2005年
11) "An Acidic Layered Clay Is Combined with A Basic Layered Clay for One-Pot Sequential Reactions", J. Am. Chem. Soc., 127(27), 9674-9675.
10) "Heterotrimetallic RuMnMn Species on a Hydrotalcite Surface as Highly Efficient Heterogeneous Catalysts for Liquid-Phase Oxidation of Alcohols Using Molecular Oxygen", Angew. Chem. Int. Ed., 44(22) 3423-3426.
9) "Monomeric Metal Aqua Complexes in Interlayer Space of Montmorillonites as a Strong Lewis Acid Catalyst for Heterogeneous Carbon-Carbon Bond Forming Reactions", Chem. Eur. J., 11(1) 288-297.
8) "Catalytic Investigations of Carbon-carbon Bond-Forming Reactions Catalyzed by a Hydroxyapatite-Bound Palladium Complex", New J. Chem., 29(9), 1174-1181 (2005).
7) "A Single-Site Hydroxyapatite-Bound Zinc Catalyst for Highly Efficient Chemical Fixation of Carbon Dioxide with Epoxides", Chem. Commun., 3331-3333 (2005)
6) "One-Pot Synthesis of α-Alkylated Nitriles with Carbonyl Compounds through Tandem Aldol Reaction / Hydrogenation Using a Hydrotalcite-Supported Palladium Nanoparticle as a Multifunctional Heterogeneous Catalyst", Tetrahedron Lett., 46, 5507-5510 (2005)
5) "Michael Reaction of 1,3-Dicarbonyls with Enones Catalyzed by a Hydroxyapatite-Bound La Complex", Tetrahedron Lett., 46, 4283-4286 (2005)
4) "Liquid-Phase Epoxidation of Alkenes Using Molecular Oxygen Catalyzed by Vanadium-Exchanged Montmorillonite", Chem. Lett., 34(12), 1626-1627 (2005)
3) "Palladium-Platinum Bimetallic Nanoparticle Catalysts Using Dendron Assembly for Selective Hydrogenation of Dienes and Their Application to Thermomorphic System", Chem. Lett. 34(2) 272-273.
2) "Dendritic Nanoreactor Encapsulating Rh Complex Catalyst for Hydroformylation", Chem. Lett. 34(3) 286-287.
1) "Quaternary Ammonium Dendrimers as Lewis Base Catalysts for Mukaiyama-Aldol Reaction", Chem. Lett.34(3) 420-421.

総説
6) “塩基性ハイドロタルサイト表面固定化Ru触媒を用いる有機合成反応”,ファインケミカル, 34, 26-33 (2005)
5) “新世代ハイドロキシアパタイト固定化金属触媒の開発”, ケミカルエンジニアリング, 50, 643-647 (2005)
4) “不均一系金属触媒を用いた自然共生型炭素―炭素結合形成反応”, ファルマシア, 41, 645-648 (2005)
3) “高機能不均一触媒を用いるone-pot反応系の開発 ―効率的化学プロセスの構築を目指して―”, 分離技術, 35, 401-406 (2005)
2) “脱ハロゲン化触媒技術の現状”, 化学と工業, 58, 583-585 (日本化学会, 2005)
1) “自然共生型有機合成反応を指向した金属固定化層状粘土触媒の開発”, 機能材料、2005, 25(2), 33-41.

2004年
1) "Hydroxyapatite-Supported Palladium nanoclusters: A Highly Active Heterogeneous Catalyst for Selective Oxidation of Alcohols Using Moleculare Oxygen", Journal of the American Chemical Society, 126(34) 10657-10666.
2) "Highly Efficient Dehalogenation Using Hydroxyapatite-Supported Palladium Nanocluster Catalyst with Molecular Hydrogen", Green Chemistry, 6(10) 507-509.
3) “A Ruthenium-Grafted Hydrotalcite as a Multifunctional Catalyst for Direct a-Alkylation of Nitriles with Primary Alcohols”, Journal of the American Chemical Society 126(18) 5662-5663.
4) “Supramolecular Catalyst by Encapsulating Palladium Complex within Dendrimer”, Journal of the American Chemical Society 126(6): 1604-1605.
5) "Multifunctional Catalysis of a Ruthenium-Grafted Hydrotalcite: One-pot Synthesis of Quinolines from 2-Aminobenzyl Alcohol and Various Carbonyl Compounds via Aerobic Oxidation and Aldol Reaction" Tetrahedron Lett. 45, 6029-6032.
6) "Highly active trimetallic Ru/CeO2/CoO(OH) catalyst for oxidation of alcohols in the presence of molecular oxygen." Journal of Molecular Catalysis A: Chemical 212: 161-170.

総説

7) "Design of hydroxyapatite-bound transition metal catalysts for environmentally-benign organic syntheses, Catalysis Surveys from Asia 8(4) 231-239 (2004).
6) "Dendritic Nanocatalysts", In Dekker Encyclopedia of Nanoscience and Nanotechnology, James A. Schwarz, Cristian. I. Contescu, and Karol Putyera, eds. New York: Marcel Dekker, Inc., 2004; pp 903-912.
5) "Palladium Nanoclusters: Preparation and Synthesis", In Dekker Encyclopedia of Nanoscience and Nanotechnology, James A. Schwarz, Cristian. I. Contescu, and Karol Putyera, eds. New York: Marcel Dekker, Inc., 2004; pp 2803-2812.
4) "無機結晶化合物を利用した新世代型固体酸触媒の開発と自然共生型炭素-炭素結合形成反応への応用-",ファインケミカル, 2004, 33, 18-27.
3) "高機能固体触媒の設計およびその触媒作用", 表面、2004, 42(11), p.321-328.
2) "自然共生型有機合成反応を指向した不均一系金属触媒の開発", 触媒技術の動向と展望、2004, p.42, 触媒学会編
1) “分子状酸素を酸化剤とするアルコール酸化反応に向けた固定化金属触媒の設計”, 触媒、2004, 46, 19-24..

2003年
1) "A Novel Montmorillonite-Enwrapped Scandium as a Heterogeneous Catalyst for Michael Reaction", Journal of the American Chemical Society 125(35): 10486-10487.
2) "Hydroxyapatite-Bound Cationic Ruthenium Complexes as Novel Heterogeneous Lewis Acid Catalysts for Diels-Alder and Aldol Reactions", Journal of the American Chemical Society 125(38): 11460 - 11461.
3) "Highly efficient esterification of carboxylic acids with alcohols by montmorillonite-enwrapped titanium as a heterogeneous acid catalyst", Tetrahedron Letters 44(51): 9205-9208.
4) "Highly efficient dehydrogenation of indolines to indoles using hydroxyapatite-bound Pd catalyst", Tetrahedron Letters 44(33): 6207-6210.5) "Efficient deprotection of N-benzyloxycarbonyl group from amino acids by hydroxyapatite-bound Pd catalyst in the presence of molecular hydrogen", Tetrahedron Letters 44(27): 4981-4984.
6) "Self-Assembled dendrimer-bound Pd(II) complexes via acid-base interactions and their catalysis for allylic amination", Chemistry Letters 32(8), 692-693.
7) "Highly efficient deprotection of acetals by titanium cation-exchanged montmorillonite as a strong solid acid catalyst", Chemistry Letters 32(7): 648-649.
8) "Highly selective oxidation of allylic alcohols catalyzed by monodisperse 8-shell Pd nanoclusters in the presence of molecular oxygen", New Journal of Chemistry 27(2): 324-328.
9) "Nanoscale palladium cluster immobilized on a TiO2 surface as an efficient catalyst for liquid-phase Wacker oxidation of higher terminal olefins", Chemistry Letters 32(2): 180-181.
10) "Clean synthesis of 3,3',5,5'-tetra-tert-butyl-4,4'-diphenoquinone from the oxidative coupling of 2,6-di-tert-butylphenol catalyzed by alkali-promoted Cu-Mg-Al hydrotalcites in the presence of molecular oxygen", Chemistry Letters 32(1): 58-59.

総説
1)  “無機結晶の特性を活かした環境調和型金属触媒の開発”,GSCN News Letter 2003, No.7, 3; Green & Sustainable Chemistry Network.
2) “不均一系金属触媒を用いた自然共生型炭素―炭素結合形成反応”,有機合成化学協会誌 2003, 61, 436-444. 
3) “ヒドロキシアパタイト固定化ルテニウム触媒による環境調和型酸化反応”,和光純薬時報 2003, 72, 8-10. 
4) “無機結晶の特性を活かした固定化金属触媒の開発―環境調和型有機合成反応への展開―”,ペトロテック 2003, 26, 640-644.

2002年
1) "Controlled Synthesis of Hydroxyapatite-Supported Palladium Complexes as Highly Efficient Heterogeneous Catalysts", Journal of the American Chemical Society, 124, 11572.
2) "Dendritic Nanoreactors Encapsulating Pd Particles for Substrate-Specific Hydrogenation of Olefins", Nano Letters, 2, 999-1002.
3) "Preparation of Novel Cationic Palladium Nanocluster with Mixed-Valence States on the Surface and Its Catalysis for Oxidative Acetoxylation of Toluene Using Molecular Oxygen", Langmuir, 18, 1849-1855.
4) "Creation of a Chain-like Cationic Iron Species in Montmorillonite as a Highly Active Heterogeneous Catalyst for Alkane Oxygenations Using Hydrogen Peroxide", Chemical Communications, 690-692.
5) "Novel catalysis of dendrimer-bound Pd(0) complexes: sterically steered allylic amination and the first application for thermomorphic system", Chemical Communications, 52-53.
6) "Efficient heterogeneous oxidation of organosilanes to silanols catalysed by a hydroxyapatite-bound Ru complex in the presence of water and molecular oxygen", New Journal of Chemistry, 26, 1536-1538. 
7) "Highly efficient oxidation of alcohols to carbonyl compounds in the presence of molecular oxygen using a novel heterogeneous Ruthenium catalyst", Tetrahedron Letters, 43, 7179-7183.
8) "Highly efficient epoxidation of alpha,beta-unsaturated ketones by hydrogen peroxide with a base hydrotalcite catalyst prepared from metal oxides", Tetrahedron Letters, 43, 6229-6232. 
9) "Environmentally friendly alcohol oxidation using heterogeneous catalyst in the presence of air at room temperature", Catalysis Communications, 3, 511-517.

総説
1)“グリーン・サステイナブルケミストリーを指向した触媒開発”,ケミカル・エンジニアリング,47, 676-682, 化学工業社
2)“環境調和型金属触媒の開発~グリーン・サステイナブルケミストリーを指向したモノづくり~”,現代化学, 10月号, No.379, 14-20.
3)“固定化金属錯体触媒の開発と環境調和型有機合成反応への応用”,ファインケミカル, 10月15日号, Vol.31, No.18, 13-30.
4) “無機結晶の特性を活かした環境調和型金属触媒の開発”, 化学と工業, 11月号, Vol.55, 1233-1236, 日本化学会.