Tuesday, July 14, 2026

 

Beyond isolated optimization: a holistic review across the pre‑mid post‑treatment chain for hard carbon in sodium‑ion battery





Shanghai Jiao Tong University Journal Center
Beyond Isolated Optimization: A Holistic Review Across the Pre‑Mid Post‑Treatment Chain for Hard Carbon in Sodium‑Ion Battery 

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  • Proposes a holistic “Pre-Mid-Post” full-process engineering mode to go beyond fragmented single-point optimization of hard carbon anodes
  • Elucidates the synergistic and contradictory interplay among graphitic domains, nanopores, and defects in determining the Na⁺ storage properties
  • Future design necessitates cross-stage co-optimization and quantitative microstructure–performance relationships for rational HC engineering
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Credit: Qingxuan Geng, Yonghui Zhang, Dongxu Xie, Chenhui Hao, Liping Guo, Jiwei Zhang*, Paul K. Chu*, Qingwei Li*.





As the global energy transition accelerates, sodium-ion batteries (SIBs) are emerging as a compelling alternative to lithium-ion systems, offering superior low-temperature performance, enhanced safety, and faster charging at a fraction of the cost. Yet, the commercialization bottleneck remains locked in the anode—specifically, hard carbon (HC), the only commercially viable anode material for SIBs today. Now, researchers from Qilu University of Technology, Henan University, City University of Hong Kong, and Wuhan University of Science and Technology, led by Professor Qingwei Li, Professor Jiwei Zhang, and Professor Paul K. Chu, have delivered a landmark review that redefines how we engineer HC from the ground up.

Why This Review Matters

Traditional HC research has long been trapped in a fragmented paradigm—optimizing precursors, pyrolysis, or post-treatment in isolation. These single-point improvements often yield disappointing results because they ignore the intricate synergies and trade-offs across the entire fabrication chain. This work shatters that paradigm by proposing a holistic "Pre-Mid-Post" full-process engineering framework, treating HC development as a systematically coordinated chain rather than a collection of disconnected steps.

Innovative Framework and Mechanism

The review first decodes the "house-of-cards" microstructure of HC—randomly oriented graphitic nanodomains, nanopores, and defects—and clarifies how these four core structural features collectively govern sodium storage. It then systematically dissects each stage of the fabrication chain:

Pretreatment Engineering: From hydrothermal crosslinking and chemical crosslinking to pre-oxidation, pre-carbonization, pre-doping, component regulation, and pore-forming treatments. Each strategy is evaluated for its capacity to modulate graphitic domain growth, pore topology evolution, and defect engineering at the precursor stage.

Mid-Pyrolysis Control: The review critically compares conventional slow heating carbonization with next-generation technologies including flash Joule heating (FJH) and microwave-induced heating. Notably, FJH enables millisecond-scale carbonization that suppresses excessive graphitization while preserving expanded interlayer spacing—yielding HC with plateau capacities up to 290 mAh g-1 and energy savings of ~80%.

Post-Treatment Modification: Surface functional group regulation, post-doping, pore filling, surface coating, and pre-sodiation are analyzed as precision "pruning" tools to refine the preformed carbon framework. For instance, fluorine grafting via "grafting technology" achieves ICE up to 90.0% and stable cycling over 5,000 cycles at 2.0 A g-1.

Outstanding Synergies and Trade-offs

The review's analytical depth lies in exposing the dynamic contradictions within HC microstructures: expanded interlayer spacing boosts ion transport but may compromise electronic conductivity; abundant closed pores enhance plateau capacity but require careful control of open-to-closed pore ratios; defects provide active sites yet exacerbate irreversible SEI formation. The authors demonstrate that only cross-stage co-optimization—where pretreatment preconditions mid-pyrolysis outcomes, which in turn dictate post-treatment efficacy—can resolve these antagonistic effects.

Industrial Relevance and Future Outlook

Drawing from commercial benchmarks including Kuraray, ShengQuan Group, and BSG New Energy, the review addresses the critical gap between laboratory innovation and industrial mass production. It emphasizes raw material consistency control, continuous rotary kiln/roller furnace engineering, and batch-to-batch stability as prerequisites for scaling.

Looking forward, the authors chart six strategic directions: (1) establishing multi-scale quantitative structure–performance relationships via advanced characterization and machine learning; (2) developing cross-stage synergistic modification strategies; (3) promoting interdisciplinary integration of computational simulation and in situ characterization; (4) resolving engineering bottlenecks in large-scale fabrication; (5) standardizing precursor physicochemical information disclosure; and (6) harnessing machine learning to accelerate R&D cycles.

Stay tuned for more groundbreaking insights from this collaborative team across Qilu University of Technology, Henan University, City University of Hong Kong, and Wuhan University of Science and Technology!

 

Plasma agriculture makes strides towards super-seeding conventional methods


Researchers review the latest results and understanding of mechanisms behind this new field of research where seeds show higher yields and resilience following flash treatment in low-temperature plasma




Nagoya University

Low temperature plasma seed treatment 

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A sample of Yardlong Bean Seeds (Vigna unguiculata var. sesquipedalis) being treated under low-temperature plasma

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Credit: Sumeet Kulkarni, Nagoya University





Every once in a while, the sun unleashes powerful flares and coronal mass ejections which hurl plasma and energetic particles into space. On the infant Earth, this solar activity drove cascades of atmospheric chemical reactions that may have helped form the building blocks of life. More recently, scientists have discovered that applying plasma to seeds in a controlled way can trigger similar activity to make them more fast-growing and resilient. Researchers at Nagoya University and Kyushu University in Japan have compiled a comprehensive review of this new field — termed “Plasma Agriculture” — a potential sustainable solution to address global food shortage.

The word plasma brings to mind a hot, ionized inferno that makes up the fourth state of matter. But the plasma used here is different. By applying high electric voltage to air or any gas, electrons from a tiny fraction of its molecules get stripped off and gain very high energies. These electrons zipping around can effectively mimic the behavior of plasma even though the bulk of the gas remains at room temperature.

This low-temperature plasma, in turn, can be applied directly to seeds without burning them. Excessive use of chemicals and genetic modification of plants are a cause of concern for many people. In its place, plasma agriculture can offer similarly high crop yields without intrusion. 

“Low temperature plasma is an alternative to genetically modified crops”, said Kenji Ishikawa, professor at Nagoya University’s Center for Low-temperature Plasma Sciences

In a review published in the Journal of Advanced Research, Ishikawa and his collaborators at Kyushu University synthesize data from over 30 crop species and find that in more than two‑thirds of reported studies, well‑tuned plasma treatments boost seed vigor or yield, while the remaining cases show neutral or even negative effects when the dose is not properly controlled.

However, to ship this technology from the lab to the farm, a deeper understanding of the physical and biochemical processes through which low temperature plasma acts is necessary. For that reason, this review also summarizes the present state of knowledge of how and why plasma treatment works.

Plasma power for stronger seeds

Low-temperature plasma mainly operates by letting its energetic electrons collide with air molecules. This excites oxygen and nitrogen in air and breaks their bonds, generating Reactive Oxygen and Nitrogen Species (RONS) such as hydroxyl radicals, nitrates, nitrites, peroxides, and superoxides. RONS are wildly temperamental — they set off several cascades of chemical activity in living systems. Too many of them, and they can damage cells and tissues. But in just the right amounts, RONS act as signaling molecules in cells that lead to faster germination and enhanced seed growth.

That is why pinpointing the beneficial chemistry of plasma-induced RONS is crucial in determining for how long and at what intensity these plasma treatments should be applied. 

The pathways currently being researched include seed coat and surface changes, inactivation of surface pathogens, phytohormone-induced growth enhancement, and increased water and nutrient uptake. The reviewers find that many of these processes are interconnected and act together to drive plasma’s agricultural value.

The pathway that excites Ishikawa the most is epigenetic modification. If you think of the DNA as an operating system with encoded programs, epigenetics determines which programs are run and which ones are not, Ishikawa notes. This is different from genetic modification which introduces changes in the programs itself, potentially harboring risks. Studies show plasma-induced epigenetic changes cause positive expression of plant genes involved in germination, stress tolerance, and metabolism.

An eco-friendly fertilizer

Another way low‑temperature plasma can help farmers is by treating water and soil rather than just seeds. Air is rich in nitrogen which is also a vital element for plant growth. But the notoriously hard-to-break triple bond in a nitrogen molecule makes it difficult for plants to use it directly. Therefore, nitrogen must first be “fixed” by microbes, lightning, or artificially in energy-hungry and high-emission Haber-Bosch reactors. Low-temperature plasma offers an alternative: its electrical discharges can convert nitrogen in or into ammonia, nitrites, and nitrates in plasma-activated water that can be used as a fertilizer powered by electricity in place of fossil fuels. 

In recent times, global food production has been under tremendous stress due to changing weather patterns and a growing need to feed disparate populations. Nagoya University’s Center for Low-temperature Plasma Sciences unites physicists, biochemists, and agriculturists to help find sustainable solutions to this problem.

 

KAIST delivers world's first multi-country projection of the future impact of climate change on mental health



A joint KAIST–University of Tokyo research team finds that rising temperatures could increase the number of suicides associated with temperature exposure worldwide, with some regions expected to be affected more severely than others





The Korea Advanced Institute of Science and Technology (KAIST)

KAIST Delivers World's First Multi-Country Projection of the Future Impact of Climate Change on Mental Health 

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[Figure 1] Regional temperature–suicide associations. The red solid line represents the relative risk (RR) of suicide mortality across temperatures for 10 regions, based on data from 751 locations across 26 countries worldwide. The shaded area indicates the 95% confidence interval, and the dotted line indicates the reference temperature — the median of each region's temperature distribution. At the reference temperature, RR equals 1.

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Credit: KAIST




A new study has, for the first time in the world, quantitatively projected how climate change will affect mental health at a multi-country level. Applying future climate change scenarios, a KAIST research team found that temperature-related suicide mortality is expected to rise overall, with the scale of the increase varying by region.

KAIST (President Choongsik Bae) announced on the 10th of July that a joint research team led by Professor Yeonseung Chung from the Department of Mathematical Sciences and Professor Yoonhee Kim from the Department of Global Environmental Health, Graduate School of Medicine, at the University of Tokyo in Japan, analyzed daily suicide mortality and temperature data from 751 locations across 26 countries, and applied the latest climate change scenarios to project future temperature-related suicide mortality. The team found that temperature-related suicide mortality is expected to increase due to climate change, with the scale of the increase varying by region.

Climate change is increasing extreme weather events such as heat waves, floods, and wildfires, and is having a wide-ranging impact on human health. Recent studies have consistently reported that climate change affects not only physical health but also mental health, including depression, anxiety, and sleep disorders. In particular, the tendency for suicide risk to rise with increasing temperatures has been repeatedly confirmed across many countries, but few studies have quantitatively projected how future climate change will affect temperature-related suicide mortality.

The team explained that these regional differences are determined not only by the magnitude of future temperature increases, but also by each region's temperature–suicide relationship — how suicide risk changes with temperature. In East Asia, suicide risk was found to increase with rising temperatures, but the increase slowed at high temperatures, so the region's future rise in temperature-related suicide mortality is projected to be relatively small. Central and South America and Southeast Asia, by contrast, are projected to see relatively large future increases, driven by both greater projected temperature rises and a pattern in which suicide risk continues to climb steadily as temperatures rise.

The team pointed to a range of physiological and psychological changes — including sleep disturbances, increased stress, and impaired emotional regulation — as factors linking high temperatures to increased suicide risk. In particular, they explained that high temperatures can affect serotonin regulation and stress hormone secretion in the brain, potentially heightening depressive feelings and impulsivity, changes that may in turn contribute to increased suicide risk.

This study is significant as the first large-scale, multi-country quantitative projection of climate change's future impact on mental health. The findings show that climate change should not solely be considered an environmental issue but it should also be viewed from a mental health perspective, and they are expected to provide important scientific evidence for developing mental health policy and suicide prevention strategies in the era of climate change.

The team emphasized that reducing the future mental health burden of climate change will require strengthening heat wave response systems alongside expanded mental health services, protection for vulnerable populations, and suicide prevention policies tailored to regional climate characteristics. The team also said that it plans to conduct more refined future projection studies that account for demographic change, adaptation to high temperatures, and improvements in mental health services.

"We hope this research will be used to help prepare for the mental health burden of the era of climate change," said Professor Yeonseung Chung.

The study, with Hyeyeong Ro, a master's student in KAIST's Graduate School of Data Science, as first author, and Professor Yeonseung Chung from KAIST's Department of Mathematical Sciences and Professor Yoonhee Kim from the University of Tokyo as co-corresponding authors, was published on the 30th of June in the international mental health journal Nature Mental Health.

※ Paper title: "Multi-country projections of temperature-related suicide mortality"

※ DOI: https://doi.org/10.1038/s44220-026-00674-w

 

Risk of severe workplace violence clusters around specific routines, times and locations in forensic psychiatric inpatient care





University of Eastern Finland






Published in the Journal of Psychiatric and Mental Health Nursing, a recent study from the Department of Nursing Science at the University of Eastern Finland found that reported incidents of severe workplace violence in forensic psychiatric inpatient care are not evenly distributed, but are concentrated in specific everyday situations, ward areas and times of day.

The researchers analysed 956 workplace violence incident reports filed by nursing staff in a Finnish forensic psychiatric hospital between 2020 and 2024. The study examined, among other things, the timing and location of workplace violence incidents, the ward in which they occurred, as well as their association with patients’ everyday activities.

According to the study, severe workplace violence incidents were associated particularly with busy daytime and afternoon periods on the ward, outdoor activities, specific ward areas and differences between wards. Severe incidents were reported proportionally more often in patient rooms, seclusion rooms, outdoor areas and day rooms, for example.

“The findings suggest that, in addition to patient-related factors, the severity of workplace violence is also associated with everyday ward routines, situations and environmental factors. The risk of workplace violence is linked to the situation at hand and to how quickly nursing staff can receive support if the situation escalates,” says Doctoral Researcher Matias Karvonen of the Department of Nursing Science at the University of Eastern Finland.

In particular, patients’ outdoor activities emerged as an everyday situation associated with elevated risk. A higher proportion of violence incidents related to outdoor activities were classified as severe than incidents occurring in other locations. The qualitative analysis showed that in incidents related to outdoor activities, the violence often involved physical aggression, such as hitting, kicking, biting or spitting. However, the association of outdoor activities with severe workplace violence was small, indicating that outdoor activities should be viewed as one risk context among others.

“Outdoor activities should not be seen as a problem per se, as they play an important role in patients’ well-being and rehabilitation. Instead, the findings highlight the importance of preparing carefully for outdoor activities: the patient’s current state should be assessed, adequate staffing should be ensured and clear procedures should be agreed in advance,” Karvonen says.

According to the study, efforts to prevent workplace violence should focus particularly on recurring high-risk situations. For example, busy afternoon periods on wards, patient rooms, seclusion rooms, day rooms and outdoor activities may require more careful advance planning than usual, targeted allocation of staff resources and consideration of environmental factors that affect safety.

“Efforts to prevent workplace violence can be improved by making systematic use of information drawn from incident reports, as they help identify the everyday situations in which the risk of workplace violence increases and where preventive measures should be focused,” Karvonen notes.

According to the study, preventing workplace violence in forensic psychiatric care requires both an assessment of the patient’s individual situation and an examination of everyday ward routines and the care environment. The findings support the use of evidence-based preventive measures identified in previous research, such as dynamic risk assessment before high-risk situations, strengthening staff competence, reviewing incidents and learning from them, and developing ward-specific procedures. Since the study was based on voluntary incident reports from a single hospital, the findings should be interpreted as associations rather than direct causal relationships.