METAL ALCHEMY

Cracking the Secret of Kanazawa Gold Leaf’s Brilliant Texture

Researchers reveal unique crystal slip mechanism behind UNESCO-recognized gold leaf’s extraordinary thinness and luster

Japan Advanced Institute of Science and Technology

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image: 

A photo of Kanazawa gold leaf, one of the world’s thinnest metallic foils, achieves its brilliance and durability through a unique crystal arrangement. The transmission electron microscopy image provides evidence of activation in the non-octahedral {110}– <110> slip system.

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Credit: Yoshifumi Oshima from JAIST.

Ishikawa, Japan -- Kanazawa gold leaf is a traditional Japanese material known for its remarkable thinness, just 100 nanometers—about 1/1,000 the diameter of a human hair—and its brilliant shine. Made using the entsuke technique, a manual process of packing and hammering at room temperature, this ultra-thin foil is commonly used to decorate temples, shrines, crafts, and historical objects. While the skill of Kanazawa artisans has gained global recognition, including UNESCO’s designation as an Intangible Cultural Heritage in 2020, the scientific reason behind its unique thinness has remained unclear.

Now, researchers from the Japan Advanced Institute of Science and Technology (JAIST), led by Professor Yoshifumi Oshima, in collaboration with Doctoral Course Student Yuanzhe Xu; Senior Lecturer Kohei Aso; Prof. Hideyuki Murata at JAIST; and Specially Appointed Professor (Full Time) Satoshi Ichikawa at the University of Osaka, have uncovered the deformation processes that give Kanazawa gold leaf its special qualities. Using electron backscatter diffraction (EBSD) and transmission electron microscopy (TEM), this study, published on September 26, 2025, in npj Heritage Science, found that during the intense hammering process, the gold crystals go through an unusual change. Instead of recrystallizing, the material uses non-octahedral slip systems, specifically the {110}– < 110> slip system, which are usually inactive in gold.

This crystal behavior shifts hammering stress into the [001] direction, creating the characteristic cube texture that provides the leaf with its brilliance and durability. “Understanding how ultrathin films such as Kanazawa gold leaf can be fabricated via the pack and hammer method at room temperature while maintaining a {001} texture is of both scientific and practical significance,” explained Prof. Oshima.

The study compared two types of Kanazawa gold leaf. Zumi foil has a thickness of about 1 micrometer, while the more refined No. 4 Kanazawa gold leaf is only 0.1 micrometers thick. These samples represent different stages of the traditional entsuke hammering process. To reveal the structural changes that occur during fabrication, researchers used imaging techniques, including EBSD and TEM.

The results showed clear differences between the two materials. In the Zumi foil, the crystal texture was mixed, featuring many orientations and a high density of dislocations, which are tiny structural irregularities in the crystal lattice. In contrast, the No. 4 gold leaf had a well-ordered structure with a dominant {001} cube texture over large areas. This texture developed even though the hammering took place at room temperature and lacked the usual recrystallization process that typically helps with crystal alignment. The TEM images provided more insights, offering direct evidence of slip bands, which are narrow areas where many dislocations align together.

The study confirmed the activation of the {110}– < 110> slip system, a deformation mechanism rarely seen in gold. This was surprising because such mechanisms usually activate only under high temperatures or during processes like rolling, which apply stresses differently. The fact that traditional artisans achieve this effect through hand hammering at room temperature underscores the precision of the entsuke technique.

These findings matter beyond the cultural significance of Kanazawa gold leaf. By explaining how the leaf’s unique brilliance and durability develop, the research offers a scientific basis for the sustainable preservation of traditional crafts. Artisans who carry on the centuries-old tradition of gold leaf making can now work with a better grasp of the physical principles behind their craft. This knowledge helps ensure that cultural treasures, including temples, shrines, and historical artworks adorned with Kanazawa gold leaf, can be preserved and restored with confidence in the material’s performance. The study also links traditional craftsmanship with modern science and technology. The deformation mechanisms discovered may inspire the design of ultrathin metallic films with specific properties. These films could find applications in electronics, sensors, decorative coatings, and nanotechnology, where precise control of crystal orientation is crucial for performance and stability.

Looking ahead, these insights could guide the development of high-performance nanomaterials that combine extreme thinness with special optical, mechanical, and electronic properties. This might lead to innovations in flexible devices, sustainable decorative materials, and consumer electronics. As Prof. Oshima states, “Our study enables the development of high-performance nanomaterials with unique optical, mechanical, and electronic properties, driving innovations in consumer electronics, flexible devices, and sustainable decorative materials, and fostering cross-disciplinary breakthroughs inspired by traditional craftsmanship.”

This work shows how traditional Kanazawa gold leaf techniques can inspire modern materials science, ensuring their brilliance continues to influence future generations.

 

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Reference

Title of original paper: Deformation mechanism behind the unique texture of Kanazawa gold leaf Authors: Yuanzhe Xu, Satoshi Ichikawa, Kohei Aso, Hideyuki Murata and Yoshifumi Oshima* Journal: npj Heritage Science DOI: 10.1038/s40494-025-02055-5

 

                                           

About Japan Advanced Institute of Science and Technology, Japan

Founded in 1990 in Ishikawa prefecture, the Japan Advanced Institute of Science and Technology (JAIST) was the first independent national graduate university that has its own campus in Japan. Now, after 30 years of steady progress, JAIST has become one of Japan’s top-ranking universities. JAIST strives to foster capable leaders with a state-of-the-art education system where diversity is key; about 40% of its alumni are international students. The university has a unique style of graduate education based on a carefully designed coursework-oriented curriculum to ensure that its students have a solid foundation on which to carry out cutting-edge research. JAIST also works closely both with local and overseas communities by promoting industry–academia collaborative research.  

 

About Professor Yoshifumi Oshima from the Japan Advanced Institute of Science and Technology, Japan

Professor Yoshifumi Oshima is a faculty member at the Nanomaterials and Devices Research Area, Japan Advanced Institute of Science and Technology. His research spans crystallography, electron microscopy, and nanomaterials, with a focus on ultrathin metallic films and their deformation mechanisms. He has published extensively in materials science journals and leads projects integrating traditional craftsmanship with advanced nanotechnology to support both cultural heritage preservation and modern innovation.

 

Funding information

The work was supported by JSPS KAKENHI (Grant No. 23H00255), Advanced Research Infrastructure for Materials and Nanotechnology in Japan (ARIM) by MEXT (JPMXP1224OS0018), and the Electron Microscopy Group of NIMS Open Facility (23NM8160).

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Journal

npj Heritage Science

DOI

10.1038/s40494-025-02055-5 

Article Title

Deformation mechanism behind the unique texture of Kanazawa gold leaf

D.E.I.

Elsevier Foundation and RIKEN launch “Envisioning Futures” report: paving the way for gender equity and women’s leadership in Japanese research

Insights from Japanese women research leaders provide powerful role models for intergenerational dialogue

Elsevier

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A unique collaboration, the Elsevier Foundation and RIKEN, Japan’s premier research institute, have released “Envisioning Futures: Women’s Leadership and Gender Equity in Japanese Research,” a comprehensive report that shines a spotlight on the journeys, achievements and challenges faced by women research leaders in Japan. The report blends data-driven analysis with compelling personal narratives, offering a timely roadmap for institutional change and a call to action for the advancement of women in science and innovation.

The report shows that despite Japan’s global reputation for technological innovation, the country continues to grapple with persistent gender disparities in its research community. In a bid to help create a more inclusive and dynamic research ecosystem, “Envisioning Futures” tells stories that are not only testament to the resilience and ingenuity of pioneering women scientists but also serve as beacons of hope. By amplifying women’s voices and recognizing their indispensable contributions, this initiative aims to inspire future generations to break barriers and reimagine what is possible for Japanese science and society. Key highlights:

• Significant gender gap: As of March 31, 2024, women make up 22% of active researchers in– well below the global average of 41%.[1]
• Leadership Disparity: Women hold an even smaller share of senior positions, with only 16% of scientific publication authorships and 17% of patent applications by women, underscoring a stark underrepresentation at the highest levels[2].
• Nonlinear Pathways: Many women research leaders have advanced through flexible, opportunity-driven careers, reframing interruptions as sources of resilience and growth.
• People-centered leadership: Interviewees describe fostering lab cultures built on empowerment, collaboration and psychological safety – creating “communities of belonging”.
• Mentorship and networks: Access to mentorship and professional networks emerges as a vital driver of career progression and confidence-building for women in research.
• Cultural barriers: Persistent challenges include unconscious bias, unequal evaluation, cultural norms and limited institutional support for work-life balance.
• Progress and gaps: Japan’s ambitious government targets for women’s participation and leadership remain challenging, with incremental progress highlighting the need for continued vigilance and sustained action.
• Rethinking success metrics: Advocacy to broaden assessment criteria beyond publication metrics and patents to include societal impact, interdisciplinarity, mentorship and science communication ensuring that diverse contributions are valued.

“The journeys of these pioneering women research leaders remind us that true progress in science depends on inclusion, resilience and collective action. By embracing diverse career paths and recognizing a broader range of achievements, we can build a research ecosystem where all voices are heard and innovation flourishes,” said Dr. Yuko Harayama, Secretary General, Global Partnership on AI (GPAI); Former Executive Director, International Affairs, RIKEN and Former Member, The Elsevier Foundation Board.

“We are proud to partner with RIKEN on ‘Envisioning Futures’. By uniting the powerful stories of Japan’s women research leaders with national data, this report offers both insight and inspiration for change. RIKEN’s leadership and commitment to open dialogue are helping to shape a more inclusive future for Japanese science. Together, we are amplifying women’s voices and paving the way for the next generation of researchers to thrive,” added Ylann Schemm, Executive Director of The Elsevier Foundation.

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Notes to Editors:

Read the “Envisioning Futures” report, including profiles of female senior leaders and discover actionable recommendations for advancing gender equity in Japanese research.

For additional materials:

• Progress Toward Gender Equality in Research & Innovation – 2024, focus on Japan. This is an abridged version of the original report. Available in English and in Japanese.
• “RIKEN Female PI Oral History Project: The Path to PI” website, with transcripts of the interviews in English and in Japanese.  This page also includes short interview excerpts, available in Japanese with English subtitles.

 

Additional quotes from RIKEN PIs:

• Collaborative research cannot be successful if only one party enjoys the benefits. There has to be proper give and take.” Dr. Reiko Mazuka
• I come from an era where being treated as if I didn’t exist was normal. Become a PI was telling me not only ‘You’re here’, but ‘It’s okay for you to be here’.” Dr. Yoshie Otake
• Diversity reduces the incidence of various difficulties by making it possible for people to exchange information and possible solutions freely and not have to feel isolated when they run into a problem.”  Dr. Yukiko Goda

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About The Elsevier Foundation

The Elsevier Foundation contributes over $1 million a year to non-profit organizations through inclusive research and health partnerships which incubate new approaches to catalyze change towards the UN Sustainable Development Goals. Funded by Elsevier, the Elsevier Foundation is a key part of Elsevier’s commitment to advance inclusive research and healthcare in partnership with the communities it serves. Since 2005, the Elsevier Foundation has contributed over $18 million in grants to over 100 partners in 70 countries around the world. www.elsevierfoundation.org

About Elsevier

Elsevier is a global leader in advanced information and decision support. For over a century, we have been helping advance science and healthcare to advance human progress. We support academic and corporate research communities, doctors, nurses, future healthcare professionals and educators across 170 countries in their vital work.  We do this by delivering mission-critical insights and innovative solutions that combine trusted, evidence-based scientific and medical content with cutting-edge AI technologies to help impact makers achieve better outcomes. We champion inclusion and sustainability by embedding these values into our products and culture, working with the communities that we serve. The Elsevier Foundation supports research and health partnerships around the world.

Elsevier is part of RELX, a global provider of information-based analytics and decision tools for professional and business customers. For more information, visit www.elsevier.com and follow us on social media @elsevierconnect.  

 

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[1] Progress towards Gender Equality in Research & Innovation – 2024 Review - Focus on Japan.

[2] Ibid.

 

Chemists at Paderborn University discover new way of breaking down climate-damaging ‘laughing gas’

No laughing matter, but grounds for hope

Universität Paderborn

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‘Defying climate change calls for new approaches in breaking down greenhouse gases’, Professor Jan Paradies of Paderborn University said. The chemist and his team have now moved a step closer to this goal: the scientists have successfully managed to reduce ozone-damaging nitrous oxide (‘laughing gas’) to its harmless constituent parts using metal-free catalysis at low temperatures. The results were published in the internationally renowned Journal of the American Chemical Society.

‘Nitrous oxide is one of the most potent ozone-depleting substances and has a global warming potential 265 times higher than that of CO₂. It causes around six percent of global warming and is used in agricultural, industrial and medical processes. Its concentration in the atmosphere has risen by 20 percent since the industrial revolution. Given this environmental impact, there is a pressing need for research into new, efficient reduction methods’, Professor Paradies explained.

The research team, consisting of doctoral students Rundong Zhou and Viktorija Medvaric as well as Professor Thomas Werner and Professor Paradies, have demonstrated a facilitation of the oxygen transfer reaction from nitrous oxide to the phosphetane catalyst. Of the greenhouse gas, this then leaves behind only the harmless nitrogen, which can for example be further processed into fertiliser for agriculture. The new phosphetane-oxygen compound can then be returned to its original state via a reaction with a silane (a special chemical compound containing silicon and hydrogen), meaning that it can be repeatedly reused. This creates a catalytic cycle.

Go to paper: https://pubs.acs.org/doi/10.1021/jacs.5c06190

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Journal

Journal of the American Chemical Society

DOI

10.1021/jacs.5c06190 

 

Worrying levels of lead detected in the indigenous population of the Amazon

Universitat Autonoma de Barcelona

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Researchers from the UAB and the UB are working with indigenous Amazonian communities to understand health issues from a holistic perspective, including people, wildlife and the ecosystem. "In recent years we have studied various viral and parasitic pathogens, such as malaria and Chagas, in Amazonian communities", explains Pedro Mayor, principal coordinator of the research and lecturer in the Department of Animal Health and Anatomy at the UAB. "On this occasion we have focused on the issue of lead, as recent studies suggest that the ammunition used by Amazonian communities for subsistence hunting could be an important route of lead exposure for indigenous peoples in the rainforest."
Lead is a highly persistent and widely distributed toxic metal on a global scale. It accumulates in the food chain and can affect several vital organs. In children, it limits neuronal development, while in adults it causes liver damage, as well as cardiovascular and fertility problems. The study analysed lead levels in humans, wild animals and fish, as well as its possible sources—including river water used for drinking and cooking, surrounding soils, and lead ammunition used in subsistence hunting—in a very remote indigenous region in the northeastern Peruvian Amazon, an environment of intact and well-preserved forests.
The study identified the main routes of lead exposure in this community. The results show that river water—used daily for drinking and cooking—and ammunition used in subsistence hunting are the two main sources of contamination. The average blood lead concentrations were 11.74 micrograms per deciliter. Although there is no safe level of lead exposure, levels above 5 micrograms per deciliter are already associated with adverse health effects. In the indigenous community studied, 95.8% of children under 12 years of age and 94.5% of adults exceeded this threshold, reflecting widespread population exposure to lead and a worrying health risk situation.
In addition, high concentrations of lead were detected in wild animals and in the river water used as a source of drinking water. In wild animals, concentrations reached up to 1.7 mg/kg of lead in liver, well above the limit of 0.1 mg/kg permitted in meat for human consumption according to European legislation. A total of 99% of wild animal samples exceeded the legal maximum permitted in meat for direct consumption.
"We have observed that the main sources of lead for humans are river water, which the indigenous population uses for drinking and cooking, as well as the ammunition they use to carry out subsistence hunting. Fish and wildlife transport lead from the water, and this fauna also acts as a transporter of lead from ammunition", warns Pedro Mayor. "This threat that affects human populations is also important for the health of wildlife and the ecosystem in general, since lead bioaccumulates and biomagnifies throughout the food chain. Furthermore, this problem transcends the Amazon forest, since in all tropical forests on the planet the main tool used by subsistence hunters is a shotgun with lead-based ammunition". Martí Orta, co-author of the article and researcher in the Department of Evolutionary Biology, Ecology and Environmental Sciences of the Faculty of Biology and the Biodiversity Research Institute (IRBio) of the University of Barcelona,  points out that "the problem of lead goes beyond the Amazon and could have global implications for the health of indigenous populations, since currently shotguns and lead-based ammunition are the main tools used by communities that hunt and consume bushmeat as a means of subsistence".
 
Traditionally, lead pollution is associated with industrialised environments and with mining and waste recycling activities. Researchers warn that the evidence of high levels of lead in remote and non-industrialised areas demonstrates the urgency of implementing regional policies to prevent exposure to this metal through effective drinking water filtration systems and the use of non-toxic, lead-free ammunition.

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Journal

Toxics

DOI

10.3390/toxics13100826 

Method of Research

Randomized controlled/clinical trial

Subject of Research

People

Article Title

Unexpected High Blood Lead Levels in a Remote Indigenous Community in the Northeastern Peruvian Amazon