APS March Meeting 2010
Volume 55, Number 2
Monday–Friday, March 15–19, 2010;
Portland, Oregon
Session J23: Focus Session: Plyler Prize Session and New Trends in Spectroscopy I
11:15 AM–1:51 PM,
Tuesday, March 16, 2010
Room: C125-C126
Sponsoring
Unit:
DCP
Chair: Brooks Pate, University of Virginia
Abstract ID: BAPS.2010.MAR.J23.6
Abstract: J23.00006 : Multi-frequency THz Heterodyne Spectroscopy using Electro-Optic Sampling
12:39 PM–1:15 PM
Preview Abstract
Abstract
Author:
David Jones
(UBC)
Multi-frequency heterodyne spectroscopy, developed by two groups
(Schiller as well as van der Weide, Keilmann and co-workers) uses
one optical femtosecond frequency comb (FFC) to probe a sample. A
second FFC with a slightly detuned spacing is used as a multi
frequency local oscillator to uniquely map the broadband optical
spectroscopic information to the RF domain where it can be easily
analyzed. Researchers at NIST (Coddington et al) have realized
the full potential of this technique by tightly locking the
detuned combs together using optical locking techniques.
It is of considerable interest to extend such capabilities to
access the so-called molecular vibrational ``fingerprint'' range
of approximately $10$ to $100$ THz ($300$ to $3000$ cm$^{-1}$). A
transfer of the direct heterodyne detection approach used in the
optical regime down to this frequency range is fraught with
difficulties including significantly lower power of the probe THz
frequency comb. In addition, a low noise detector with a
relatively fast RF response ($>100$ MHz at a minimum) is required.
An alternative, indirect detection technique for detecting THz
signals is electro-optic sampling (EOS). It has employed for time
domain THz spectroscopic applications for a number of years with
a demonstrated spectral detection ranging from 0.5 THz range to
over 100 THz.
Through careful analysis of the EOS we show how electro-optic
sampling of THz frequency comb by a detuned optical FFC followed
by direct optical detection of the optical sampling beam enables
conversion of the THz spectroscopic data directly to the RF
domain. In particular, we show there is a one-to-one
correspondence between a detected RF heterodyne beat and THz comb
element. Numerical simulations predict excellent signal to noise
ratio of the RF beats (20 dB) with modest acquisition times (10
$\mu$s). We will also summarize our progress toward experimental
realization of such a system.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2010.MAR.J23.6