Basic Information

Affiliated programs (koza)

• Graduate School of Energy Science, エネルギー基礎科学専攻 エネルギー物質科学講座, 講師

Faculty

• 国際高等教育院

Academic Degree

• Ｍ．Ｓ．(マドラス大学)
• 博士（理学）(東北大学)

Research History

• From Feb. 2015, To Present

  Institute of Advanced Energy, Kyoto University, (In Collaboration with Prof. Takashi Morii & Dr. Eiji Nakata), Junior Associate Professor
• From Sep. 2013, To Jan. 2015

  Life Science Center of TARA, University of Tsukuba, (In Collaboration with Prof. Makoto Komiyama), Assistant Professor
• From Jan. 2010, To Aug. 2013

  WPI-iCeMS & Department of Chemistry, Kyoto University, (In Collaboration with Prof. Hiroshi Sugiyama & Dr. Masayuki Endo), CREST & JSPS Postdoctoral Researcher
• From Nov. 2008, To Dec. 2009

  FIBER, Konan University, (In Collaboration with Prof. Naoki Sugimoto & Dr. Shu-ichi Nakano), Postdoctoral Researcher

ID,URL

• J-Global ID

  201801017643092679

• External link

  https://drraj.webnode.com

researchmap URL

• https://researchmap.jp/raji

Research

Research Interests

• Nano/Bio Materials
• DNA Nanotechnology
• Applied Chemistry
• Biorelevant Chemistry
• Nucleic Acids Chemistry

Research Areas

• Nanotechnology/Materials, Nanobioscience
• Nanotechnology/Materials, Nanomaterials
• Nanotechnology/Materials, Molecular biochemistry

Papers

• Cucurbit[6]uril-stabilized copper oxide nanoparticles: Synthesis, potent antimicrobial and in vitro anticancer activity

  Anakha D. Rajeeve; Vyshnavi T. Veetil; P.K. Krishnan Namboori; R. Yamuna; Arivazhagan Rajendran

  Journal of Molecular Liquids, Dec. 2024, Peer-reviewed, Corresponding author

  
• Functional Nucleic Acid-Protein Complexes: Application to Fluorescent Ribonucleopeptide Sensors

  Arivazhagan Rajendran; Shiwei Zhang; Takashi Morii

  Handbook of Chemical Biology of Nucleic Acids, 26 Nov. 2022, Peer-reviewed, Lead author

  
• Front Cover: Topologically‐Interlocked Minicircles as Probes of DNA Topology and DNA‐Protein Interactions (Chem. Eur. J. 22/2022)

  Arivazhagan Rajendran; Kirankumar Krishnamurthy; Seojeong Park; Eiji Nakata; Youngjoo Kwon; Takashi Morii

  Chemistry – A European Journal, 23 Mar. 2022

  
• Implantable Microfluidic Device: An Epoch of Technology

  Abey Joseph; Arivazhagan Rajendran; Akash Karthikeyan; Baiju G. Nair

  Current Pharmaceutical Design, Mar. 2022, Peer-reviewed

  
• Affinity Isolation of Defined Genomic Fragments Cleaved by Nuclease S1‐based Artificial Restriction DNA Cutter

  Arivazhagan Rajendran; Narumi Shigi; Jun Sumaoka; Makoto Komiyama

  Current Protocols in Nucleic Acid Chemistry, 12 Feb. 2019, Peer-reviewed, Lead author

  
• Artificial Restriction DNA Cutter Using Nuclease S1 for Site‐Selective Scission of Genomic DNA

  Arivazhagan Rajendran; Narumi Shigi; Jun Sumaoka; Makoto Komiyama

  Current Protocols in Nucleic Acid Chemistry, 05 Feb. 2019, Peer-reviewed, Lead author

  
• Near Quantitative Ligation Results in Resistance of DNA Origami Against Nuclease and Cell Lysate

  Kirankumar Krishnamurthy; Arivazhagan Rajendran; Eiji Nakata; Takashi Morii

  Small Methods, 21 Sep. 2023, Peer-reviewed, Lead author

  
• Topologically-Interlocked Minicircles as Probes of DNA Topology and DNA-Protein Interactions.

  Arivazhagan Rajendran; Kirankumar Krishnamurthy; Seojeong Park; Eiji Nakata; Youngjoo Kwon; Takashi Morii

  Chemistry (Weinheim an der Bergstrasse, Germany), 19 Apr. 2022, Peer-reviewed, Lead author

  
• Topologically-Interlocked Minicircles as Probes of DNA Topology and DNA-Protein Interactions.

  Arivazhagan Rajendran; Kirankumar Krishnamurthy; Seojeong Park; Eiji Nakata; Youngjoo Kwon; Takashi Morii

  Chemistry (Weinheim an der Bergstrasse, Germany), 19 Apr. 2022

  
• Tuning the Reactivity of a Substrate for SNAP-Tag Expands Its Application for Recognition-Driven DNA-Protein Conjugation.

  Zhengxiao Zhang; Eiji Nakata; Huyen Dinh; Masayuki Saimura; Arivazhagan Rajendran; Kazunari Matsuda; Takashi Morii

  Chemistry (Weinheim an der Bergstrasse, Germany), 23 Dec. 2021, Peer-reviewed

  
• Stabilization and structural changes of 2D DNA origami by enzymatic ligation.

  Arivazhagan Rajendran; Kirankumar Krishnamurthy; Amulya Giridasappa; Eiji Nakata; Takashi Morii

  Nucleic acids research, 20 Aug. 2021, Peer-reviewed, Lead author

  Access this paper :

  
• One-Pot Isolation of a Desired Human Genome Fragment by Using a Biotinylated pcPNA/S1 Nuclease Combination

  Arivazhagan Rajendran; Narumi Shigi; Jun Sumaoka; Makoto Komiyama

  Biochemistry, 22 May 2018, Peer-reviewed, Lead author

  
• Covalent bond formation by modular adaptors to locate multiple enzymes on a DNA scaffold

  Eiji Nakata; Shun Nakano; Arivazhagan Rajendran; Takashi Morii

  Kinetic Control in Synthesis and Self-Assembly, 01 Jan. 2018, Peer-reviewed

  
• Nucleic-Acid-Templated Enzyme Cascades

  Arivazhagan Rajendran; Eiji Nakata; Shun Nakano; Takashi Morii

  ChemBioChem, Apr. 2017, Peer-reviewed

  
• Small molecule binding to a G-hairpin and a G-triplex: A new insight into anticancer drug design targeting G-rich regions

  Arivazhagan Rajendran; Masayuki Endo; Kumi Hidaka; Marie Paule Teulade-Fichou; Jean Louis Mergny; Hiroshi Sugiyama

  Chemical Communications, 04 Jun. 2015, Peer-reviewed, Lead author

  Access this paper :

  
• Direct Observation of G-Quadruplexes and their Folding Intermediates

  A. Rajendran; Y. Li; M. Endo; H. Sugiyama

  DNA G-quadruplexes as new anticancer targets (R. De Vooght-Johnson Ed.), Future Science, 2015, Peer-reviewed, Lead author

  
• Affinity isolation of desired restriction fragment from human genome using double-duplex invasion of biotin-bound pseudo-complementary PNA

  Narumi Shigi; Arivazhagan Rajendran; Xiaohui Wang; Hiroko Kunifuda; Jun Sumaoka; Makoto Komiyama

  Chemistry Letters, 2015, Peer-reviewed

  
• A lock-and-key mechanism for the controllable fabrication of DNA origami structures

  Arivazhagan Rajendran; Masayuki Endo; Kumi Hidaka; Naohiko Shimada; Atsushi Maruyama; Hiroshi Sugiyama

  Chemical Communications, 10 Jul. 2014, Peer-reviewed

  
• Direct and single-molecule visualization of the solution-state structures of G-hairpin and G-triplex intermediates

  Arivazhagan Rajendran; Masayuki Endo; Kumi Hidaka; Hiroshi Sugiyama

  Angewandte Chemie - International Edition, Apr. 2014, Peer-reviewed

  
• State-of-the-art high-speed atomic force microscopy for investigation of single-molecular dynamics of proteins

  Arivazhagan Rajendran; Masayuki Endo; Hiroshi Sugiyama

  Chemical Reviews, 22 Jan. 2014, Peer-reviewed

  
• G-quadruplex-binding ligand-induced DNA synapsis inside a DNA origami frame

  Arivazhagan Rajendran; Masayuki Endo; Kumi Hidaka; Phong Lan Thao Tran; Marie Paule Teulade-Fichou; Jean Louis Mergny; Hiroshi Sugiyama

  RSC Advances, 2014, Peer-reviewed

  
• HIV-1 nucleocapsid proteins as molecular chaperones for tetramolecular antiparallel g-quadruplex formation

  Arivazhagan Rajendran; Masayuki Endo; Kumi Hidaka; Phong Lan Thao Tran; Jean Louis Mergny; Robert J. Gorelick; Hiroshi Sugiyama

  Journal of the American Chemical Society, 11 Dec. 2013, Peer-reviewed

  
• Controlling the stoichiometry and strand polarity of a tetramolecular G-quadruplex structure by using a DNA origami frame

  Arivazhagan Rajendran; Masayuki Endo; Kumi Hidaka; Phong Lan Thao Tran; Jean Louis Mergny; Hiroshi Sugiyama

  Nucleic Acids Research, Oct. 2013, Peer-reviewed

  Access this paper :

  
• Direct and real-time observation of rotary movement of a DNA nanomechanical device

  Arivazhagan Rajendran; Masayuki Endo; Kumi Hidaka; Hiroshi Sugiyama

  Journal of the American Chemical Society, 23 Jan. 2013, Peer-reviewed

  
• G-quadruplex Nanostructures Probed at the Single Molecular Level by Force-based Methods

  Dhakal Soma; Mao Hanbin; Rajendran Arivazhagan; Endo Masayuki; Sugiyama Hiroshi

  Guanine Quartets: Structure and Application, 2013, Peer-reviewed

  
• Control of the two-dimensional crystallization of DNA origami with various loop arrangements

  Arivazhagan Rajendran; Masayuki Endo; Kumi Hidaka; Hiroshi Sugiyama

  Chemical Communications, 2013, Peer-reviewed

  
• ChemInform Abstract: Deciphering DNA-Based Asymmetric Catalysis Through Intramolecular Friedel-Crafts Alkylations.

  Park Soyoung; Ikehata Keiichi; Watabe Ryo; Hidaka Yuta; Rajendran Arivazhagan; Sugiyama Hiroshi

  ChemInform, 2013, Peer-reviewed

  
• Deciphering DNA-based asymmetric catalysis through intramolecular friedel–crafts alkylations

  Soyoung Park; Keiichi Ikehata; Ryo Watabe; Yuta Hidaka; Arivazhagan Rajendran; Hiroshi Sugiyama

  Chemical Communications, 26 Sep. 2012, Peer-reviewed

  Access this paper :

  
• Dna origami: Synthesis and self-assembly

  Arivazhagan Rajendran; Masayuki Endo; Hiroshi Sugiyama

  Current Protocols in Nucleic Acid Chemistry, Mar. 2012, Peer-reviewed

  
• Single-molecule analysis using DNA origami

  Arivazhagan Rajendran; Masayuki Endo; Hiroshi Sugiyama

  Angewandte Chemie - International Edition, 23 Jan. 2012, Peer-reviewed

  
• STRUCTURAL AND FUNCTIONAL ANALYSIS OF PROTEINS BY HIGH-SPEED ATOMIC FORCE MICROSCOPY

  Arivazhagan Rajendran; Masayuki Endo; Hiroshi Sugiyama

  STRUCTURAL AND MECHANISTIC ENZYMOLOGY: BRINGING TOGETHER EXPERIMENTS AND COMPUTING, 2012, Peer-reviewed

  
• Einzelmolekülanalysen mithilfe von DNA-Origami

  2012, Peer-reviewed

  
• ChemInform Abstract: Single-Molecule Analysis Using DNA Origami

  Rajendran Arivazhagan; Endo Masayuki; Sugiyama Hiroshi

  ChemInform, 2012, Peer-reviewed

  
• Structural and functional analysis of proteins by high-speed atomic force microscopy

  Arivazhagan Rajendran; Masayuki Endo; Hiroshi Sugiyama

  Advances in Protein Chemistry and Structural Biology, 2012, Peer-reviewed

  
• Photo-cross-linking-assisted thermal stability of DNA origami structures and its application for higher-temperature self-assembly

  Arivazhagan Rajendran; Masayuki Endo; Yousuke Katsuda; Kumi Hidaka; Hiroshi Sugiyama

  Journal of the American Chemical Society, 21 Sep. 2011, Peer-reviewed

  
• Two-dimensional DNA origami assemblies using a four-way connector

  Masayuki Endo; Tsutomu Sugita; Arivazhagan Rajendran; Yousuke Katsuda; Tomoko Emura; Kumi Hidaka; Hiroshi Sugiyama

  Chemical Communications, 01 Mar. 2011, Peer-reviewed

  
• Programmed two-dimensional self-assembly of multiple DNA origami jigsaw pieces

  Arivazhagan Rajendran; Masayuki Endo; Yousuke Katsuda; Kumi Hidaka; Hiroshi Sugiyama

  ACS Nano, 25 Jan. 2011, Peer-reviewed

  
• Effect of substituents of alloxazine derivatives on the selectivity and affinity for adenine in AP-site-containing DNA duplexes

  Burki Rajendar; Arivazhagan Rajendran; Zhiqiang Ye; Eriko Kanai; Yusuke Sato; Seiichi Nishizawa; Marek Sikorski; Norio Teramae

  Organic and Biomolecular Chemistry, 07 Nov. 2010, Peer-reviewed

  
• Folding pathways of human telomeric type-1 and type-2 G-Quadruplex structures

  Tomoko Mashimo; Hirotaka Yagi; Yuta Sannohe; Arivazhagan Rajendran; Hiroshi Sugiyama

  Journal of the American Chemical Society, 27 Oct. 2010, Peer-reviewed

  
• Effect of the bases flanking an abasic site on the recognition of nucleobase by amiloride

  Arivazhagan Rajendran; Chunxia Zhao; Burki Rajendar; Viruthachalam Thiagarajan; Yusuke Sato; Seiichi Nishizawa; Norio Teramae

  Biochimica et Biophysica Acta - General Subjects, Jun. 2010, Peer-reviewed

  
• NBD-based green fluorescent ligands for typing of thymine-related SNPs by using an abasic site-containing probe DNA

  Viruthachalam Thiagarajan; Arivazhagan Rajendran; Hiroyuki Satake; Seiichi Nishizawa; Norio Teramae

  ChemBioChem, 04 Jan. 2010, Peer-reviewed

  
• Molecular crowding of the cosolutes induces an intramolecular i-motif structure of triplet repeat DNA oligomers at neutral pH

  Arivazhagan Rajendran; Shu Ichi Nakano; Naoki Sugimoto

  Chemical Communications, 2010, Peer-reviewed

  
• Simultaneous recognition of nucleobase and sites of DNA damage: Effect of tethered cation on the binding affinity

  Arivazhagan Rajendran; Viruthachalam Thiagarajan; Burki Rajendar; Seiichi Nishizawa; Norio Teramae

  Biochimica et Biophysica Acta - General Subjects, Feb. 2009, Peer-reviewed

  
• Effect of methyl substitution in a ligand on the selectivity and binding affinity for a nucleobase: A case study with isoxanthopterin and its derivatives

  Burki Rajendar; Arivazhagan Rajendran; Yusuke Sato; Seiichi Nishizawa; Norio Teramae

  Bioorganic and Medicinal Chemistry, 01 Jan. 2009, Peer-reviewed

  
• A pyrazine-based fluorescence-enhancing ligand with a high selectivity for thymine in AP site-containing DNA duplexes

  Chunxia Zhao; Arivazhagan Rajendran; Qing Dai; Seiichi Nishizawa; Norio Teramae

  Analytical Sciences, Jun. 2008, Peer-reviewed

  
• DNA-DNA cross-linking mediated by bifunctional [SalenAl^III]⁺ complex

  Arivazhagan Rajendran; Chinnian J. Magesh; Paramasivan T. Perumal

  Biochimica et Biophysica Acta - General Subjects, Feb. 2008, Peer-reviewed

  
• Unprecedented dual binding behaviour of acridine group of dye: A combined experimental and theoretical investigation for the development of anticancer chemotherapeutic agents

  Arivazhagan Rajendran; Balachandran Unni Nair

  Biochimica et Biophysica Acta - General Subjects, Dec. 2006, Peer-reviewed

  
• Calculation of solvent shifts on electronic g-tensors with the conductor-like screening model (COSMO) and its self-consistent generalization to real solvents (direct COSMO-RS)

  Sebastian Sinnecker; Arivazhagan Rajendran; Andreas Klamt; Michael Diedenhofen; Frank Neese

  Journal of Physical Chemistry A, 16 Feb. 2006, Peer-reviewed

  
• Abstracts of the XIIth international symposium on luminescence spectrometry—Detection techniques in biomedical, environmental and food analysis (ISLS 2006)

  Luminescence, 2006, Peer-reviewed

  
• Tight-binding quantum chemical molecular dynamics simulation of mechano-chemical reactions during chemical-mechanical polishing process of SiO 2 surface by CeO 2 particle

  Arivazhagan Rajendran; Yasufumi Takahashi; Michihisa Koyama; Momoji Kubo; Akira Miyamoto

  Applied Surface Science, 15 May 2005, Peer-reviewed

  

Misc.

• Topologically interlocked DNA nanostructures inside a DNA origami

  A. Rajendran; S. Park; 中田栄司; Y. Kwon; 森井孝

  The 97th CSJ Annual Meeting, Tokyo, 2017.3.16-20, 2017

  
• Two-Dimensional Self-Assembly and Photo-Cross-Linking Induced Thermal-Stabilization of DNA Origami Structures

  A. Rajendran; M. Endo; K. Hidaka; H. Sugiyama

  9th Conference on the Foundations of Nanoscience 2012, Snowbird, UT, Apr. 2012

  
• Programmed Self-Assembly and Thermal-Stabilization of DNA Origami Nanostructure

  A. Rajendran; M. Endo; Y. Katsuda; K. Hidaka; H. Sugiyama

  The 38th International Symposium on Nucleic Acid Chemistry, Sapporo, Nov. 2011

  
• Programmed Self-Assembly of Pre-Designed DNA Nanoconstrcts for the preparation of suitable Platform for Nano-Bio Application

  A. Rajendran; M. Endo; T. Sugita; Y. Katsuda; K. Hidaka; H. Sugiyama

  Pacific Basin Societies (PACIFICHEM), Hawaii, Dec. 2010, Peer-reviewed

  

Media Coverage

• Cover Profile

  Chemistry - A European Journal, Topologically-Interlocked Minicircles as Probes of DNA Topology and DNA–Protein Interactions, https://doi.org/10.1002/chem.202200839, Mar. 2022, Paper

  
• From mountains to oceans

  Chemistry and Chemical Industry, CCI Salone, Researcher Introduction, Volume 71-9, Page 789, Sep. 2018, Paper

  
• 京都大学、DNAオリガミで薬剤送達へ 構造安定化の技術

  日本経済新聞, https://www.nikkei.com/article/DGXZQOUC16AD30W4A210C2000000/, Mar. 2024, Paper

  
• 「DNA折り紙」より頑強に

  科学新聞, 科学新聞第3949号8面（裏表紙）, Dec. 2023, Paper

  
• DNA折り紙 安定化に成功 結合の切れ目 効率的に連結

  京都大学新聞, "京都大学新聞第2709号 １面", Nov. 2023, Paper

  
• 「DNA折り紙」より頑強に、京大が新たな構造安定化法を開発

  MIT Technology Review Japan, https://www.technologyreview.jp/n/2023/11/07/321500/?fbclid=IwAR1VZowKLypLFkBOT8RjAJE1fsV6avZMps7MVMfbfN2bFAcZKz_evet0XUg, Nov. 2023, Internet

  

External funds: Kakenhi

• Retroviral integration into topologically-interlocked DNAs to probe the role of DNA structure and screen viral inhibitors

  Grant-in-Aid for Scientific Research (C)

  Basic Section 37010:Bio-related chemistry

  Kyoto University

  Rajendran A.

  From 01 Apr. 2021, To 31 Mar. 2024, Project Closed

  DNA origami;DNA nanotechnology;Structural biology;Nucleic acids chemistry;DNA-protein interaction;DNA origami stability;Topological DNA;DNA-protein interactions;Atomic force microscopy;Viral proteins;Topological structures;Minicircle DNA;Interlocked structures;DNA minicircles;HS-AFM;Viral inhibitor;Viral integrase;Drug screening

  https://kaken.nii.ac.jp/grant/KAKENHI-PROJECT-21K05274/
• Development of new method for screening anticancer drugs that target topoisomerases by using DNA origami

  Grant-in-Aid for Young Scientists (B)

  Kyoto University

  Rajendran Arivazhagan

  From 01 Apr. 2016, To 31 Mar. 2018, Project Closed

  DNA origami;Inhibitors;Topoisomerase;HS-AFM;Drug screening;Single-molecule analysis;Rotaxane;Catenane;DNA rotaxanes;DNA catenane;Topoisomerase inhibitors;high speed AFM;ナノバイオ;High-Speed AFM

  https://kaken.nii.ac.jp/grant/KAKENHI-PROJECT-16K17934/
• Creation of new genome science using chemical tools to precisely detect modification and damage of human genome

  Grant-in-Aid for Scientific Research (A)

  National Institute for Materials Science

  Makoto Komiyama

  From 01 Apr. 2015, To 31 Mar. 2018, Project Closed

  ゲノム;PNA;インベージョン;ゲノム断片分離;エピゲノム;DNA結合タンパク質;DNAメチル化;テロメア;DNA損傷

  https://kaken.nii.ac.jp/grant/KAKENHI-PROJECT-15H02189/
• Control and elucidation of gene expression at a molecular level

  Grant-in-Aid for Scientific Research (S)

  Kyoto University

  Hiroshi SUGIYAMA

  From 31 May 2012, To 31 Mar. 2017, Project Closed

  遺伝子発現制御;エピジェネティックス;細胞初期化;Py-Imポリアミド;DNAナノ構造体;遺伝子発現;初期化;エピジェネティクス

  https://kaken.nii.ac.jp/grant/KAKENHI-PROJECT-24225005/

Education

Teaching subject(s)

• From 01 Apr. 2025, To 31 Mar. 2026

  Chemistry of Sustainable Energy-E2

  N367, Fall, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2025, To 31 Mar. 2026

  Basic Physical Chemistry (quantum theory)-E2

  N366, Fall, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2025, To 31 Mar. 2026

  Basic Physical Chemistry (thermodynamics)-E2

  N365, Spring, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2025, To 31 Mar. 2026

  Essentials of Basic Physical Chemistry-E2

  N371, Spring, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2025, To 31 Mar. 2026

  From Carbon Neutral to Carbon Negative

  M634, Spring, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2025, To 31 Mar. 2026

  From Carbon Neutral to Carbon Negative

  3623, Spring, Graduate School of Energy Science, 2
• From 01 Apr. 2025, To 31 Mar. 2026

  Fundamental Energy Science

  3211, Spring, Graduate School of Energy Science, 2
• From 01 Apr. 2024, To 31 Mar. 2025

  Basic Physical Chemistry (quantum theory)-E2

  N366, Fall, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2024, To 31 Mar. 2025

  Basic Physical Chemistry (thermodynamics)-E2

  N365, Spring, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2024, To 31 Mar. 2025

  Chemistry of Sustainable Energy-E2

  N367, Fall, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2024, To 31 Mar. 2025

  Essentials of Basic Physical Chemistry-E2

  N371, Spring, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2024, To 31 Mar. 2025

  From Carbon Neutral to Carbon Negative

  3623, Spring, Graduate School of Energy Science, 2
• From 01 Apr. 2024, To 31 Mar. 2025

  Fundamental Energy Science

  3211, Spring, Graduate School of Energy Science, 2
• From 01 Apr. 2023, To 31 Mar. 2024

  Basic Physical Chemistry (quantum theory)-E2

  N366, Fall, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2023, To 31 Mar. 2024

  Basic Physical Chemistry (thermodynamics)-E2

  N365, Spring, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2023, To 31 Mar. 2024

  Essentials of Basic Physical Chemistry-E2

  N371, Spring, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2023, To 31 Mar. 2024

  Chemistry of Sustainable Energy-E2

  N367, Fall, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2023, To 31 Mar. 2024

  Carbon Neutrality

  3618, Spring, Graduate School of Energy Science, 2
• From 01 Apr. 2023, To 31 Mar. 2024

  Fundamental Energy Science

  3211, Spring, Graduate School of Energy Science, 2
• From 01 Apr. 2022, To 31 Mar. 2023

  Essentials of Basic Physical Chemistry-E2

  N371, Spring, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2022, To 31 Mar. 2023

  Basic Physical Chemistry (thermodynamics)-E2

  N365, Spring, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2022, To 31 Mar. 2023

  Carbon Neutrality

  3618, Spring, Graduate School of Energy Science, 2
• From 01 Apr. 2022, To 31 Mar. 2023

  Chemistry of Sustainable Energy-E2

  N367, Fall, Institute for Liberal Arts and Sciences, 2
• From 01 Apr. 2022, To 31 Mar. 2023

  Basic Physical Chemistry (quantum theory)-E2

  N366, Fall, Institute for Liberal Arts and Sciences, 2
• From Apr. 2015, To Mar. 2016

  Basic Physical Chemistry (quantum theory)

  Fall, 全学共通科目
• From Apr. 2015, To Mar. 2016

  Basic Physical Chemistry (thermodynamics)

  Spring, 全学共通科目
• From Apr. 2015, To Mar. 2016

  Chemistry of Sustainable Energy

  Fall, 全学共通科目
• From Apr. 2015, To Mar. 2016

  Essentials of Basic Physical Chemistry

  Spring, 全学共通科目
• From Apr. 2016, To Mar. 2017

  Basic Physical Chemistry (quantum theory)-E2

  Fall, 全学共通科目
• From Apr. 2016, To Mar. 2017

  Basic Physical Chemistry (thermodynamics)-E2

  Spring, 全学共通科目
• From Apr. 2016, To Mar. 2017

  Chemistry of Sustainable Energy-E2

  Fall, 全学共通科目
• From Apr. 2016, To Mar. 2017

  Essentials of Basic Physical Chemistry-E2

  Spring, 全学共通科目
• From Apr. 2017, To Mar. 2018

  Basic Physical Chemistry (quantum theory)-E2

  Fall, 全学共通科目
• From Apr. 2017, To Mar. 2018

  Basic Physical Chemistry (thermodynamics)-E2

  Spring, 全学共通科目
• From Apr. 2017, To Mar. 2018

  Chemistry of Sustainable Energy-E2

  Fall, 全学共通科目
• From Apr. 2017, To Mar. 2018

  Essentials of Basic Physical Chemistry-E2

  Spring, 全学共通科目
• From Apr. 2018, To Mar. 2019

  Basic Physical Chemistry (quantum theory)-E2

  Fall, 全学共通科目
• From Apr. 2018, To Mar. 2019

  Basic Physical Chemistry (thermodynamics)-E2

  Spring, 全学共通科目
• From Apr. 2018, To Mar. 2019

  Chemistry of Sustainable Energy-E2

  Fall, 全学共通科目
• From Apr. 2018, To Mar. 2019

  Essentials of Basic Physical Chemistry-E2

  Spring, 全学共通科目
• From Apr. 2019, To Mar. 2020

  Basic Physical Chemistry (quantum theory)-E2

  Fall, 全学共通科目
• From Apr. 2019, To Mar. 2020

  Basic Physical Chemistry (thermodynamics)-E2

  Spring, 全学共通科目
• From Apr. 2019, To Mar. 2020

  Chemistry of Sustainable Energy-E2

  Fall, 全学共通科目
• From Apr. 2019, To Mar. 2020

  Essentials of Basic Physical Chemistry-E2

  Spring, 全学共通科目
• From Apr. 2020, To Mar. 2021

  Basic Physical Chemistry (quantum theory)-E2

  Fall, 全学共通科目
• From Apr. 2020, To Mar. 2021

  Basic Physical Chemistry (thermodynamics)-E2

  Spring, 全学共通科目
• From Apr. 2020, To Mar. 2021

  Chemistry of Sustainable Energy-E2

  Fall, 全学共通科目
• From Apr. 2020, To Mar. 2021

  Essentials of Basic Physical Chemistry-E2

  Spring, 全学共通科目
• From Apr. 2021, To Mar. 2022

  Basic Physical Chemistry (quantum theory)-E2

  Fall, 全学共通科目
• From Apr. 2021, To Mar. 2022

  Basic Physical Chemistry (thermodynamics)-E2

  Spring, 全学共通科目
• From Apr. 2021, To Mar. 2022

  Chemistry of Sustainable Energy-E2

  Fall, 全学共通科目
• From Apr. 2021, To Mar. 2022

  Essentials of Basic Physical Chemistry-E2

  Spring, 全学共通科目

Administration

Faculty management (title, position)

• From 01 Jan. 2023, To 31 Dec. 2023

  エネルギー理工学研究所講演企画委員会委員
• From 01 Apr. 2023

  エネルギー理工学研究所研究支援部広報･資料室
• From 01 Apr. 2015

  エネルギー理工学研究所安全衛生委員会委員
• From 01 Apr. 2015

  エネルギー理工学研究所将来構想検討委員会委員
• From 01 Apr. 2020, To 31 Mar. 2023

  エネルギー理工学研究所研究支援部広報室

Academic, Social Contribution

Committee Memberships

• From Jan. 2017, To Present

  Member, Japan Society of Nucleic Acids Chemistry (JSNAC)
• From Jan. 2010, To Present

  Member, The Chemical Society of Japan (CSJ)
• From Jan. 2010, To Present

  Member, The Biofunction-Related Chemistry Subcommittee