University of Tsukuba


The University of Tsukuba is located in the suburbs of Tokyo and is at the heart of Tsukuba Science City —Japan’s largest “science city,” which has 29 national research institutes and about 150 private research organizations. The University operates on the principle that it is open to all.

The University of Tsukuba aims to cross the borders that separate a variety of organizations, such as those between nations, research institutions, and fields of study. The University’s network is expanding globally. In particular, the University has entered into ten campus-in-campus arrangements with universities in eight countries and regions, thereby promoting close cooperative relationships between education and research. At present, the University hosts approximately 2,200 study abroad students from more than 110 countries and regions.

Collaboration is essential in order to achieve high-quality outcomes with limited resources. As an example, the University is actively engaged in an exchange of talent and joint research that goes beyond the conventional university framework at nationwide joint-use institutes that encompass the four fields of computational science, marine science, plant science, and plasma research.

The Research and Development Centers are the part of the University’s quest to pursue research and innovation that result in benefits for society. Externally funded, twelve centers are newly established as industry-university-government partnerships for joint research in areas of high demand from the community.

The University is also proactively engaging in the support of venture corporations. Thus far, a total of 160 companies have originated from the University of Tsukuba, including Cyberdyne, Inc.

A frontrunner in university reform in Japan, the University is creating a flexible education and research structure as well as a university system to meet the needs of the next generation. It aspires to be a comprehensive university, continuously meeting new challenges and developing new areas. The foremost mission of a university is to provide an environment that allows future leaders to realize their full potential. The University gives students the opportunity to develop their individuality and skills through an education that is backed by cutting-edge research.

The University of Tsukuba retains sole responsibility for content. © 2021 The University of Tsukuba.

1 June 2020 - 31 May 2021

Region: Global
Subject/journal group: All

The table to the right includes counts of all research outputs for University of Tsukuba published between 1 June 2020 - 31 May 2021 which are tracked by the Nature Index.

Hover over the donut graph to view the FC output for each subject. Below, the same research outputs are grouped by subject. Click on the subject to drill-down into a list of articles organized by journal, and then by title.

Note: Articles may be assigned to more than one subject area.

Count Share
237 46.77

Outputs by subject (Share)

Subject Count Share
Physical Sciences 129 13.59
1 0.17
5 0.61
8 1.33
14 2.71
1 0.25
16 0.16
33 2.05
1 0.11
5 0.87
2 0.15
6 0.32
2 0.28
Competition and interplay between topology and quasi-periodic disorder in Thouless pumping of ultracold atoms
Chemotaxis under flow disorder shapes microbial dispersion in porous media
9 2.32
1 0.02
22 2.07
1 0.08
1 0.08
1 0.01
Earth & Environmental Sciences 12 5.10
Life Sciences 61 15.43
Chemistry 55 16

Highlight of the month

The nitrogen atoms that matter in fuel cell catalysts



The active nitrogen atoms in a carbon catalyst for polymer electrolyte fuel cells have been identified.

The high efficiency and flexibility of polymer electrolyte fuel cells make them attractive power sources for vehicles, but they usually use catalysts containing platinum. Catalysts made from carbon doped with nitrogen are promising as cheaper alternatives. But there has been considerable debate about the role the nitrogen atoms play.

Now, five researchers, all at the University of Tsukuba in Japan, have investigated the role nitrogen with the so-called pyridinic bonding configuration plays in catalysing the oxygen reduction reaction. They did this by using seven molecules containing pyridinic nitrogen.

They found that a molecule with two pyridinic nitrogen atoms its armchair edges exhibited the highest activity. This knowledge sheds light on the catalyst mechanism and will be helpful for optimizing catalysts.

Supported content

  1. Angewandte Chemie International Edition 60, 5121–5124 (2021). doi: 10.1002/anie.202014323

View the article on the Nature Index

See more research highlights from University of Tsukuba

More research highlights from University of Tsukuba

1 June 2020 - 31 May 2021

International vs. domestic collaboration by Share

  • 39.46% Domestic
  • 60.54% International

Note: Hover over the graph to view the percentage of collaboration.

Top 10 domestic collaborators by Share (229 total)

  • University of Tsukuba, Japan
  • Domestic institution
  1. The University of Tokyo (UTokyo), Japan (15.95)
  2. National Institute for Materials Science (NIMS), Japan (13.85)
  3. RIKEN, Japan (10.07)
  4. Kyoto University, Japan (9.58)
  5. National Institute of Advanced Industrial Science and Technology (AIST), Japan (9.25)
  6. Kyushu University, Japan (4.93)
  7. Tohoku University, Japan (4.74)
  8. Osaka University, Japan (3.89)
  9. Niigata University, Japan (3.44)
  10. Hokkaido University, Japan (3.43)

Note: Collaboration is determined by the fractional count (Share), which is listed in parentheses.

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