QuantaMaster™ 8000 Series

Two years after the acquisition of PTI, HORIBA is proud to introduce the new PTI QuantaMaster™ 8000 series of fluorometers. The new PTI QuantaMaster 8000 series modular research fluorometers from HORIBA Scientific offer the world’s highest guaranteed sensitivity specification, plus many unique benefits. Only the HORIBA Fluorolog 3, also from HORIBA Scientific, matches the sensitivity of the new QuantaMaster 8000 series.” 

  •     Highest guaranteed sensitivity specification at 30,000:1 Water Raman RMS
  •     World class software for all steady state and lifetimes needs
  •     Extended wavelength range with triple grating monochromators
  •     Ultimate flexibility with up to four light sources and six detectors that can be selected
  •     Fully automated system
  •     Best in class stray light rejection with large single or double additive, coma corrected, monochromators
  •     World class TCSPC lifetime enhancements
  •     NIR steady state and phosphorescence lifetime detection to 5,500 nm

History of HORIBA Fluorescence

Six companies in One

Fluorescence tree image

The HORIBA Fluorescence group offers more systems to choose from than any other company. We also have the cumulative experience, and history of innovation, that comes from 2,500 employee years in fluorescence, and counting. This is why we can confidently say that,

“You’re going to find what you need, and love what you get, from HORIBA Fluorescence”

Manufactured by HORIBA Scientific


PTI QuantaMaster 8000

PTI QuantaMaster 300 Series

PTI QuantaMaster 800

Signal to Noise Ratio

30,000:1 or better

300: 1500:1 or better
300 Plus: 3000:1 or better

6000:1 or better

Data Acquisition Rate

1,000,000 points/sec. to
1 point/1000 sec

300/300 Plus: 1 point/sec to
300 points/sec
310: Up to 20 points/sec

1,000,000 points/sec.
to 1 point/1000 sec


4 photon counting (TTL); 4 analog (+/- 10 volts) ; 1 analog reference channel (+/- 10 volts); 2 TTL


2 analog (+/- 10 volts) 2 TTL

Emission Range

185 nm to 900 nm
(optional to 5,500 nm)

185 to 680 nm
(optional to 5,500 nm)

185 to 680 nm
(optional to 1,010 nm)

Light Source

High efficiency “ECO” friendly
continuous 75 W Xenon arc
lamp (Optional 450 W xenon)

300/300 plus: High power
Xenon flash lamp
310: Nitrogen laser pumped
dye laser

High efficiency “ECO” friendly
continuous 75 W Xenon arc


300 mm, coma-aberration corrected, asymmetrical, excitation or emission optimized, Czerny-Turner design

Focal Length

300 mm

300 mm

150 mm excitation
300 mm emission


Computer controlled,
continuously adjustable

Manual or computer
controlled, continuously

Manual continues Excitation,
Manual or computer controlled
continuous Emission

Emission Grating

1200 line/mm 400 nm blaze
(Plus two optional gratings)

1200 line/mm 400 nm blaze
(Plus two optional gratings)

1200 line/mm 400 nm blaze
(Plus two optional gratings)

Optional Grating


75 to 2400 line/mm and holographic models available


+/- 0.3 nm

+/- 0.3 nm

+/- 0.05 nm excitation
+/- 0.3 nm emission

Minimum Step Size

0.022 nm

0.022 nm

0.05 nm excitation
0.022 nm emission

Lifetime Range


1 μs to seconds



Multimode: Photon Counting, 3 analog (fast, medium, slow response), direct and Single-Shot
Transient Digitizer (SSTD) mode

System Control

Computer interface with spectroscopy software

PTI QuantaMaster Series

The PTI QuantaMaster series of modular research grade spectrofluorometers are multidimensional systems for photoluminescence measurements. The foundation of a fluorescence spectroscopy laboratory is built on steady state intensity measurements such as wavelength scans, time-based experiments, synchronous scans and polarization. The PTI QuantaMaster series ensures you get the best possible results for all these measurements with high sensitivity, spectral resolution and stray light rejection. This level of sensitivity is achieved using a unique xenon illuminator, providing safety, cost, and energy consumption benefits not found amongst competitor companies. These conditions make the PTI QuantaMaster system more than capable of meeting the highest demands of research.

The PTI QuantaMaster system is adaptable to every research need, with additions such as TCSPC lifetimes, upconversion lasers and phosphorescence detection up to 5,500 nm. Using the pulsed light source allows for not only spectral and kinetic fluorescence and phosphorescence measurements, but also the measurement of lifetimes in the microsecond to seconds range. This addition is especially beneficial when using fluorescent probes prone to photobleaching, and when characterizing inorganic material with longer lifetimes. The modular design of the PTI QuantaMaster ensures that your system can be easily adapted to your growing research needs.

Unique PTI QuantaMaster Benefits

  • Highest guaranteed sensitivity specification1
  • World class software for all steady state and lifetimes needs
  • Extended wavelength range with triple grating monochromators
  • Multiple light sources and detectors with dual entrance & dual exit monochromators
  • Excellent stray light rejection with large single or double additive, coma corrected, monochromators
  • World class TCSPC lifetime enhancements
  • NIR steady state and phosphorescence lifetime detection to 5,500 nm

Lifetime Measurements TCSPC

The QuantaMaster series can be easily enhanced with TCSPC fluorescence lifetime capabilities. Utilizing world class TCSPC sources, electronics and detectors developed by our IBH group, the QuantaMaster provides the ultimate in speed, versatility and performance. The standard QuantaMaster PMT can be used for these additional TCSPC measurements, or you can add a dedicated TCSPC detector with enhanced performance or extended NIR detection. All steady state and time-resolved control, acquisition and analysis are handled by FeliXGX software.


  • 40 years of experience in TCSPC innovation
  • Industry-leading true 100 MHz system operation allows for millisecond acquisition times
  • TCSPC lifetime measurements from under 25 ps
  • Full control over TCSPC and steady state acquisitions with single Felix GX software package
  • Measure TCSPC lifetimes, time-resolved anisotropy and TRES
  • Select from our catalog of over 60 state-of-the-art compact pulsed LEDs and Laser Diodes for
    virtually any application
  • For unsurpassed versatility choose a picosecond Supercontinuum Laser with HORIBA’s proprietary
    Frequency Doubler – a powerful tool for Time-Resolved protein studies
  • PowerFit-10 decay analysis package with multiple fitting models including a unique Maximum
    Entropy Method (MEM) lifetime distribution program
Lifetime Measurements TCSPC

Two Systems Can be Better Than One!

We also offer very affordable stand-alone TCSPC systems. You can increase your labs throughput by having a dedicated steady state fluorometer and a dedicated TCSPC system operating at the same time, for almost the same price as adding TCSPC to the QuantaMaster.

Near-Infrared Spectrofluorometry

Near-infrared (NIR) spectrofluorometry has emerged as a valuable analytical technique, especially in the fields of material research, nanotechnology, chemistry, and photomedicine. Powerful and diverse NIR capabilities are available through PTI as either a stand-alone research grade fluorometer, or as an upgrade to PTI’s UV-VIS steady state spectrofluorometers. There are different configurations to adapt to any research needs.

Near-Infrared Spectrofluorometry

NIR-PMT Based Steady State Systems

Comprised of a high intensity continuous xenon light source, scanning monochromators, and a cooled NIR PMT detector. Available with four NIR PMTs for maximum spectral range coverage:

  • 300 nm–1,400 nm, LN-cooled
  • 950 nm–1,400 nm, TE-cooled
  • 300 nm–1,700 nm, LN-cooled
  • 950 nm–1,700 nm, TE-cooled

Solid-State Photodiode Based NIR Steady State Systems

Comprised of a high intensity continuous xenon light source, scanning monochromators, lock-in amplifier and chopper for noise suppression. There are a variety of photo diodes available, TE-cooled or LN-cooled up to 2400 nm:

  • InGaAs: 500 nm–1,700 nm (up to 2400 nm detector available upon request)
  • PbS: 1,000 nm–3,200 nm
  • InSb: 1,500 nm–5,500 nm

Additions for NIR Lifetime Measurements to 5,500 nm!

All of the detectors listed above can be used in a single shot transient digitizer (SSTD) mode for luminescence lifetime measurement capability in NIR to measure lifetimes from 1 μs to hundreds of ms. SSTD is extremely fast and offers outstanding signal to noise, add:

  • Variable high rep rate pulsed xenon lamp option for
    phosphorescence lifetime (NIR-TR-10)
  • Pulsed nitrogen and dye laser (NIR-TR-20)
  • 3rd party pulsed Q-switched lasers
  • TCSPC lifetime add-on with supercontinuum laser,
    laser diodes and LEDs (for NIR-PMT based systems)

Unique NIR Solutions

A PTI QuantaMaster can be equipped with multiple illuminators and detectors to cover the widest spectral
range for both steady state spectra and for fluorescence and phosphorescence lifetimes. Consider the
following configuration:

  • Double emission monochromator with R928 PMT, InGaAs &, InSb detectors cover 250 to 5,500 nm
  • Continuous xenon lamp for steady state spectra
  • 20 Hz Q-switched/OPO Opolette laser for tunable excitation from 210 to 2,200 nm
  • Or frequency doubled nitrogen pumped dye laser for tunable excitation from 250 to 990 nm
  • Steady state spectra from 250 to 5,500 nm
  • Single Shot Transient Digitizer (SSTD) phosphorescence decays over entire range from 250 to 5.500 nm
PTI QuantaMaster

Modularity To Grow

The PTI QuantaMaster series features an open architecture design that provides the ultimate in versatility, allowing your instrument to adapt to your future fluorescence application needs. You can optimize the initial configuration by choosing the light source, gratings, and PMT tubes, as well as a wide array of available accessories. The number of available configurations is virtually limitless!

The PTI QuantaMaster universal QuadraCentric™ sample compartment has a spacious design that provides accessibility and can accommodate a wide selection of sample accessories. Choose from sample temperature controllers to various holders for solids, liquids and powders, and many other options. See the Accessories page for more details.

PTI QuantaMaster series features

The open architecture design also allows for application and methodology changes. As your application needs grow, so can your PTI QuantaMaster. For example, if you develop a need to measure dynamic anisotropy, you can add a second emission channel and a set of polarizers. If you want to complement your steady state data with lifetime measurements, you can do so by adding a laser or LED-based excitation to your initial configuration. If you are interested in intracellular Ca2+ after completing initial Fura-2 studies, you may decide you would like to start imaging the events. The system can be easily coupled with any fluorescence microscope. Whether you choose to add NIR detection or a second excitation source, the possible configurations are endless.

PTI QuantaMaster



PTI FelixGX Software

PTI FelixGX Software

PTI QuantaMaster fluorometers come with our own software for the control of the instrument and accessories, which includes analytical functions for trace manipulation, and spectral and kinetic analysis. Through the powerful ASOC- 10 USB interface, PTI FelixGX provides a full set of data acquisition protocols, and controls the hardware for all system configurations and operating modes.

PTI FelixGX Controls

Hardware Controls

Acquisition Modes

  • Monochromators
  • Triple grating turret
  • Flipping mirrors switching between different
  • light sources and detectors
  • Motoried slits
  • Motorized polarizers
  • Motorized multiple sample holders
  • Excitation correction detector (Xcorr)
  • Temperature control Peltier devices
  • Cryostat
  • Gain control of PMT detector
  • Switching from digital to analog mode
  • External devices such as stopped flow and
  • titrator
  • Pulsed light sources
  • Scanning of wavelength-tunable OPO lasers
  • TCSPC electronics
  • Electroluminescence and photovoltaic
  • accessories

PTI FelixGX provides several acquisition modes for spectral and kinetic measurements:

  • Excitation and Emission spectral scans with user control of integration time, monochromator step, speed and wavelengths
  • Time-based scan with user defined macro-time duration and integration time
  • Spectral and time-based polarization scans with full control of motorized polarizers and automated measurement of G-factor, and sample background for all polarizer orientations
  • Simultaneous multi dye measurements with predefined library of common fluorescence dyes or customer-defined dyes
  • Synchronous excitation/emission scan
  • Excitation and emission ratio fluorescence
  • Phosphorescence decay and time-resolved excitation and emission spectra using Single-Shot Transient Digitizer (SSTD)
  • Phosphorescence decay and time-resolved excitation and emission spectra using gated detection (VCI)

Macro Capabilities


PTI FelixGX comes equipped with Macro capabilities to allow for automated measurements. Choose from a list of actions to make a chain of commands, or set up a loop function to eliminate the need to constantly change the acquisition settings. Set up the automation job and simply walk away, letting PTI FelixGX execute your demands.

PTI FelixGX Analytical Capabilities

PTI FelixGX Analytical Capabilities

Trace Manipulation

PTI FelixGX also provides an extensive set of math functions that can be used for processing and manipulation of acquired data traces:

  • Antilog
  • Average
  • Distribution average
  • XY Combine
  • Differentiate
  • Integrate
  • Linear Fit
  • Linear Scale
  • Logarithm
  • Normalize
  • Reciprocal
  • Smooth
  • Truncate
  • Baseline
  • Merge Traces
  • Peak Finder

Kinetic Data

PTI FelixGX Software Kinetic Data
PowerFit-10 output graph with residuals and autocorrelation.

Fluorescence and phosphorescence decays can be analyzed with the PowerFit-10 lifetime analysis package which includes:

  • One to four exponentials
  • Multi one to four exponentials
  • Global one to four exponentials
  • Anisotropy decays
  • Exponential Series Method (ESM) lifetime distribution
  • Maximum Entropy Method (MEM) lifetime distribution
  • Micelle kinetics
  • Stretched exponential

Advanced Calculators

PTI FelixGX also offers a special set of software functions, such as quantum yield, absorption, FRET and color coordinates calculators, as well as the software that calculates structural parameters for single-walled carbon nanotubes. These are very convenient additions to some accessories, such as the integrating sphere or absorption accessory, and are also indispensable for some fluorescence applications, such as intermolecular interactions (FRET) and materials characterization.

Absorption Calculator

Absorption measurements are complementary to fluorescence. They are necessary for fluorescence quantum yield determination and are an easy and convenient way to check the fluorophore concentration. You can compare the absorption and excitation spectra to draw conclusions about the purity of the sample. Using the built-in absorption calculator with an absorption accessory will greatly enhance the capabilities of your PTI QuantaMaster fluorometer.

Quantum Yield

Quantum yield is one of the most important parameters that characterize photoluminescence of materials. PTI FelixGX incorporates a quantum yield calculator which, when coupled with an integrating sphere, allows you to calculate the quantum yield with ease.

PTI FelixGX Software Advanced Calculators



The FRET technique provides information about molecular distances, interactions in macromolecular systems, binding, diffusion, sensing, etc. FRET happens when an excited donor molecule transfers its energy to an acceptor in the ground state. FRET is essentially a molecular ruler, where distances are scaled with the Förster critical radius Ro, which is a unique parameter for a given donor-acceptor (D-A) pair, defined by spectroscopic parameters of the pair and their environment. Once the Ro is known and the FRET efficiency is determined experimentally, the D-A distance and the FRET rate constant can be calculated. PTI FelixGX provides an easy and convenient way of calculating all relevant FRET parameters, including Ro.

Advanced Calculators

PTI FelixGX Advanced Calculators

Single-Walled Carbon Nanotube Calculator

Carbon nanotubes can be characterized using the specially-designed NanoCal within PTI FelixGX. NanoCal analyzes 3-D ExEm spectral maps and returns structural parameters such as the nanotube radius and the chiral angle. Combining this easy-touse software with PTI QuantaMaster NIR options allows for full characterization of SWCNTs.




PTI FelixGX Color Coordinate Calculator

Color Coordinate Calculator

In many applications, such as phosphors for screen displays, multi-color LEDs, fluorescent additives to consumer products, etc., there is a need to quantify a visual perception of color. PTI FelixGX provides a Color Coordinate Calculator based on two widely accepted standards introduced by the International Commission on Illumination, CIE 1931 and CIE 1976. The CIE 1931 uses x,y chromaticity coordinates where each x, y pair corresponds to a unique color within the colored shape. The CIE 1976 uses a system with more uniform perceptual chromaticity to define the color space using u, v coordinates. Upon highlighting a spectral trace and clicking on CIE 1931 and CIE 1976 Color Coordinates, PTI FelixGX will display both CIE pairs. Advanced Calculators

Color Coordinate Calculator

Applications and Examples: UV VIS Fluorescence Spectroscopy

Steady State Anisotropy

Steady State Anisotropy
Temperature-induced unfolding of bovine serum albumin (BSA) in PBS (pH=7.4) monitored by fluorescence anisotropy with dual mission channels using a rapid temperature change Peltier option.

Both photon absorption and photon emission are correlated in space with the transition dipole moment vector of the molecule. Therefore, a measurement of the fluorescence polarization of the emitted light can yield information about the rotational mobility of the molecule under investigation. The rotational mobility of a macromolecule such as protein or DNA, depends on its size, conformation and viscosity of the medium. Fluorescence anisotropy measurements provide an easy and powerful tool to study conformational transitions, such as protein folding and unfolding induced by temperature, pH changes, and drug or ligand binding. For fast and convenient anisotropy measurements, dual emission configurations are available to allow simultaneous determinations of vertically and horizontally polarized fluorescence signals. A software controlled rapid temperature change Peltier unit is a valuable option for anisotropy measurements.

Total Luminescence Spectroscopy (TLS)

The powerful PTI FelixGX software, with its user-friendly macro programming capability, and the rapid scanning performance of the PTI QuantaMaster, make it easy to create automated acquisition protocols for measuring emission spectra at varying excitation wavelengths, and creating a 3-D EEM characterization of a fluorescing sample. Such measurements enable the user to fully characterize spectrally complex samples very rapidly with minimum personal involvement. This means you save valuable time. The TLS technique is used in various analytical applications of photoluminescence spectroscopy. It is especially useful for detecting and identifying Polycyclic Aromatic Hydrocarbons (PAHs) in environmental samples, as well as in food science to test for contaminants or assess foodstuff deterioration. 3D mapping can then be used to demonstrate the naturally occurring fluorescent components.

Total Luminescence Spectroscopy (TLS)

Synchronous Fluorescence Spectroscopy (SFS)

Synchronous Fluorescence Spectroscopy (SFS)
The data represents a mixture of three organic hydrocarbons: p-terphenyl, anthracene, and perylene. The ordinary emission scan does not reveal the complexity or identities of the mixture. On the other hand, the synchronous scan clearly shows 3 narrow emission peaks located at the emission maxima of the respective compounds, making it possible to identify the mixture components.

Synchronous Fluorescence Spectroscopy involves scanning the excitation and emission monochromators simultaneously at identical scan rates, with a fixed offset between the two wavelength ranges. It offers much higher spectral selectivity than the conventional emission and excitation scans, reduces light scattering and improves resolution. SFS is a powerful analytical technique that enables simultaneous determination of multiple components in the mixture. It has been used in detecting carcinogenic Polycyclic Aromatic Hydrocarbons (PAHs) in food and environmental samples.

Ratiometric Measurements for Intracellular Ions

Excitation-shifted probes such as Fura-2 and BCECF are often used in determining intracellular calcium concentration and pH. These probes exhibit an excitation shift upon binding calcium (Fura-2) or protonation (BCECF). In these experiments, the excitation monochromator automatically alternates between two excitation wavelengths corresponding to the free and ion-bound probe. The ratio of the two signals is also measured. Pre-configured look-up tables transform the measured intensity ratio into ion concentrations or pH. Similar measurements can be done for emission shifted probes such as Indo and carboxy-SNARF.

Ratiometric Measurements for Intracellular Ions

Time Based Measurements

Time Based Measurements
BSA protein unfolding induced by detergent SDS monitored

Probably one of the most common experiments, time based measurements, are useful for many applications such as enzymatic activity assays, ion activity in cells, titration studies, proteinprotein and protein-drug interactions, anisotropy measurements, and chemical kinetics. The measurements involve monitoring the fluorescence intensity at fixed excitation, and emission wavelengths as a function of time. The PTI QuantaMaster series can do kinetic measurements on a time scale ranging from microseconds to hours or days. The use of the excitation correction unit (Xcorr) greatly improves the signal stability by eliminating any light source intensity fluctuations and drift over time.

For best results, time-based kinetic experiments should be conducted at a controlled temperature. Therefore our Peltier-based rapid temperature controlled cuvette holders, K-155-C or K-157-C, are recommended. If very fast reaction kinetics are studied, a stopped-flow accessory, K-161-B, will be a useful addition.

Förster Resonance Energy Transfer (FRET)

FRET is a popular technique used to study binding, conformational changes, dissociation and other types of molecular interactions. Applications of FRET are especially common in biomedical research involving protein-protein, protein-nucleic acid interactions, protein folding/unfolding, nucleic acid hybridization, membrane fusion and many others. There is also a variety of immunoassays based on FRET. The FRET phenomenon occurs between an excited donor (D) molecule and a ground-state acceptor (A) molecule over a range of distances, typically 10-100 Å. It is a nonradiative process, meaning no photon is emitted or absorbed during the energy exchange. The efficiency of FRET is strongly dependent on the D-A distance and is characterized by the Förster critical radius Ro, a unique parameter for each D-A pair. Once Ro is known, the D-A pair can be used as a molecular ruler to determine the distance, or monitor distance changes between sites labeled by D and A. Since FRET is mostly used to study biological systems, where concentrations are often low and samples can be highly scattering, the PTI QuantaMaster is an ideal fluorometer for this application due to its high sensitivity and excellent stray light rejection. It is also easy to upgrade to a lifetime option, which can be very beneficial for verification of the FRET mechanism. The PTI QuantaMaster series will also help you take advantage of this technology with the built-in PTI FelixGX FRET Calculator.

Förster Resonance Energy Transfer (FRET)
Titration monitored by FRET between Alexa-BSA complex and a Bodipy-labeled fatty acid.

Automated Temperature Control

Sample temperature plays a critical role in all types of luminescence measurements. For example, when the emission anisotropy is measured, the viscosity will change as a function of the temperature affecting the rotational motion of the fluorophore. The temperature control can be critical for fluorescence quantum yield determination, or any quantitative intensity measurements since the nonradiative deactivation is strongly temperature dependent. Temperature control is essential in fluorescence studies of proteins as it affects thermal stability of proteins, and their folding and unfolding characteristics.

Solid samples, such as doped crystals, glasses, ceramics, and organic molecules deposited on surfaces will exhibit narrowing of spectral lines when cooled to low cryogenic temperatures, thus allowing study of fine interactions. Organic molecules will usually exhibit phosphorescence when cooled to sufficiently low temperatures.

The PTI QuantaMaster series comes standard with a thermostatable cuvette holder where the plumbing is already in place for temperature control utilizing a circulating water bath. If your research requires more precise or extreme temperature control, additional solutions are available, including software controlled Peltier-based variable temperature cuvette holders (single or 4 position) and a liquid nitrogen cryostat. Programmable spectral scans at automatically varying temperatures and temperature ramping experiments are available.

Temperature control is critical in applications, such as:

  • Temperature dependent quantum yields
  • Quantitative intensity measurements
  • Activation energies of photophysical processes
  • Protein folding and unfolding
  • Nucleic acid melting profiles
  • Thermodynamic parameters of binding reactions
  • Membrane fluidity and permeability studies
  • Fluorescence measurements of live cells
  • Enzyme kinetics
Automated Temperature Control
Fully automated temperature mapping emission scans of coronene deposited on silica measured in liquid nitrogen cryostat. As the temperature is lowered, the phosphorescence spectrum begins to appear and intensity increases.

Phosphorescence with a Pulsed Light Source

Fluorescence and phosphorescence spectra
Phenanthrene at 77 K utilizing a cold finger Nitrogen Dewar Accessory. Fluorescence and phosphorescence spectra measured while increasing the delay time (at 2 μs increments) for signal integration.

A pulsed light source and the ability to integrate the signal at user-selected time delay are dispensable tools in discriminating spectra based on the lifetime of the respective excited state. Fluorescence emission happens on the picosecond to nanosecond time scale, while phosphorescence occurs on the microsecond to second time scale. By varying the temporal position and the width of the signal detection gate one can selectively detect fluorescence and phosphorescence spectra as attested by phenanthrene spectra on the accompanying figure. Here, the emission of phenanthrene in a frozen glass was measured with gradually increased time delay of the detection gate to diminish contribution of fluorescence. However, the true potential of this technique can be seen in the case of Room Temperature Phosphorescence (RTP) of RNase T1 tryptophan, where the signal was extracted by gating out the overwhelming Trp fluorescence—a task impossible with a continuous excitation source. Conveniently, the same instrument can be used to measure phosphorescence decay of this extremely weak emission by using the Single-Shot Transient Digitizer (SSTD) function of the ASOC-10 interface.

Room Temperature Phosphorescence (RTP)
Discrimination between strong fluorescence and weak Room Temperature Phosphorescence (RTP) from RNase T1 tryptophan by varying the temporal position and widths of the signal detection gate on a PTI QuantaMaster equipped with a pulsed Xe lamp and gated detector for signal integration.
Phosphorescence decay of a weakly emitting RNase T1 tryptophan signal
Phosphorescence decay of a weakly emitting RNase T1 tryptophan signal using the same instrument.

Bio and Chemiluminescence

Bio and Chemiluminescence
The unsurpassed sensitivity of the PTI QuantaMaster detection

Semiconductors Research

Semiconductors Research
Due to its dedicated accessories, such as a well-designed solid sample holder and excellent stray light rejection characteristics, the PTI QuantaMaster is an excellent choice for semiconductors research. Here, clean spectra from strongly scattering ZnO samples were measured with the PTI QuantaMaster equipped with a double excitation monochromator.

Fluorescence Upconversion

Fluorescence Upconversion
Upconversion phenomena in lanthanide-doped glasses and powders has been extensively studied in recent years. They are of interest due to a demand for compact and efficient lasers and amplifiers for optical communications, especially
luminescence upconversion quantum yields
The upconversion setup allows for simple determination of the luminescence upconversion quantum yields due to an efficient and ergonomicallydesigned integrating sphere (shown with the top removed) with easy access to the sample

Electroluminescence and Photovoltaic Measurements

Electroluminescence and Photovoltaic Measurements
The flexibility of the modular design makes it easy to utilize the PTI QuantaMaster for more specialized applications, such as electroluminescence or photovoltaic measurement. Here, the figure shows an electrical response of a photovoltaic cell illuminated with the PTI QuantaMaster excitation monochromator equipped with an NIR grating. The electrical signal from the cell is fed directly to one of the analog inputs of our versatile ASOC-10 interface, and the powerful PTI FelixGX software takes care of rest!
electroluminescent sample
Emission generated by applying different voltages (6V and 9V) to a thin film electroluminescent sample using the PTI QuantaMaster with the electroluminescence accessory.

Quantum Yield

Quantum Yield determination of Nd3+ doped glass in NIR with the integrating sphere and InGaAs detector
Quantum Yield determination of Nd3+ doped glass in NIR with the integrating sphere and InGaAs detector

Quantum Yield determination of Nd3+ doped glass in NIR with the integrating sphere and InGaAs detector. The measurement requires high signal stability and precise emission corrections. The QY experiment involves emission scanning over the excitation peak, which is usually significantly higher than the emission spectrum. Since the absorbance of the sample is very low, an excellent signal stability, high dynamic range and a linear behavior of the detector are of utmost importance for accurate QY determination. The graph on the right shows the expanded excitation peak with, and without, the sample. Capturing the difference of the two signals is the key to accuracy. The triplicate experiment showed excellent reproducibility resulting in QY = 0.567 ± 0.017.

Applications and Examples: NIR Fluorescence Spectroscopy

The applications and interest in NIR photoluminescence have been growing rapidly in recent years. This trend is spearheaded mostly by extensive research in nanotechnology and materials science. NIR-emitting nanoparticles, lanthanide doped glasses and ceramics used in developing new laser media and photonic devices, single-walled carbon nanotubes, semiconductor and electroluminescent systems are only a few dominant applications. There is also a considerable research effort in the optical fiber communication industry to develop infrared molecular amplifiers for the transmittance window at 1550 nm. In biomedical areas, there is a trend of using NIR-emitting nanoparticles as luminescent markers due to the fact that the light scattering, a notorious problem in UV-VIS fluorescence measurements, is greatly reduced as the wavelength increases. Less interference means better signal to noise with strongly scattering biological samples. NIR light can penetrate tissue at a much greater depth than the UV and VIS— a definite advantage in tissue imaging and therapeutic applications. In photobiology, the detection of singlet oxygen and development of efficient photo sensitizers for PDT has been the dominant application for years. The continuing introduction of new NIR emitters, coupled with better detection and lower cost systems continues to fuel the growth of NIR luminescence applications. PTI offers an extensive line of PTI QuantaMaster NIR photoluminescence systems with a broad range of options and accessories. The detectors offered include both NIR PMTs and solid state photodiodes that span the range of up to 5,500 nm. Most of these detectors can also be used with pulsed light sources, thus providing the lifetime capabilities in NIR.

Applications of NIR Fluorescence

  • Materials Science
    • Nanomaterials
    • Glasses and ceramics
    • LEDs and lasing media
    • Semiconductors
    • Upconverting nanoparticles for tissue imaging
  • Optical fiber communication
    • Optical amplifiers (e.g. chelated Er3+, 1540 nm)
  • Photobiology and photomedicine
    • Singlet oxygen detection
    • R&D of singlet oxygen photosensitizers
    • Photodynamic Therapy (PDT)
  • Environmental
    • Photo-oxidation of environmental pollutants
  • Geology
    • NIR luminescence of minerals
  • Forensic science
    • Identifying forged documents

Photoluminescene of Lanthanides

Many applications using photoluminescence measurements involve rare earth ions (lanthanides), such as Nd3+, Er3+, Tm3+, Ho3+ and Pr3+, which often emit in the NIR. Often these ions are used with ligand photosensitizers which improve their light absorption properties, as lanthanide ions themselves are very weak absorbers. They are used as dopants in lasing media and glasses, and are made into nanoparticles of varying sizes and shapes in order to control their optical properties. The photoluminescence lifetime (from microseconds to milliseconds) is the key parameter in assessing the optical efficiency of devices involving lanthanides, as well as in quality control during their manufacturing.

PL emission and excitation spectra
PL emission and excitation spectra of Ho3+ doped glass measured with the PTI QuantaMaster 500, using the TE-cooled inGaAs detector and lock-in amplifier.
PL decays of Ho3+ doped glass measured with the PTI QuantaMaster 500 system operating in the lifetime mode. Note that the decays are very different for different transitions. The decay at 1200 nm also shows a rise time of 2.4 μs.

Single Walled Carbon Nanotubes

Single-walled carbon nanotubes have been one of hottest topics in photonics/materials science in the last few years. There are numerous existing and potential applications where SWCNTs are used, such as microdiodes and microtransistors, computing and switching devices, screen displays, gas sensors, biological sensors (NA hybridization), bio-imaging, drug delivery and many others. Mechanically, they are 3 to 10 times stronger than steel and exhibit high thermal and electrical conductivity.

SWCNTs are made of a sheet of graphene rolled along a certain angle (chiral angle) into a tube of diameter r. These structural parameters can be determined by photoluminescence measurements, usually in the NIR range. By collecting a 3D excitation-emission matrix and determining the excitation and emission wavelengths of the 3D PL peaks, the structural parameters, the chiral angle and r, can be calculated. Felix GX provides the Nanotube Calculator which makes this task easy.

Single Walled Carbon Nanotubes
Photoluminescence spectra of two different SWCNTs measured with the PTI QuantaMaster 600 NIR photoluminescence spectrometer. In order to determine the chiral angle α and the nanotube radius r, a 3-D ExEm matrix needs to be acquired, and the result submitted to the Nanotube Calculator. 

Optical Fiber Communications

The use and demand for optical fiber communication has grown rapidly and applications are numerous, ranging from global networks to desktop computers. There have been three spectral ‘windows’ used for optical transmission: 850 nm, 1310 nm and 1550 nm, with the third window now becoming a globally accepted transmission band. There is a need to insert some light amplifiers along the fiber line. One idea of amplifying the signal is based on a chelated Erbium ion. Erbium belongs to the family of lanthanides and has an emission band in the NIR at about 1550 nm, so it matches perfectly the 3rd optical transmission window. The chelating molecules are excited in the UV or VIS by inexpensive LEDs and transfer the excitation energy by FRET to the Erbium center, thus promoting Erbium to its excited state. Since the energy difference between the excited and ground state of Erbium equals the energy of photons (1550 nm) that are propagated along the fiber, these incoming photons will stimulate the emission from Erbium, enhancing the overall signal.

Optical Fiber Communications
Emission spectrum of chelated Erbium (solid sample) measured with the NIR-PMT and solid sample holder accessory. The system features a thermoelectrically cooled, extended wavelength range NIR PMT operating in the photon counting mode.
Luminescence decay of chelated Erbium (solid sample) measured with the NIR-PMT system operating in the time-resolved ‘gated’ mode. The decay can be described by a broad tri-modal lifetime distribution, as shown by the MEM distribution analysis—a powerful analysis package from PTI.

Singlet Oxygen Detection

Singlet oxygen generation and detection are growing fields with applications in such areas as cancer treatment, photosensitized oxidations, and biomolecular degradation. The first excited state of an oxygen molecule is a singlet state, which can readily react with other singlet molecules. Radioactive decay to the triplet ground state is a spin forbidden transition resulting in a long lived excited state. Excited singlet oxygen emits phosphorescence in the NIR at 1270 nm.

Singlet Oxygen Detection
Spectra of singlet oxygen generated by Rose Bengal in methanol
Lifetime of singlet oxygen using a NIR-PMT with the Xe flash lamp. This is a substantial undertaking, considering the singlet oxygen phosphorescence quantum yields are of the order of 10-6

Tags: Fluorescence, Diffuse Reflectance, Quantum Efficiency (IQE), Transmittance, Absorbance

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