SFG Spectrometer

Sum Frequency Generation (SFG) Vibrational Spectrometer

 /  Characterisation of vibrational bonds of molecules at surfaces or interfaces.

 /  Intrinsically surface specific

 /  High spectral resolution.

 /  Wide range of accessible (molecular) vibrations: 625-4000 cm⁻¹

 /  SFG Microscope

 /  Characterisation of vibrational bonds of molecules at surfaces or interfaces.

 /  Intrinsically surface specific

 /  High spectral resolution.

 /  Wide range of accessible (molecular) vibrations: 625-4000 cm⁻¹

 /  SFG Microscope

Sum Frequency Generation (SFG) Vibrational Spectroscopy


  • Intrinsically surface specific
  • Selective to adsorbed species
  • Sensitive to submonolayer of molecules
  • Applicable to all interfaces accessible to light
  • Nondestructive
  • Capable of high spectral and spatial resolution


  • Investigation of surfaces and interfaces of solids, liquids, polymers, biological membranes and other systems
  • Studies of surface structure, chemical composition and molecular orientation
  • Remote sensing in hostile environment
  • Investigation of surface reactions under real atmosphere, catalysis, surface dynamics
  • Studies of epitaxial growth, electrochemistry, material and environmental problems
Principle of SFG spectroscopy

Principle of SFG spectroscopy


Sum Frequency Generation Vibrational Spectroscopy (SFG-VS) is powerful and versatile method for in-situ investigation of surfaces and interfaces. In SFG-VS experiment a pulsed tunable infrared IR (ωIR) laser beam is mixed with a visible VIS (ωVIS) beam to produce an output at the sum frequency (ωSFG = ωIR + ωVIS). SFG is second order nonlinear process, which is allowed only in media without inversion symmetry. At surfaces or interfaces inversion symmetry is necessarily broken, that makes SFG highly surface specific. As the IR wavelength is scanned, active vibrational modes of molecules at the interface give a resonant contribution to SF signal. The resonant enhancement provides spectral information on surface characteristic vibrational transitions.


Spectra examples. On the left - SFG spectra of monoolein surface, 1 cm-1 scan step, 200 acquisitions per step. On the right. Water-air interface spectra, 200 acquisitions per step (Courtesy of University of Michigan).

Spectra examples. On the left – SFG spectra of monoolein surface, 1 cm-1 scan step, 200 acquisitions per step. On the right. Water-air interface spectra, 200 acquisitions per step (Courtesy of University of Michigan).

Design of the SFG Spectrometer

Sum frequency generation (SFG) spectrometer is based on picosecond pump laser and optical parametric generator (OPG) with difference frequency generation (DFG) extension. Solid state mode-locked Nd:YAG laser featuring high pulse duration and energy stability is used in the system. Fundamental laser radiation splits into several channels in multichannel beams delivery unit. Two of these beams are used for pumping OPG and DFG. Small part of laser output beam, usually with doubled frequency (532 nm), is directed to VIS channel of SFG spectrometer. IR channel of spectrometer is pumped by DFG output beam. All system components are designed to operate in tandem. The sizes of individual compartments, positions of apertures and beams heights are fitted. As a result SFG spectrometer takes less space in laboratory. Standard versions usually fit on 1000×2400 mm optical table. No laser beams are passing across optical table. For example beam dedicated for VIS channel passes through OPG compartment only to minimize the risk of accident with dangerous high intensity laser radiation. It makes Ekspla spectrometer substantially safer comparing to home-made SFG-VS setups. Also optical parameters, like beam diameter, pulse energy, delays between channels are perfectly matched. We designed our spectrometer thinking about user friendly operation. Many components of the system are automated and controlled from PC. The opto-mechanical holders that need to be tuned often during routine operation are located around sample area and can be easily accessed without walking around the optical table. According to user needs different level of automation can be proposed, starting from most simple mechanical setup to most advanced fully motorized version. Detection system consists of monochromator with high stray light rejection and gated PMT based SF signal detector. The feature of such design is ability to perform measurements in room lighting. Second parallel detection channel is available as an option. All system components are controlled from single dedicated software. Program contains  many useful instruments for automatic SFG spectra recording, dynamics monitoring, X-Y sample mapping, azimuthal scan and system parameters monitoring. Ekspla offers three common SFG spectrometer models for classical picosecond scanning SFG vibrational spectroscopy and several specialized models for most demanding users. Basic models are: SFG Classic, SFG Advanced and Double resonance SFG. They differ by IR beam tuning ranges and available VIS beam wavelengths (please see specifications page). Other models: Phase-sensitive SFG and SFG microscope provides unique features, which are described in the “Modifications and Options” section.

Schematic layout of SFG Classic spectrometer.

Schematic layout of SFG Classic spectrometer.


System Components

  • Picosecond mode-locked Nd:YAG laser
  • Multichannel beam delivery unit
  • Picosecond optical parametric generator
  • Spectroscopy module
  • Monochromator
  • PMT based signal detectors
  • Data acquisition system
  • Dedicated LabView® software package for system control

Picosecond mode-locked Nd:YAG laser


PL2230 series Diode Pumped High Energy Picosecond Nd:YAG Lasers

PL2230 series Diode Pumped High Energy Picosecond Nd:YAG Lasers


Model PL2231 is fully diode pumped, which means that master oscillator and all following amplification stages are diode pumped. It features great long term parameters stability and minimal maintenance requirements. This model provides up to 40 mJ per pulse output energy, which in most cases is enough for pumping OPG and VIS channel of SFG spectrometer. Model PL2251, which provides up to 100 mJ per pulse output energy has similar internal structure to previously described PL2231, except power amplifier stage, which is flash lamp pumped in this case. This model usually is used for pumping of two independent OPG’s. Such configuration is used in double resonance SFG version. It can be also considered in case, if SFG spectrometer must be optically synchronized with other experiment, e.g.: pump-probe and SFG simultaneous measurements.


Multichannel beams delivery unit


Multichannel beams delivery unit

Multichannel beams delivery unit


Fundamental laser radiation needs to be split into several channels and converted to different wavelenghts. Tunable IR radiation is generated in picosecond optical parametric generator (OPG). Large portion of laser output is converted into second or third harmonics and used for OPG pumping. Residual beam is spatially  filtered, delayed and directed into SFG spectrometer as VIS channel. Usually it is converted into second harmonic (532 nm), but in some cases can be used also at fundamental wavelength (1064 nm) or tunable in visible range, when second OPG is used.

Multichannel beams delivery unit SFGHX00 series provides all these features. Additionally it contains automatized VIS channel input energy monitoring and control.

The VIS channel wavelength (if double wavelenght option is included) is changed manually. Setup also includes all needed separators and filters to block residual radiation and prevent it from reaching a sample.


An example of Multichannel beams delivery unit used for Double resonance SFG spectrometer.

An example of Multichannel beams delivery unit used for Double resonance SFG spectrometer.



Picosecond optical parametric generator

PG501 series picosecond optical parametric generator (OPG) feature high pulse energy and narrow linewidth. It is used for generation of tunable wavelength in broad spectral range. In SFG spectrometer it provides middle infrared radiation for IR channel.

Optically this unit can be divided into several functional modules:

  • traveling wave optical parametric generator (TWOP G);
  • diffraction grating based linewidth narrowing system (LNS);
  • optical parametric amplifier (OPA);
  • difference frequency generator (DFG).

The purpose of the TWOP G module is to generate parametric superfluorescence (PS). Spectral properties of the PS are determined by the properties of a nonlinear crystal and usually vary with the generated wavelength. In order to produce narrowband radiation, the output from OPG is narrowed by LNS down to 6 cm-1 and then used to seed OPA.

Output wavelength tuning is achieved by changing the angle of the nonlinear crystal(s) and grating. To ensure exceptional wavelength reproducibility, computerized control unit driven precise stepper motors rotate the nonlinear crystals and diffraction grating. Nonlinear crystal temperature stabilization ensures long term stability of the output radiation wavelength.

In order to protect nonlinear crystals from damage, the pump pulse energy is monitored by built-in photodetectors, and the control unit produces an alert signal when pump pulse energy exceeds the preset value.

DFG stage extends tuning range to mid IR, which corresponds to molecular vibrational fingerprints. Depending of OPG model, DFG output can cover spectral range 2.3 – 10 μm or 2.3 – 16 μm. All residual wavelengths are carefully filtered preventing residual radiation from reaching a sample. Visible laser pointer is installed inside each unit and aligned in-line with IR beam. It helps to manage invisible mid IR radiation and direct it through multiple optical elements into a sample.

Some SFG-VS studies require better than 6 cm-1 spectral resolution. In such cases Ekspla offers unique design PG511 series OPG. In this system seed is generated in synchronously pumped optical parametric oscillator (SPOPO), which is temporally synchronized with laser regenerative amplifier. In this configuration radiation spectral width is narrowed down to 2 cm-1 in mid IR range.


Spectroscopy module

SFG spectroscopy module is designed with idea to make all adjustable components accessible within outspread hands. Most of them are located around sample area, when other components, which shouldn’t be touched often, are hidden or located in more distant parts of the spectrometer. Some nodes, like IR polarization rotation system, which are rather difficult to align for unexperienced user, are motorized. Due to vertical beams plane geometry spectroscopy module is very convenient for practically all interfaces accessible by light.

The size of spectroscopy module is adjusted to particular geometry of experiment and other options, which require some extra space. The most common experiment geometry is with co-propagating, non-collinear VIS and IR beams accessing the sample from top side. SFG beam is being caught reflected from the sample surface. The incidence angle of VIS and IR beams is around 55 – 60 deg., which guarantee best SFG efficiency. Such geometry is optimal for most samples, especially liquids and monolayers deposited on nontransparent substrates.

However, in some experiments one layer of the sample can be transparent only for VIS beam, but not for IR beam and vice versa. In such case experimental setup requires different geometries. This problem can be solved, if we can access interface from different sides, for example directing VIS beam from the top and IR beam from the bottom. Ekspla offers several standard geometries: top side, bottom side, top-bottom side and total internal reflection. All of them can be implemented in single spectroscopy unit and easy interchangeable. The special design of SFG spectrometer provides possibility to change angles of interaction. This feature together with different polarization combinations helps better understand molecular dipoles orientation. In our spectrometer we use large aperture parabolic mirror. The sample is places in focal point of parabolic mirror. Such solution makes optical system extremely simple in operation, because it guarantee the same beams position on the sample surface and perfect overlap, when incidence angle is changed.Sample surface and beams overlap can be monitored using camera installed above sample area. This utility is integrated into every SFG spectrometer. On a special request sample visualization system can be combined with motorized beams adjustment. This allows to align SFG spectrometer from PC, even being physically far from it. It essentially solves safety issues and opens new possibilities for multiple long time experiments without accessing spectroscopy box.

SFG Spectrometer Modifications and Options


  • Double resonance SFG spectrometer – allows investigation of vibrational mode coupling to electron states at a surface
  • Phase sensitive SFG spectrometer – allows measurement of the complex spectra of surface nonlinear response coefficients
  • SFG microscope – provides spectral and spatial surface information with micrometers resolution


  • Single or double wavelength VIS beam: 532 nm and/or 1064 nm
  • One or two detection channels: main signal and reference
  • Second harmonic generation surface spectroscopy option
  • High resolution option – down to 2 cm-1
  • Motorized VIS and IR beams alignment system


Double resonance model

Both IR and VIS wavelengths are tunable in Double resonance SFG spectrometer model. This twodimensional spectroscopy is more selective than single resonant SFG and applicable even to media with strong fluorescence. Double resonant SFG allows investigation of vibrational mode coupling to electron states at a surface.

In Double resonance SFG spectrometer model second OPG is used to generate tunable VIS beam in UV and visible range.


SFG microscope

SFG-VS spectroscopy combined with micrometers spatial resolution provides unique ability to investigate spatial and chemical variations across the surface as a function of time. An example of such application is chemical imaging of corrosion. SFG microscopy reveals presence of highly-coordinated complexes of molecules at particular stage of this process.

SFG spectrometer offered by Ekspla uses far-field image formation technique. Illuminated area on the sample surface is substantially bigger than in regular SFG spectrometer. Using blazed grating and unique design optical system, image of surface plane is translated to matrix of ICCD camera. This way we can record distribution of SF signal at particular wavelength. For complete spectral and spatial information it is necessary to record multiple surface pictures at different wavelength. Integrated software package provides ability to visualize measured data making various cross sections: position-, wavelength- or time-dependent.


Phase-sensitive SFG spectrometer

In conventional SFG-VS intensity of SF signal is measured. It is proportional to the square of second order nonlinear susceptibility ISF ~ | χ(2) |2. However, χ(2) is complex, and for complete information, we need to know both the amplitude and the phase. This will allow us to determine the absolute direction in which the bonds are pointing and characterize their tilt angle with respect to the surface. Measurement of the phase of an optical wave requires an interference scheme. Mixing the wave of interest with a reference wave of known phase generates an interference pattern, from which the phase of the wave can be deduced.

In practice Phase-sensitive SFG experimental setup includes two samples generating SF signal simultaneously. One sample (usually called local oscillator) has well known and flat spectral response. Second one is investigated sample. The excitation beams are directed to first sample, where SFG beam is generated. Later all three beams are retranslated to the second sample, where another SFG beam is generated. Due to electromagnetic waves coherence both SFG beam are interfering. Setup contains the phase modular located on the SFG beam path between samples. We are able to change the phase of SFG beam by rotating it. This way we are recording two-dimensional interfererogram with wavelength and phase shift on x and y axis. Using fitting algorithms we are able to calculate the amplitude and phase of SF signal.

Optional Accessories

  • Six axis sample holder
  • Sealed temperature controlled sample chamber
  • Langmuir trough


VersionSFG Classic SFG Advanced SFG Double resonance
System (General)
Spectral range1000- 4300 cm-1625- 4300 cm-11000- 4300 cm-1
Spectral resolution <6 cm-1(optional <2 cm-1) <6 cm-1(optional <2 cm-1)<10 cm-1
Spectra acquisition methodScanning
Sample illumination geometryTop side, reflection (optional: bottom side, top-bottom side, total internal reflection)
Incidence beams geometryCo-propagating, non-colinear (optional: colinear)
Incidence anglesFixed, VIS ~60 deg, IR ~55 deg (optional: tunable)
VIS beam wavelength532 nm (optional: 1064 nm)532 nm (optional: 1064 nm)Tunable 420 – 680 nm (optional: 210 – 680 nm)
Polarization (VIS, IR, SFG)Linear, selectable “s” or “p”, purity > 1:100
Beam spot on the sampleSelectable, ~150 – 600 µm
SensitivityAir-water spectra
Pump lasers
Pulse energy40 mJ80 mJ (70 mJ at 20 Hz)
Pulse energy stability <0.5 % <0.8 %
Pulse duration28±3 ps30±3 ps
Pulse duration stability±1.0 ps
Pulse repetition rate50 Hz10 or 20 Hz
Optical parametric generators
IR source with standard linewidth (<6 cm-1)PG501-DFG1PPG501-DFG2PG501-DFG1P
IR source with narrow linewidth (<2 cm-1)PG551-DFG--
UV-VIS source for Double resonance SFG--PG401 (optional: PG401-SH)
For standard specifications please check the brochure of particular model
TypeCzerny-Turner with single grating turret (optional: four grating turret)
Focal length200 mm2x350 mm
Slits0-2.0 mm, manual
Stray light rejection10-510-510-10
Physical dimensions (footprint)
Standard2400 x 1000 mm3600 x 1500 mm
Extended (with special options or large accessories)2700 x 1200 mm3600 x 1500 mm

Due to continuous product improvements, specifications are subject to changes without advance notice.

Drawings & Images

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