Research Areas

Spectroscopy is the "eyes" of modern science, and hence it plays essential roles in a variety of research fields covering physics, chemistry and biology. We develop and utilize the most advanced spectroscopy for molecular science of complex systems in the condensed-phase. To elucidate a variety of complex phenomena occurring in the condensed phase, we need to clarify the electronic and vibrational states of molecules, the response of surroundings, and the fluctuation and dissipation of energy behind. Based on this view, we carry out fundamental research using the most advanced linear/nonlinear spectroscopic methods with most suitable time- and space-resolution for the problems to be studied. Currently, we are carrying out the following projects:
1. Elucidation and control of ultrafast phenomena using advanced time-resolved spectroscopy,
2. Study of soft interfaces using new nonlinear spectroscopy,
3. Study of the dynamics of complex systems in the femtosecond - millisecond time region.
Targets of the projects 1, 2, 3 are (1) fundamental molecules in solution, (2) molecules at the air/liquid,liquid/liquid, liquid/solid and biological interfaces, and (3)biological macromolecules, respectively.

Research Subject

1. Elucidation and control of ultrafast phenomena using advanced time-resolved spectroscopy
2. Study of soft interfaces using new nonlinear spectroscopy
3. Study of the dynamics of complex systems in the femtosecond - millisecond time region.

Related links

1. RIKEN Advanced Science Institute Website_Laboratories Page
2. Individual Website Laboratory Page

Press release

September 28, 2011

When water and air meet
New study sheds light on the mysterious structure of the world's most common liquid interface

April 25,2011

Image taken at picosecond speed reveals deformations in optical molecular switch

July 29, 2009

New laser spectroscopy method developed for detection of 'color' on liquid interface

November 14, 2008

A new methdology for the detection of the change in molecular structure in a time of 0.1 ps (pico second), providing powerful tools 'to elucidate the transition state of chemical reactions

August 31, 2007

The Molecular Spectroscopy Laboratory of DRI has developed a "fourth-order nonlinear Raman spectroscopy," a new laser spectroscopy that enables the depiction of a specific boundary surface buried between dense materials.

March 20, 2007

Molecular Spectroscopy Laboratory provided key evidence that supported the concerted mechanism, and not the step-wise, in the mechanistic controversy for the double proton transfer reaction.

RIKEN RESEARCH

January 27, 2012

Resolving controversy at the water's edge
High-level spectroscopy and computer simulations of specially diluted liquids reveal the long-debated structure of air-water interfaces

August 05, 2011

Detecting an unexpected delay at ultrafast speed
High-speed laser measurements reveal new insights into rearrangements of light-driven chemical structures with implications for solar-energy conversion and opto-electric devices

September 24,2010

Heads up, tails down
Advanced laser spectroscopy exposes the unique organization of water molecules under model membrane surfaces

October 16, 2009

Interfaces: Different for every molecule
A novel spectroscopic technique reveals a new fundamental property of air/water interfaces

August 14, 2009

A tight fit helps energy transmit
Mechanically trapped molecules throw light on energy transfer within artificial photosynthetic systems

March 19, 2009

Seeing molecules move in real-time
Ultrafast lasers instantaneously track a molecular twist in progress

November 22, 2007

Hidden surface chemistry revealed
A new technique that works at normal pressures shows molecular interactions at liquid interfaces