Member

A01

Research Group

A01-1
Creation of advanced π-conjugated molecules based on 2D/3D-hybridization of nanographenes

Organic and Carbon Nanomaterials Unit, Okinawa Institute of Science and Technology Graduate University
Associate Professor

Akimitsu Narita

Laboratory HP

A01-2
Creation of rigid and advanced π-conjugated molecules based on sp²/sp³ skeleton-hybridization

Graduate School of Science, Nagoya University
Professor

Akiko Yagi

Laboratory HP

A01-3
Synthesis of advanced π-conjugated molecules with a new π-bonding mode

Graduate School of Science, Tohoku University
Professor

Takeaki Iwamoto

Laboratory HP

A01-4
Creation of advanced π-conjugated molecules based on cyclic π-conjugated systems of heavier main group elements

A01 Leader
Faculty of Pure and Applied Sciences, University of Tsukuba
Professor

Takahiro Sasamori

Laboratory HP

Public Research Group

A01-5
Topology-Induced π-Molecular Complexity and Its Emergent Functions

Graduate School of Advanced Science and Engineering; WPI-SKCM2, Hiroshima University
Professor

Takeharu Haino

Laboratory HP

A01-6
Synthesis of Unexplored Twisted Nanocarbons toward Advanced Chiroptical Properties

School of Materials and Chemical Technology, Institute of Science Tokyo
Assistant Professor

Juntaro Nogami

Laboratory HP

A01-7
π-Molecular complexity based on heavier main group elements

Graduate School of Engineering, The University of Osaka
Professor

Koji Hirano

Laboratory HP

A01-8
Investigation and functionalization of antiaromatic compounds enabled by novel π-conjugation frameworks

Graduate School of Engineering, The University of Osaka
Assistant Professor

Akihto Konishi

Laboratory HP

A02

Research Group

A02-1
Functional stable radicals derived from advanced π-conjugated molecules

Graduate School of Engineering Science, The University of Osaka
Associate Professor

Akihiro Shimizu

Laboratory HP

A02-2
Functional switching controlled by multi-stage redox reaction of advanced π-conjugated molecules

Faculty of Science, Hokkaido University
Associate Professor

Yusuke Ishigaki

Laboratory HP

A02-3
Triplet engineering of advanced π-conjugated molecules

Department of Engineering Science, The University of Electro-Communications
Associate Professor

Shuzo Hirata

Laboratory HP

Institute of Materials Structure Science, High Energy Accelerator Research
Associate Professor

Keiki Fukumoto

Laboratory HP

A02-4
Advanced π-conjugated molecules with environment response for fluorescent imaging

A02 Leader
Institute of Transformative Bio-Molecules, Nagoya University
Professor

Shigehiro Yamaguchi

Laboratory HP

Public Research Group

A02-5
Time-resolved structural measurements of complex π-conjugated molecules in excited states elucidating their functions

Institute of Pure and Applied Sciences, University of Tsukuba
Professor

Masaki Hada

Laboratory HP

A02-6
Novel Approach to Generating Spin-Correlated Radical Pairs Based on Precise Molecular Design toward Nuclear Hyperpolarization

Graduate School of Science, The University of Tokyo
Assistant Professor

Takuya Shimajiri

Laboratory HP

A02-7
Multistage functional control based on advanced π-conjugated molecular systems with radical-ion character and state complexity

Faculty of Engineering, Aichi Institute of Technology
Professor

Shuichi Suzuki

Laboratory HP

A02-8
Manipulation of bond alternation and exploration of functions via controlled assembly of antiaromatic molecules

Graduate School of Engineering, Nagoya University
Professor

Hiroshi Shinokubo

Laboratory HP

A02-9
Development of highly efficient exciton fission and fusion materials based on precise control of inter-π-molecular interaction

Graduate School of Engineering, Kyushu University
Associate Professor

Yoichi Sasaki

Laboratory HP

A02-10
Force-based control of the electric/magnetic polarization of individual π molecules

Graduate School of Frontier Sciences, The University of Tokyo
Professor

Yoshiaki Sugimoto

Laboratory HP

A03

Research Group

A03-1
Advanced π-conjugated molecules: Control of organic-inorganic interface and application to organic electronic devices

A03 Leader
Institute for Chemical Research, Kyoto University
Professor

Atsushi Wakamiya

Laboratory HP

A03-2
Development of advanced π-conjugated molecular polarization systems and their application to actuators and sensors

Molecular Mechatronics Group, National Institute for Materials Science
Research Administrator

Masafumi Yoshio

Laboratory HP

Molecular Mechatronics Group, National Institute for Materials Science
Senior researcher

Junko Aimi

Laboratory HP

A03-3
Advanced π-conjugated molecular liquids for application in electret materials

Research Center for Materials Nanoarchitectonics, National Institute for Materials Science
Group Leader

Takashi Nakanishi

Laboratory HP

A03-4
The development of functions through the higher-order structures of nanospaces formed by advanced π-conjugated molecules

Graduate School of Engineering, Nagoya University
Professor

Ryotaro Matsuda

Laboratory HP

International Institute for Sustainability with Knotted Chiral Meta Matter/WPI-SKCM2, Hiroshima University
Professor

Hiroshi Sato

Laboratory HP

Public Research Group

A03-5
Development of Optically Pumped Organic Laser Displays

Institute of Pure and Applied Sciences, University of Tsukuba
Associate Professor

Hiroshi Yamagishi

Laboratory HP

A03-6
Integrated control of hierarchical π molecular complexity for next generation molecular targeted photomedicine

Research Center for Macromolecules and Biomaterials, National Institute for Materials Science
Senior Researcher

Hajime Shigemitsu

Laboratory HP

A03-7
Development of next-generation organic electron storage function based on porous highly π-conjugated molecular systems

School of Engineering, Kwansei Gakuin University
Professor

Hirofumi Yoshikawa

Laboratory HP

A03-8
Metabolically Inspired Organic Electronic Devices Based on π-Ion Gels

Institute of Pure and Applied Sciences, University of Tsukuba
Assistant Professor

Soh Kushida

Laboratory HP

A03-9
High-entropy π crystals: Creation of photon cavities with controlled arrangement and orientation through molecular mixing

School of Engineering Science, Kochi University of Technology
Professor

Shotaro Hayashi

Laboratory HP

A03-10
Exploration of π-conjugated molecules for regulating gene expression

Graduate School of Engineering, The University of Osaka
Associate Professor

Masafumi Minoshima

Laboratory HP

Research Group

A04-1
In-silico design of advanced π-conjugated molecules integrated with functional field modeling

A04 Leader
Institute of Transformative Bio-Molecules, Nagoya University
Professor

Takeshi Yanai

Laboratory HP

Institute for Catalysis, Hokkaido University
Professor

Jun-ya Hasegawa

Laboratory HP

Public Research Group

A04-2
Virtual Molecule-Based Optimization of Excited-State Energy Landscapes for Controlling the Photoresponses of π-Conjugated Molecules

Institute for Chemical Reaction Design and Discovery, Hokkaido University
Specially Appointed Associate Professor

Wataru Matsuoka

Laboratory HP

A04-3
Development of a platform for exploring advanced π-conjugated molecules via Δ-property-driven panoramic complexity mapping

Graduate School of Science, The University of Osaka
Assistant Professor

Kensuke Suga

Laboratory HP

A04-4
Theory development for understanding and controlling state complexity and design of highly efficient hetero-singlet fission systems

Graduate School of Engineering Science, The University of Osaka
Associate Professor

Ryohei Kishi

Laboratory HP

Member

A01

Research Group

A01-1Creation of advanced π-conjugated molecules based on 2D/3D-hybridization of nanographenes

A01-2Creation of rigid and advanced π-conjugated molecules based on sp2/sp3 skeleton-hybridization

A01-3Synthesis of advanced π-conjugated molecules with a new π-bonding mode

A01-4Creation of advanced π-conjugated molecules based on cyclic π-conjugated systems of heavier main group elements

Public Research Group

A01-5Topology-Induced π-Molecular Complexity and Its Emergent Functions

A01-6Synthesis of Unexplored Twisted Nanocarbons toward Advanced Chiroptical Properties

A01-7π-Molecular complexity based on heavier main group elements

A01-8Investigation and functionalization of antiaromatic compounds enabled by novel π-conjugation frameworks

A02

Research Group

A02-1Functional stable radicals derived from advanced π-conjugated molecules

A02-2 Functional switching controlled by multi-stage redox reaction of advanced π-conjugated molecules

A02-3Triplet engineering of advanced π-conjugated molecules

A02-4Advanced π-conjugated molecules with environment response for fluorescent imaging

Public Research Group

A02-5Time-resolved structural measurements of complex π-conjugated molecules in excited states elucidating their functions

A02-6Novel Approach to Generating Spin-Correlated Radical Pairs Based on Precise Molecular Design toward Nuclear Hyperpolarization

A02-7Multistage functional control based on advanced π-conjugated molecular systems with radical-ion character and state complexity

A02-8Manipulation of bond alternation and exploration of functions via controlled assembly of antiaromatic molecules

A02-9Development of highly efficient exciton fission and fusion materials based on precise control of inter-π-molecular interaction

A02-10Force-based control of the electric/magnetic polarization of individual π molecules

A03

Research Group

A03-1Advanced π-conjugated molecules: Control of organic-inorganic interface and application to organic electronic devices

A03-2Development of advanced π-conjugated molecular polarization systems and their application to actuators and sensors

A03-3Advanced π-conjugated molecular liquids for application in electret materials

A03-4The development of functions through the higher-order structures of nanospaces formed by advanced π-conjugated molecules

Public Research Group

A03-5Development of Optically Pumped Organic Laser Displays

A03-6Integrated control of hierarchical π molecular complexity for next generation molecular targeted photomedicine

A03-7Development of next-generation organic electron storage function based on porous highly π-conjugated molecular systems

A03-8Metabolically Inspired Organic Electronic Devices Based on π-Ion Gels

A03-9High-entropy π crystals: Creation of photon cavities with controlled arrangement and orientation through molecular mixing

A03-10Exploration of π-conjugated molecules for regulating gene expression

Research Group

A04-1In-silico design of advanced π-conjugated molecules integrated with functional field modeling

Public Research Group

A04-2Virtual Molecule-Based Optimization of Excited-State Energy Landscapes for Controlling the Photoresponses of π-Conjugated Molecules

A04-3Development of a platform for exploring advanced π-conjugated molecules via Δ-property-driven panoramic complexity mapping

A04-4Theory development for understanding and controlling state complexity and design of highly efficient hetero-singlet fission systems

Member

A01-1
Creation of advanced π-conjugated molecules based on 2D/3D-hybridization of nanographenes

A01-2
Creation of rigid and advanced π-conjugated molecules based on sp²/sp³ skeleton-hybridization

A01-3
Synthesis of advanced π-conjugated molecules with a new π-bonding mode

A01-4
Creation of advanced π-conjugated molecules based on cyclic π-conjugated systems of heavier main group elements

A01-5
Topology-Induced π-Molecular Complexity and Its Emergent Functions

A01-6
Synthesis of Unexplored Twisted Nanocarbons toward Advanced Chiroptical Properties

A01-7
π-Molecular complexity based on heavier main group elements

A01-8
Investigation and functionalization of antiaromatic compounds enabled by novel π-conjugation frameworks

A02-1
Functional stable radicals derived from advanced π-conjugated molecules

A02-2
Functional switching controlled by multi-stage redox reaction of advanced π-conjugated molecules

A02-3
Triplet engineering of advanced π-conjugated molecules

A02-4
Advanced π-conjugated molecules with environment response for fluorescent imaging

A02-5
Time-resolved structural measurements of complex π-conjugated molecules in excited states elucidating their functions

A02-6
Novel Approach to Generating Spin-Correlated Radical Pairs Based on Precise Molecular Design toward Nuclear Hyperpolarization

A02-7
Multistage functional control based on advanced π-conjugated molecular systems with radical-ion character and state complexity

A02-8
Manipulation of bond alternation and exploration of functions via controlled assembly of antiaromatic molecules

A02-9
Development of highly efficient exciton fission and fusion materials based on precise control of inter-π-molecular interaction

A02-10
Force-based control of the electric/magnetic polarization of individual π molecules

A03-1
Advanced π-conjugated molecules: Control of organic-inorganic interface and application to organic electronic devices

A03-2
Development of advanced π-conjugated molecular polarization systems and their application to actuators and sensors

A03-3
Advanced π-conjugated molecular liquids for application in electret materials

A03-4
The development of functions through the higher-order structures of nanospaces formed by advanced π-conjugated molecules

A03-5
Development of Optically Pumped Organic Laser Displays

A03-6
Integrated control of hierarchical π molecular complexity for next generation molecular targeted photomedicine

A03-7
Development of next-generation organic electron storage function based on porous highly π-conjugated molecular systems

A03-8
Metabolically Inspired Organic Electronic Devices Based on π-Ion Gels

A03-9
High-entropy π crystals: Creation of photon cavities with controlled arrangement and orientation through molecular mixing

A03-10
Exploration of π-conjugated molecules for regulating gene expression

A04-1
In-silico design of advanced π-conjugated molecules integrated with functional field modeling

A04-2
Virtual Molecule-Based Optimization of Excited-State Energy Landscapes for Controlling the Photoresponses of π-Conjugated Molecules

A04-3
Development of a platform for exploring advanced π-conjugated molecules via Δ-property-driven panoramic complexity mapping

A04-4
Theory development for understanding and controlling state complexity and design of highly efficient hetero-singlet fission systems