provide due to limited environmental adaptability.

In this study, the team introduced a ring resonator structure combined with iodine molecular absorption frequency locking technology. By locking the laser frequency to the flank of specific iodine absorption lines and employing feedback control to adjust the resonator length, they achieved long-term frequency stability.

The laser exhibits excellent beam quality, with M² values of 1.05 in the horizontal direction and 1.19 in the vertical direction, demonstrating high spatial coherence. Its output linewidth is less than 10 MHz, confirming stable single-longitudinal-mode operation. In terms of frequency stability, while the laser shows a drift of more than 200 MHz in free-running mode, this is significantly reduced to within 4 MHz over a continuous 7-hour period when frequency locking is applied.

To support future integration and field deployment, the team also engineered the system with a compact opto-mechanical-thermal-electrical design, meeting the requirements for miniaturization and stability.

This achievement is expected to provide a core laser source for next-generation environmental monitoring instruments, particularly in the detection of atmospheric pollutants and greenhouse gases, offering technical support for air quality assessment and climate change research, according to the team.

Iodine-Stabilized Single-Longitudinal-Mode Laser Enhances Atmospheric Sensing and Environmental Monitoring

Credit

LIU Pan

Journal

Optics & Laser Technology

DOI

10.1016/j.optlastec.2025.113124 

Article Title

A stable all-solid-state continuous-wave single-longitudinal-mode Nd:YVO4 laser at 1064 nm based on the molecular iodine absorption

 

New AI-powered model improves ozone pollution forecasting

Hefei Institutes of Physical Science, Chinese Academy of Sciences

Facebook

XLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

CNN-LSTM Machine Learning Framework Integrating Spatiotemporal Evolution Characteristics of Weather Processes

view more 

Credit: HU Feng

Recently, a research team led by Prof. XIE Pinhua from the Hefei lnstitutes of Physical Science of the Chinese Academy of Sciences, has developed a novel prediction model for surface ozone concentration in the North China Plain (NCP) and Yangtze River Delta (YRD) regions. The model is based on a sequential convolutional long short-term memory network framework (CNN-LSTM) framework that integrates spatiotemporal meteorological features, addressing key limitations in existing forecasting methods.

The research results, which were published in Environmental Science & Technology, provided a new technical approach for ozone pollution early warning.

Surface ozone has emerged as a major summer air pollutant, often linked to high temperatures and low humidity. However, ozone levels are also influenced by complex meteorological factors such as atmospheric circulation, solar radiation, boundary layer height, and cloud cover—making accurate forecasting a persistent challenge. While traditional machine learning models often overlook these spatiotemporal dynamics, numerical models face high computational costs and limited ability to predict high-concentration ozone episodes.

In this study, the team developed a multi-scale mapping model using meteorological forecast data and CNN-LSTM architecture. By incorporating meteorological fields across various spatiotemporal scales, the model achieved high prediction accuracy—with hit rates of 83% in the NCP and 56% in the YRD for high-concentration ozone events (MDA8 ≥ 160 μg/m³), and an R² ≥ 0.85 in explaining daily ozone variability.

The model also successfully quantified the impact of typhoon position shifts on regional ozone levels, further proving its robustness. 

"We've gained a clearer picture of how weather patterns drive ozone pollution, which can really support better early warnings for high-risk ozone days," said Prof. XIE Pinhua.

---

Journal

Environmental Science & Technology

DOI

10.1021/acs.est.4c11988 

Article Title

Mapping Regional Meteorological Processes to Ozone Variability in the North China Plain and the Yangtze River Delta, China

 

New BrainHealth research demonstrates accelerated cognitive gains in active service members

SMART training efficiently improves cognitive gains in active-duty service members with mTBI.

Center for BrainHealth

As part of its ongoing quest to redefine how people understand and address the brain’s health and performance, Center for BrainHealth at UT Dallas collaborated with the Traumatic Brain Injury Center of Excellence (TBICoE) team at Camp Pendleton on new research investigating the effects of cognitive rehabilitation protocols on the brain performance of active-duty service members (ADSMs) with mild traumatic brain injury (mTBI). Cognitive strength, resilience, agility and focus are essential to military readiness and overall well-being.

Results from the randomized clinical trial “Validation of Cognitive Enhancement Techniques for mTBI” were recently published in Frontiers of Human Neuroscience and Frontiers in Neurology.

The study included 148 ADSMs who had persistent cognitive complaints related to a past mTBI. Researchers compared the efficacy and efficiency of two cognitive rehabilitation protocols: Strategic Memory Advanced Reasoning Tactics (SMART™) and Study of Cognitive Rehabilitation Effectiveness (SCORE).

Over 20 hours, SMART training took a “top-down” approach, teaching and practicing strategies that promote self-agency and flexible thinking and can be applied to all areas of life. SMART brain training is Center for BrainHealth's proprietary methodology, teaching science-backed techniques that prime the brain, calibrate mental energy, reinforce strategic thinking and ignite innovation.

Over 60 hours, SCORE took a “bottom-up” approach, training compensatory strategies that address attention, planning and memory. SCORE is an independent research-based cognitive intervention that combines foundational skill training with computer-based Attention Processing Training (APT-3) to support cognitive recovery and improve functional outcomes.

Both groups showed comparable, significant improvements in overall cognitive gains. However, SMART training was completed in one-third of the training time, suggesting it may promote faster cognitive gains and be transferable to complex tasks more quickly and a lower cost.

“Top-down SMART brain training is about exercising the executive networks, which are essentially the brain’s CEO,” said lead author Erin Venza, MS, CCC-SLP, head of clinical operations at Center for BrainHealth. “Cognitive strategies to think strategically and problem-solve creatively can empower people to thrive in their lives, even when facing ongoing challenges.”

Evidence of SMART’s efficiency and efficacy is especially meaningful for active duty and veteran warriors, law enforcement and other first responders. “These findings suggest that SMART brain training can contribute to a faster return to mission readiness, which is critical for our warfighters,” added co-author Jennifer Zientz, MS, CCC-SLP, director of programs at Center for BrainHealth. “Like a single-issue pair of boots, we only get one brain – so we need to take the best care of it we can.”

Over the past 15 years, Center for BrainHealth has trained more than 6,000 members of the military – active duty, veterans and families – from every branch. This work has informed the further development and testing of SMART protocols.

About Center for BrainHealth

Center for BrainHealth®, part of The University of Texas at Dallas, is a translational research institute committed to enhancing, preserving, and restoring brain health across the lifespan. Major research areas include the use of functional and structural neuroimaging techniques to better understand the neurobiology supporting cognition and emotion in health and disease. This leading-edge scientific exploration is translated quickly into practical innovations to improve how people think, work and live, empowering people of all ages to unlock their brain potential. Translational innovations leverage 1) the BrainHealth Index, a proprietary measure that uniquely charts one’s upward (or downward) holistic brain health trajectory whatever their starting level; and 2) Strategic Memory Advanced Reasoning Tactics (SMART™) brain training, a strategy-based toolkit developed and tested by BrainHealth researchers and other teams over three decades.

---

Journal

Frontiers in Human Neuroscience

DOI

10.3389/fnhum.2025.1542422 

Method of Research

Randomized controlled/clinical trial

Subject of Research

People

Article Title

Validation of Cognitive Enhancement Techniques for mTBI

 

People with ‘young brains’ outlive ‘old-brained’ peers, Stanford Medicine scientists find

Organs’ biological ages predict disease

Stanford Medicine

Facebook

X
BlueskyMessageWhatsAppEmail

The candles on your birthday cake don’t tell the whole story. As anyone who ever attended a high-school reunion can tell you, some people age faster than others.

Whoever put the candles on your cake probably didn’t have to guess your chronological age. But research has shown that we also have what’s called a “biological age,” a cryptic but more accurate measure of our physiological condition and likelihood of developing aging-associated disorders from heart trouble to Alzheimer’s disease.

We all guess people’s actual ages, almost unconsciously, by scanning their faces for wrinkles, baggy eyes and other telltale signs. But figuring out how old someone’s brain, arteries or kidneys are is another matter. The organs tucked inside our bodies are aging at different speeds, too, according to a new study by Stanford Medicine investigators.

“We’ve developed a blood-based indicator of the age of your organs,” said Tony Wyss-Coray, PhD, professor of neurology and neurological sciences and director of the Knight Initiative for Brain Resilience. “With this indicator, we can assess the age of an organ today and predict the odds of your getting a disease associated with that organ 10 years later.”

They can even predict who is most likely to die from medical conditions associated with one or more of the 11 separate organ systems the researchers looked at: brain, muscle, heart, lung, arteries, liver, kidneys, pancreas, immune system, intestine and fat.

The biological age of one organ — the brain — plays an outsized role in determining how long you have left to live, Wyss-Coray said.

“The brain is the gatekeeper of longevity,” he said. “If you’ve got an old brain, you have an increased likelihood of mortality. If you’ve got a young brain, you’re probably going to live longer.”

Wyss-Coray, the D. H. Chen Professor II, is the senior author of the study, to be published online July 9 in Nature Medicine. The lead author is Hamilton Oh, PhD, a former graduate student in Wyss-Coray’s group.

Eleven organ systems, 3,000 proteins, 45,000 people

The scientists zeroed in on 44,498 randomly selected participants, ages 40 to 70, who were drawn from a longitudinal data-gathering endeavor called UK Biobank. This ongoing effort has collected multiple blood samples and updated medical reports from some 600,000 individuals over several years. These participants were monitored for up to 17 years for changes in their health status.

Wyss-Coray’s team made use of an advanced commercially available laboratory technology that counted the amounts of nearly 3,000 proteins in each participant’s blood. Some 15% of these proteins can be traced to single-organ origins, and many of the others to multiple-organ generation.

The researchers fed everybody’s blood-borne protein levels into a computer and determined the average levels of each of those organ-specific proteins in the blood of those people’s bodies, adjusted for age. From this, the scientists generated an algorithm that found how much the composite protein “signature” for each organ being assessed differed from the overall average for people of that age.

Based on the differences between individuals’ and age-adjusted average organ-assigned protein levels, the algorithm assigned a biological age to each of the 11 distinct organs or organ systems assessed for each subject. And it measured how far each organ’s multiprotein signature in any given individual deviated in either direction from the average for people of the same chronological age. These protein signatures served as proxies for individual organs’ relative biological condition. A greater than 1.5 standard deviation from the average put a person’s organ in the “extremely aged” or “extremely youthful” category.

One-third of the individuals in the study had at least one organ with a 1.5-or-greater standard deviation from the average, with the investigators designating any such organ as “extremely aged” or “extremely youthful.” One in four participants had multiple extremely aged or youthful organs.

For the brain, “extremely aged” translated to being among the 6% to 7% of study participants’ brains whose protein signatures fell at one end of the biological-age distribution. “Extremely youthful” brains fell into the 6% to 7% at the opposite end.

Health outcomes foretold

The algorithm also predicted people’s future health, organ by organ, based on their current organs’ biological age. Wyss-Coray and his colleagues checked for associations between extremely aged organs and any of 15 different disorders including Alzheimer’s and Parkinson’s diseases, chronic liver or kidney disease, Type 2 diabetes, two different heart conditions and two different lung diseases, rheumatoid arthritis and osteoarthritis, and more.

Risks for several of those diseases were affected by numerous different organs’ biological age. But the strongest associations were between an individual’s biologically aged organ and the chance that this individual would develop a disease associated with that organ. For example, having an extremely aged heart predicted higher risk of atrial fibrillation or heart failure, having aged lungs predicted heightened chronic obstructive pulmonary disease (COPD) risk, and having an old brain predicted higher risk for Alzheimer’s disease.

The association between having an extremely aged brain and developing Alzheimer’s disease was particularly powerful — 3.1 times that of a person with a normally aging brain. Meanwhile having an extremely youthful brain was especially protective against Alzheimer’s — barely one-fourth that of a person with a normally aged brain.

In other words, someone with a biologically old brain is approximately 12 times as likely to receive a new diagnosis of Alzheimer’s disease over the next decade or so as someone the same age with a biologically young brain.

In addition, Wyss-Coray said, brain age was the best single predictor of overall mortality. Having an extremely aged brain increased subjects’ risk of dying by 182% over a roughly 15-year period, while individuals with extremely youthful brains had an overall 40% reduction in their risk of dying over the same duration.

Predicting the disease, then preventing it

“This approach could lead to human experiments testing new longevity interventions for their effects on the biological ages of individual organs in individual people,” Wyss-Coray said.

Medical researchers may, for example, be able to use extreme brain age as a proxy for impending Alzheimer’s disease and intervene before the onset of outward symptoms, when there’s still time to arrest it, he said.

Careful collection of lifestyle, diet and prescribed- or supplemental-substance intake in clinical trials, combined with organ-age assessments, could throw light on the medical value of those factors’ contributions to the aging of various organs, as well as on whether existing, approved drugs can restore organ youth before people develop a disease for which an organ’s advanced biological age puts them at high risk, Wyss-Coray added.

“This is, ideally, the future of medicine,” he said. “Today, you go to the doctor because something aches, and they take a look to see what’s broken. We’re trying to shift from sick care to health care and intervene before people get organ-specific disease.”

Although the analytical tool is available only for research purposes now, Wyss-Coray has plans to commercialize it. He is a co-founder and scientific officer of Teal Omics and Vero Bioscience, two companies to whom Stanford University’s Office of Technology Licensing has licensed technology developed in this and related research for commercializing, respectively, screens for new drug targets and a consumer product.

The test could be available in the next two to three years, Wyss-Coray said. “The cost will come down as we focus on fewer key organs, such as the brain, heart and immune system, to get more resolution and stronger links to specific diseases.”

The study was funded by the National Institutes of Health (grants P50AG047366 and P30AG066515), the Milky Way Foundation, the Knight Initiative for Brain Resilience and the Stanford Alzheimer’s Disease Research Center.

 

# # #

 

About Stanford Medicine

Stanford Medicine is an integrated academic health system comprising the Stanford School of Medicine and adult and pediatric health care delivery systems. Together, they harness the full potential of biomedicine through collaborative research, education and clinical care for patients. For more information, please visit med.stanford.edu.

---

Journal

Nature Medicine

DOI

10.1038/s41591-025-03798-1 

Method of Research

Data/statistical analysis

Subject of Research

Human tissue samples

Article Title

Plasma proteomics links brain and immune system aging with healthspan and longevity

Article Publication Date

9-Jul-2025

 

Cancer is extremely rare in turtles, finds a new study

University of Nottingham

Facebook

XLinkedInWeChatBlueskyMessageWhatsAppEmail

 

image: 

Football and Burt

view more 

Credit: Chester Zoo

A new study, led by experts at the University of Nottingham, provides the strongest evidence to date that cancer is extremely rare in turtles, a finding that could offer valuable clues for preventing or fighting cancer in humans.

 

While previous research had hinted that cancer might be uncommon in turtles, the new analysis, published in BioScience, shows that only about 1% of individuals are affected, far less than in mammals or birds. The study was led by Dr Ylenia Chiari from the School of Life Sciences at the University of Nottingham, alongside Dr Scott Glaberman from the University of Birmingham, in collaboration with a team of researchers from zoos across the US, UK, and Europe.

 

The team analysed medical records and necropsies (autopsies) from hundreds of zoo turtles, including individuals from Chester Zoo in the UK.

 

The work was only possible thanks to a global network of zoos that have spent decades keeping detailed records and collaborating to support science, highlighting the vital role zoos can play in discovery research. The findings were striking not only for the low number of cancer cases, but also because, when tumours did appear, they almost never spread.

 

Some turtle species grow to tremendous size. Galapagos and Aldabra giant tortoises, for example, can weigh hundreds of kilograms. Turtles are also known for their long lifespans, and many are centenarians. One radiated tortoise at Chester Zoo named Burt was born in 1945 and may live to over 100, while some Galapagos and Aldabra giant tortoises have lived beyond 150 years.

Species that are both large and long-lived are expected to face higher cancer risk, since more cells mean more opportunities for something to go wrong. But turtles seem to defy this pattern.

 

Why are turtles so resistant to cancer? Their secret may lie in strong defences against cell damage, slow metabolism that reduces cellular stress, and unique genes that protect against cancer. Turtles could offer valuable clues for preventing or treating cancer in humans and are a promising model for studying healthy aging and cancer resistance.

 

Dr Ylenia Chiari said: “Turtles, especially iconic species like Galapagos and Aldabra giant tortoises, are famous for living long lives and growing to tremendous sizes. You’d expect that to mean more cancer, but our study, which combines decades of zoo records with previous research, shows how incredibly rare cancer is in these animals. It highlights turtles as an untapped model for understanding cancer resistance and healthy aging, and it shows the vital role zoos play in advancing science through collaboration.”

 

Dr Scott Glaberman added: “Biodiversity has so much to teach us about how the world works. While fascinating in their own right, extreme species like giant tortoises may have already solved many of the problems humans face, including those related to aging and cancer. That makes biodiversity doubly worthy of protection.”

 

Dr Helena Turner, Research Officer at Chester Zoo, said: “This research underscores the immense value of zoo-based science. At Chester Zoo, we’ve long been committed to detailed health monitoring and the long-term care of our animals. It’s fantastic to see these efforts not only contribute to advancing scientific knowledge around cancer resistance but also support vital conservation work to protect these remarkable species that may hold keys to medical breakthroughs benefiting both wildlife and humans.”

Several species of turtles are classified as Endangered or Critically Endangered according to the IUCN Red List, due to different threats including pressure from climate change, habitat loss, and illegal pet trade.

Many of the zoos that contributed data to the study, including Chester Zoo, are involved in conservation breeding programmes that aim to pull species like these back from extinction.

Radiated Turtoise

Credit

Chester Zoo

Galapagos tortoise

Credit

Dr Ylenia Chiari

---

Journal

BioScience

DOI

10.1093/biosci/biaf100 

Method of Research

Data/statistical analysis

Subject of Research

Animals

Article Title

Do turtles get cancer?

Article Publication Date

9-Jul-2025