research
 
It is highly desirable (if we can) to jump onto the catalyst surface and move with the atoms and molecules to find out what exactly is going on at the molecular level. Since this is not possible, we require an understanding of the fundamentals that control the catalytic reactions and the related surface chemical events through several experiments by suitable means. Traditional catalyst development was based on try and error approach and even after hitting a good catalyst, generally, there was no looking back on why a particular catalyst is active/selective and what fundamental properties contribute to that. Partly it is due to the complex catalytic materials involved as well as complex reactions. The goal of research in our laboratory is to understand the fundamentals of surface catalytic reactions on the real-world complex catalytic materials at a molecular level, and to suggest the ways to control the surface catalytic reactions based on the molecular level understanding. The molecular level controlling of the surface reactions would guide the development of highly active and/or selective catalysts, which might help to solve the critical issues of highly selective chemical processes in different catalytic reactions. To achieve the goal, we have been using the sophisticated tools such as Photoemission Spectroscopy, Molecular Beam Instrument, In Situ IR spectroscopy etc. along with micro and nano-materials into surface chemistry and catalysis.
 
+ Molecular Beam Kinetics

J. Physical Chemistry B, (2005) Vol.109, 13272-82.

J. Physical Chemistry B (2005) Vol.109, 13283-90.

Catalysis Letters, Vol.119, 50-58 (2007).

Chemistry - An Asian Journal Vol. 4, 74-80 (2009)

J. Physical Chemistry C Vol. 113, 7385-97, (2009).

J. Physical Chemistry C Vol. 113, 9814-19 (2009).

Applied Surface Science Vol. 256, 443-448 (2009).

Journal of Physical Chemistry C Volume: 115 Issue: 43 Pages: 21299-21310 (2011).

Journal of Physical Chemistry C Volume: 115 Issue: 31 Pages: 15487-15495(2011).

+ Band-Gap Engineering of semiconductor at Molecular level

Chemistry of Materials Vol. 21, 351-359 (2009).

Chemistry of Materials Vol. 21, 2973-79 (2009).

Chemistry of Materials Vol. 22, 565-578 (2010).

Transactions of the Materials Research Society of Japan Vol. 38, 145-158 (2013)

+ Titania based new materials and applications

Journal of Materials Chemistry Volume: 21 Issue: 8 Pages: 2639-2647 (2011).

Green Chemistry Volume: 14 Issue: 2 Pages: 461-471(2012)

Journal of Physical Chemistry C,Volume 116, Issue 3, Pages 2581-2587.

Applied Catalysis A: General Vol. 452 (2013) 132– 138

ChemCatChem Vol. 6, 522-530 (2014)

+ Heterogeneous Ziegler-Natta Catalysis

J. Physical Chemistry C(Letter), Vol. 113,8556-59 (2009).

J. Physical Chemistry C Vol. 115, 1952-60 (2011).

Dalton Transactions Volume: 40 Issue: 41 Pages: 10936-10944 (2011)

Dalton Transactions Volume: 41 Issue: 37 Pages: 11311-11318 Published: 2012

Journal of Physical Chemistry C, Volume116, Issue 45, Pages 24115-24122.

ACS Catalysis Vol. 3, 303-311 (2013)

Appl. Catal. A Vol. 469, 267-274 (2014)

J. Phys. Chem. A Vol. 118, 2014, 1213-1219

+ Ambient Pressure Photoelectron Spectroscopy(APPES)

Journal of Physical Chemistry C, Volume: 117 Issue: 9 Pages: 4717-4726(2013)

ChemCatChem, Vol. 6, 531-537 (2014)

Analytical Chemistry Accepted (2014)(letter)

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