LabRAM Odyssey

LabRAM Odyssey Picture

Imagerie Confocale Raman et Spectromètre à Haute Résolution

Advancing Knowledge Further *

Les microscopes Raman LabRAM Odyssey sont parfaitement adaptés aux mesures micro et macro, et offrent des fonctions avancées d'imagerie confocale 2D et 3D. Le microscope confocal Raman permet d'obtenir rapidement et en toute confiance des images et des analyses plus détaillées que jamais. Associant haute performance et utilisation intuitive, le LabRAM Odyssey est l'instrument idéal pour la spectroscopie Raman.  Les microscopes LabRAM Odyssey sont largement utilisés pour l'analyse Raman standard, la photoluminescence (PL), la spectroscopie Raman exaltée par effet de pointe (TERS) et d'autres méthodes hybrides.

Passez de la microscopie à la nanoscopie en toute simplicité grâce au couplage AFM.

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Segment: Scientific
Fabricant: HORIBA France SAS

Haute résolution spatiale et spectrale
La conception optimisée du spectromètre à simple étage à haute sensibilité de 800 mm de focale d'HORIBA Scientific permet de développer les instruments les plus sensibles du marché, avec une résolution spatiale optimale et une diffraction limitée. Sur le plan spectral, le spectromètre haute résolution facilite la caractérisation d'informations subtiles d'un échantillon, telles que la cristallinité, le polymorphisme, la contrainte et d'autres analyses de bandes.

De l'UV profond au proche Infrarouge sans concessions
La compatibilité avec une large gamme de longueurs d'onde laser et la possibilité de monter jusqu'à trois détecteurs permettent d'étendre la gamme de longueurs d'onde de mesure de 200 nm à 2200 nm. La configuration UV optimisée offre une solution idéale pour l'analyse Raman UV avec des longueurs d'onde inférieures à 400 nm. Ces performances ouvrent la voie à d'autres techniques spectroscopiques telles que la spectroscopie Raman UV, la spectroscopie Raman de résonance et la photoluminescence, pour une caractérisation détaillée d'échantillons de matériaux très variés.

Facilité d'utilisation et ergonomie
La conception intelligente et entièrement automatisée du LabRAM Odyssey garantit des performances ultimes associées à une grande facilité d'utilisation. Le vaste choix d'applications dédiées à LabSpec 6, disponibles dans le LabStore, permet de configurer et de faire évoluer le logiciel en fonction de vos besoins.

Le LabRAM Odyssey offre un haut niveau d'automatisation, tel que le choix du laser, une tourelle à objectifs automatisée, ou encore la calibration spatiale automatique avec sa fonction VRM brevetée.

Imagerie confocale ultrarapide
Le LabRAM Odyssey intègre les technologies uniques d'imagerie Raman rapide SWIFT™ et DuoScan™.
DuoScan™ est un mode d'imagerie confocale, avec des miroirs de balayage haute précision ultrarapides qui créent des macro-points laser de taille variable et permettent de réaliser une cartographie par macro-pas, de l'UV profond au proche IR.
SWIFT™ assure une cartographie Raman confocale avec des temps d'intégration CCD pouvant descendre à 1 ms par point, voire moins.

La combinaison unique d'optiques, de détecteurs et de logiciels innovants permet d'obtenir une véritable imagerie confocale Raman avec une vitesse d'acquisition des données inégalée.

Compatible Raman-AFM et TERS
Grâce à sa grande flexibilité, le LabRAM Odyssey est la plateforme idéale pour combiner l'analyse Raman-AFM et la recherche par spectroscopie nano-Raman TERS (diffusion Raman exaltée par effet de pointe).

Le LabRAM Odyssey peut également intégrer notre fonction brevetée nanoGPS™ navYX pour réaliser une caractérisation collaborative complète avec diverses autres modalités de microscopie telles que SEM, FTIR, et autres.

Module à ultra-basse fréquence (ULF)
Le LabRAM Odyssey allie simplicité d'accès aux très basses fréquences, jusqu'à 5 cm-1, avec un spectromètre haut rendement à plateau unique, grâce au module ULF. La nouvelle génération de filtres coupe-bande et passe-bande améliore la caractérisation de l'échantillon dans une région spectrale rarement accessible avec d'autres spectromètres de base.

Localisation et identification chimique automatisée des particules
ParticleFinder est un outil convivial de localisation, de caractérisation et d'analyse Raman automatisées des particules. Les fonctions Raman avancées du LabRAM Odyssey permettent de localiser et de caractériser rapidement des centaines, voire des milliers de particules.

Profitez des meilleures conditions pour l'analyse de votre échantillon
La flexibilité d'échantillonnage du LabRAM Odyssey permet d'optimiser pleinement vos recherches. Il est équipé de série d'un microscope en espace ouvert. Le dégagement sous l'objectif vous permet ainsi d'adapter de nombreux accessoires, comme des cryostats de grande dimension ou des plateaux à large débattement. Dans le domaine de la recherche en sciences de la vie, le microscope inversé offre un échantillonnage idéal pour les cellules et les tissus.

Piégeage laser CaptuR
Cette solution unique de piégeage laser intégrée est idéale pour le contrôle des particules fines lors des analyses microscopiques.

Spécifications Générales
Gamme de longueur d'ondeUV profond jusqu'à VIS-NIREn standard 200 nm - 2200 nm (achromatique, pas de changement d'optique nécessaire)
Spectrometer ImageurConfiguration Czerny-TurnerLongueur focale : 800 mm
LasersJusqu'à 6 motorisésSélectionnables par l'utilisateur: 266 nm, 325 nm, 355 nm, 405 nm, 458 nm, 473 nm, 532 nm, 633 nm, 660 nm, 785 nm, 1064 nm
D'autres longueurs d'onde sont possibles sur demande.
Filtres LaserIllimitéGamme de filtres variée (Dielectric, Notch, ULF…) pour répondre à toutes les applications
Nombre de réseauxIllimité 
Résolution spectrale
FWHM
À la longueur d'onde d'excitation de 244 nm : ≤ 1.5 cm-1 avec 3600 t/mm
À la longueur d'onde d'excitation de 532 nm : ≤ 0.6 cm-1 avec 1800 t/mm et ≤ 0.3 cm-1 avec 3000 t/mm
À la longueur d'onde d'excitation de 633 nm : ≤ 0.4 cm-1 avec 1800 t/mm et ≤ 0.2 cm-1 avec 2400 t/mm
À la longueur d'onde d'excitation de 785 nm : ≤ 0.2 cm-1 avec 1800 t/mm
Ultra-basse fréquence
(ULF)
< 10 cm-1, mesure sur le soufreBasé sur des filtres à réseau de Bragg (VBG). Disponible pour les excitations laser à 473, 532, 633 et 785 nm.
Fonctions de calibration
automatisées internes
Méthodes intégrées automatiques AutoCAL et ICS,
VRM & VRM OA de série
Calibration automatique de l'intensité et de la gamme spectrale.
VRM génère une haute précision spatiale pour les cartographies Raman et microscopie,
VRM OA permet de modifier le facteur de grossissement sans perte de précision spatiale.
Imagerie Raman rapideFonctions SWIFT™ brevetéesCompatible avec tous les objectifs et lasers.
3 modes disponibles de série : imagerie SWIFT™, imagerie répétitive et haute résolution spectrale XR.
L'imagerie à haute vitesse SWIFT™ XS nécessite un détecteur EMCCD disponible en option.
Couplage AFM / SEMOuiCompatible avec le module NanoRaman et l'accessoire breveté nanoGPS™ navYX pour les mesures corrélatives.
Dimensions l x H x P
(mm)
1300 x 1194 x 473La profondeur dépend du choix de la table XY et du banc laser (en option).
Cette valeur correspond à une table de 100 x 100 mm et au banc laser de Classe IIIb - sans CDRH (optionnel).
Poids~100 kgDépend de la configuration.
SécuritéClasse IIIbEn option, laser avec CDRH, sécurité de classe 1.
Multimodal spectroscopy techniques for nanostructured materials characterization
Multimodal spectroscopy techniques for nanostructured materials characterization
In this article, we present the combination of Raman spectroscopy, Photoluminescence and SEM-CL techniques, where the instruments weren’t physically connected. Smart nanostructured materials require a comprehensive understanding of their morphology, elemental and chemical composition. nanoGPS Suite solution allows a colocalized combination of a variety of microscopy techniques, providing a full characterization of nanostructured materials and a precise superimposition of the results obtained.
Quality control of sugar content in beverages using Raman spectroscopy
Quality control of sugar content in beverages using Raman spectroscopy
We all consume or have all consumed sugary drinks at least once. Sugar content of those drinks must be regulated. Also, to avoid those properties of sugar, it has been replaced by sweeteners. These have lower sweetness than natural sugars. Whether it is sugar or sweetener, their content just be controlled. Here, we demonstrate that Raman spectroscopy is one solution to identify and evaluate sugar/sweetener concentrations in a quality control process.
Quality control of hand sanitizer gels and 70% alcohol products using Raman spectroscopy
Quality control of hand sanitizer gels and 70% alcohol products using Raman spectroscopy
Disinfecting your hands with hydroalcoholic gel has become a daily practice. In the meanwhile, 70° alcohol has been used for even longer to disinfect wounds. But, to remain efficient, the alcohol concentration of these products must not be below a defined threshold and must be controlled. This application note demonstrates how to evaluate alcohol concentrations in a quality control process with Raman.
Co-localized microscopy techniques for pyrite mineral spatial characterization
Co-localized microscopy techniques for pyrite mineral spatial characterization
In this study we have chosen to investigate pyrite and its surrounding minerals in order to identify the different mineral phases as well as the chemical variations from micro- to nano-scale. Using the different microscopes instruments and being co-localized allows a comprehensive characterization of the sample and a precise superimposition of all the images.
Proton Exchange Membrane Fuel Cell Bipolar Plate Analyses by GD-OES and Raman
Proton Exchange Membrane Fuel Cell Bipolar Plate Analyses by GD-OES and Raman
Bipolar plates are key components of proton exchange membrane fuel cells – they notably distribute fuel gas and air and conduct electricity. Various materials and surface treatments have been developed to improve their properties. Here, we described a reverse engineering study on a bipolar plate from a commercial vehicle using GD-OES and Raman spectroscopy. The analyses revealed that the plate had an amorphous carbon coating on a titanium base plate.
Pigment identification of an old Japanese flag “Hinomaru” using micro-XRF and Raman microscopy
Pigment identification of an old Japanese flag “Hinomaru” using micro-XRF and Raman microscopy
This application note introduces pigment identification using micro-XRF and Raman microscopy on a Japanese flag “Hinomaru”, which is presumed to be the oldest and designed by an ancient Japanese Emperor Go-Daigo. The two spectroscopic analyses identified that the red pigment used on the flag matched the cinnabar ore (Mercury(II) sulfide) mined from the Mine near the place where the Emperor lived.
Three Dimensional Raman Imaging
Three Dimensional Raman Imaging
Segmented channel waveguides have been fabricated in single crystal KTiOPO4 through a topotactic process of partial cation exchange. The ion-exchanged waveguides maintain the high nonlinear susceptibility of KTiOPO4 to function as frequency doubling laser light sources. We apply three dimensional (3D) Raman imaging to understand and characterize the changes to the chemical bonding and crystalline structure as well as measure the volumetric structure of the waveguide segments.
Raman Microscopy Applied to Polymer Characterization: An Overview
Raman Microscopy Applied to Polymer Characterization: An Overview
Raman microscopy is an excellent tool to address the polymer research. Raman microscopy can be used to characterize raw materials, to inline or outline monitor polymerization process, to investigate orientation and crystallization changes, and also to control the quality and traceability of genuine products, by understanding defects and compounds distribution. In this article we present how HORIBA Raman microscopy solutions can support the polymer chemical and structural understanding.
Milk compounds characterization by optical spectroscopies and laser diffraction
Milk compounds characterization by optical spectroscopies and laser diffraction
In the food industry, the compounds characterization is a critical step to ensure the quality of the products or to provide information to customers which can be sensitive to allergies. In this application note, we showed how optical spectroscopies and laser diffraction can help for food compounds characterization, especially on a specific product, i.e. milks.
Morphological and chemical characterizations of microplastic particles using ParticleFinderTM and Raman techniques
Morphological and chemical characterizations of microplastic particles using ParticleFinderTM and Raman techniques
The assessment of microplastics in a marine environment is a multi-step process (sampling, extraction, detection and quantification of microplastics), in which each step is time consuming. Analyzing the chemical composition and morphology of microplastics represents a real challenge for answering crucial questions about the sources and fate of microplastics in aquatic environments. In this application note, we present a reproducible and time-effective method for fast and thorough morphological and chemical characterization of microplastics using a semi-automated scanning of particles coupled to micro-Raman spectroscopy. The rapid analysis of large number of collected particles allows for an exhaustive assessment of both large sample sizes and small subsamples.
Valuable analysis tool for cosmetics and skin characterization
Valuable analysis tool for cosmetics and skin characterization
Confocal Raman Spectroscopy is an important analytical tool in various fields and it has shown high efficiency for specific applications in the cosmetic and/or pharmaceutical fields. Its non-invasive behavior, and its high molecular sensitivity make it one of the preferred label-free analytical techniques to characterize materials such as skin and cosmetic products.
Confocal Raman microspectrometry imaging combined with chemometric methods
Confocal Raman microspectrometry imaging combined with chemometric methods
The non destructive and in-situ identification of different black inks using Raman Spectroscopy
The non destructive and in-situ identification of different black inks using Raman Spectroscopy
The use of security features, such as luminescent inks, has increased significantly in an attempt to prevent fraud and counterfeiting of materials and goods. Obvious applications of these inks include banknotes, branded goods, drug packaging and food security. Security inks can either show up overtly or be covert, with the latter driving the luminescence further from the visible spectral region into the ultraviolet (UV) and near infrared (NIR) regions. These are regions where light sources are not so common. The use of the luminescence lifetime on top of the wavelength signature adds an extra parameter that can be interrogated.
Strain Measurements of a Si Cap Layer Deposited on a SiGe Substrate, Determination of Ge Content
Strain Measurements of a Si Cap Layer Deposited on a SiGe Substrate, Determination of Ge Content
Raman spectroscopy is a very well suited technique to determine both Ge fraction and strain in SiGe layers and Si cap layers. Moreover the possibility of using both UV and visible excitation lines on the same instrument is essential to study structures made up of a Silicon cap layer on top of a SiGe layer. The relative Ge content in the constant Si1-xGex layer is calculated from the visible Raman spectrum and the strain of the cap Si layer is derived from the UV Raman spectrum.
Concentration Profile Measurements in Polymeric Coatings During Drying by Means of Inverse-Micro-Raman-Spectroscopy
Concentration Profile Measurements in Polymeric Coatings During Drying by Means of Inverse-Micro-Raman-Spectroscopy
The coupling of the power of confocal Raman microscopy to the inverted sampling geometry has enabled detailed investigations to be made of solvent and water based coating systems, providing important information on the processes and chemistry that occurs at the coating interface and within.
Raman Imaging of a Single Gallium Nitride Nanowire: Pushing the Limits of Confocal Microscopy
Raman Imaging of a Single Gallium Nitride Nanowire: Pushing the Limits of Confocal Microscopy
We have performed a complete Raman polarized study of a single GaN nanowire using a confocal microscope together with a high resolution stage. The high spatial resolution of our Raman confocal instrument together with a piezoelectric stage demonstrates unambiguously the possibility to image the optical properties of nano-objects with a resolution better than 200 nm keeping the fill advantage of the polarization control under a confocal microscope.
Raman Mapping of Wheat Grain Kernels
Raman Mapping of Wheat Grain Kernels
Raman analysis of a 50 μm section of a wheat grain kernel has allowed spectral features corresponding to starch, lipid and proteins to be identified. The distribution of these components on the micron scale has been studied using a Raman mapped image. Decomposition of the Amide I band allows a correlation between protein structures and grain hardness.
Real-time Monitoring of Polymerisations in Emulsions by Raman Spectroscopy - Modelling and Chemometrics
Real-time Monitoring of Polymerisations in Emulsions by Raman Spectroscopy - Modelling and Chemometrics
Raman spectra, in conjunction with Multivariate (Chemometric) Analysis, have been demonstrated to provide real-time information on the progress of a polymerisation reaction. As shown by this example, these results can provide unexpected information on the details of the reaction. in this case, the inequivalent reaction rates of the two monomers. Such information ultimately enables the process engineer to optimise his process.
What’s Protecting Your Mobile Screen? A Depth Profile of Polymer Protection Covers Using Raman and UFS-GDOES
What’s Protecting Your Mobile Screen? A Depth Profile of Polymer Protection Covers Using Raman and UFS-GDOES
Pulsed RF Glow Discharge Optical Emission Spectrometry, coupled with the Ultra Fast Sputtering system, offers the Ultra Fast Elemental Depth Profiling of plastic thin films Polymer Mobile Screen Protection Covers. By coupling this technique with the Raman spectroscopy z-Scan analysis it is possible to acquire important information concerning the fabrication of smartphone screen protectors.
Using Chemometrics and Raman Spectra for Quantitative Predictions of Physical and Chemical Properties of Polymers
Using Chemometrics and Raman Spectra for Quantitative Predictions of Physical and Chemical Properties of Polymers
As far as polymeric fibres are concerned, slight modifications of Raman features are directly related to differences in the molecular orientation and the degree of crystallinity of the fibres. To utilize these subtle spectral changes and correlate them with physical properties of the polymer, one is obliged to use Chemometrics on the Raman spectra. The resulting synergism between Raman spectroscopy and Chemometrics will provide a powerful tool for monitoring and control of manufacturing of polymeric materials.
Transmission Raman Spectroscopy: Review of Applications
Transmission Raman Spectroscopy: Review of Applications
The transmission design has demonstrated to be the technique of choice whenever Raman spectral information of a bulk material is required. It has already proven its utility for pharmaceutical applications, as tablets or even powder mixtures are good candidates for this measurement mode. However, transmission Raman might be applied successfully to other sample types, such as polymers, bio-tissues or any translucent material, and can be envisaged for evaluating the content of product inside a package. In addition, as TRS provides a global spectral information of the measured sample, it will be a technique of choice when quantitative evaluation of mixtures is needed.
Raman Imaging of Holographic Gratings Inscribed on Polymer Thin Films
Raman Imaging of Holographic Gratings Inscribed on Polymer Thin Films
Using holographic techniques we have structured the surface in a one step procedure (no wet nor photocuring processing ) along the X and Y directions. A grating is first inscribed with grooves along the X direction, the sample is rotated by 90° and a second grating is inscribed with grooves along the Y direction. The intensity of the 1st diffracted orders is monitored to have equal intensities in both X and Y directions.
Raman Characterization of Polymers in Industrial Applications
Raman Characterization of Polymers in Industrial Applications
Recent developments in Raman instrumentation have made the technique easier to use, more compact, and more affordable. Consequently, all of the demonstrated potential of the spectroscopy for industrial uses can now be exploited, including its use in combination with statistical methods for concentration calibrations.
Localisation of Polymeric Phases by Raman Microscopy Mapping Components of a Blend in a Plane and Depth Profiles of Laminated Film
Localisation of Polymeric Phases by Raman Microscopy Mapping Components of a Blend in a Plane and Depth Profiles of Laminated Film
Blending, an alternative method for engineering products that combines the properties of polymer types is a physical mixing. It has the advantage of being not only simple and inexpensive, but also allows for re-cycling used material. Incompatibility or non-miscibility of the differing chemical components is often an issue in the final performance of the polymer product. The first part of this note concerns the dispersion of the two components in a polyethylene-polybutylene terephthalate blend. The chemical imaging capabilities of the LabRAM are used to get this information. The second part deals with the depth analysis of laminated films made of different polymer layers.
Raman and PL Characterization of GaN
Raman and PL Characterization of GaN
Gallium Nitride (GaN) is one of a generation of promising light-emitting materials. Its direct energy band gap of ~3.4 eV at room temperature make it particularly suitable for emission in the blue, and near UV spectral ranges. The material often exhibits high temperature stability and low electrical leakage, and hence GaN is generally a good candidate for fabricating high-temperature and high-power devices.
Observing Oxidating Kinetics on an aluminium alloy surface with Fluorescence mapping
Observing Oxidating Kinetics on an aluminium alloy surface with Fluorescence mapping
Characterization of MoS2 Flakes using TEOS
Characterization of MoS2 Flakes using TEOS
Both TEPL and TERS images are well correlated with AFM morphological images obtained simultaneously, and all are consistent in revealing the nature (number of layers) of MoS2 flakes. Upon deconvolution, the TEPL signal is even capable of revealing local inhomogeneities within a MoS2 flake of 100 nm size. Kelvin probe measurement supports TEPL and TERS measurements and adds to the power of such tip-enhanced combinative tools. TEOS characterization of 2D materials is likely to contribute to further deployment of these materials into commercial products through a better understanding of their electrical and chemical properties at the nanoscale.
Combined Raman and Photoluminescence Imaging of 2D WS2
Combined Raman and Photoluminescence Imaging of 2D WS2
Raman and photoluminescence spectroscopy reveal different aspects of the solid state structure of 2D materials. Raman and photoluminescence imaging performed simultaneously with one instrument reveals the spatial variation of the solid state structure and electronic properties of 2D crystals that is not revealed in reflected white light imaging. That ability should allow materials scientists to better design and fabricate electronic and optoelectronic devices based upon 2D crystals.
Characterization of Carbon Nanotubes Using Tip-Enhanced Raman Spectroscopy (TERS)
Characterization of Carbon Nanotubes Using Tip-Enhanced Raman Spectroscopy (TERS)
The use of TERS to reveal the defects density in the structure of CNTs is of interest for a better understanding of the electrical properties of the devices made with such nano-objects. Not only defects concentration but also local chirality changes from the different radial breathing modes, pressure effect and strain distribution can be studied at the single carbon nanotube level through TERS.
Number of Layers of MoS2 Determined Using Raman Spectroscopy
Number of Layers of MoS2 Determined Using Raman Spectroscopy
The two methods - Analysis of fingerprint modes (intralayer) and Analysis of low-frequency modes (interlayer) - give complementary results and allow the determination of the number of MoS2 layers. Method 2 (using low frequency modes) gives excellent contrast; however it does not show single layer regions (which is related to the nature of the modes, rising from interaction between at least two layers). Method 1 (using fingerprint modes) shows all the layers, but the contrast is poorer, particularly for higher numbers of layers. The best result can be obtained combining the two methods. All the measurements (low-frequency and fingerprint) were done using ultra-low frequency ULFTM filters which allow a high throughput measurement in a full Raman range, down to <10 cm-1.
SWNT Quality Control by Raman Spectroscopy
SWNT Quality Control by Raman Spectroscopy
Raman has shown a high potential in characterising the SWCNTs' structure. The correlation between knowledge about structure with physical and chemical properties about the tubes make the technique extremely powerful to control the quality of the SWCNTs for specific applications. Raman spectrometer capabilities like spatial resolution, spectral resolution and excitation wavelength versatility have been examined. Beside Raman, preliminary fluorescence studies are describing the potential of the technique.
Impact of Raman Spectroscopy on Technologically Important Forms of Elemental Carbon
Impact of Raman Spectroscopy on Technologically Important Forms of Elemental Carbon
The Raman spectra of the various forms of elemental carbon are very sensitive to the type of nearest neighbour bonding, and to intermediate and long range order. In many cases Raman spectroscopy is the technique of choice for characterization of carbon materials. Correlation of Raman spectral features with tribological properties can facilitate the deposition of carbon films.
Graphene Studies using Raman Spectroscopy
Graphene Studies using Raman Spectroscopy
Graphene is a new nanomaterial which may partially replace silicon in microcircuits and computer chips in the future. In order to better understand its quality characteristics, fast reliable techniques that deliver the right property measures are needed. Raman spectroscopy has emerged as a key technique for studying this exceptional material.
Derivation of Physical Parameters from Raman Spectra of Hard Carbon Films
Derivation of Physical Parameters from Raman Spectra of Hard Carbon Films
The Raman spectra of elemental carbon materials are known to be sensitive to polymorphy. For hard carbon films, the spectra of amorphous and diamond-like carbons can be band-fit to separate the contributions of the "graphitic carbon" (G band) from the "disordered carbon" (D band). The spectral behaviour of carbon films has been empirically correlated with thin film physical properties such as hardness, durability, optical transparency, electrical conductivity, thermal conductivity and corrosion resistance, and can be of use for prediction of these properties without extensive alternative testing. The DiskRam has been designed to automate the collection of Raman spectra from hard carbon coatings on computer hard disk media and the extraction of parameters that are well correlated with the properties of the films. The extracted information is output in spreadsheet format for SPC at a manufacturing facility.
Coloured Diamond Defect Identification by Raman Diffusion and Photoluminescence
Coloured Diamond Defect Identification by Raman Diffusion and Photoluminescence
The colour enhancement treatment on native brown and yellow diamonds can be highlighted by Photoluminescence analyses performed with the Raman spectrometer LabRAM HR. The PL signature of green and violet diamonds has also been recorded. The defect centres responsible of the colour of the diamonds have all been detected and assigned. This proves the Raman spectrometer to be a very good tool to investigate the fine defects in the Diamond structure by Photoluminescence analysis.
Characterization and mapping of active pharmaceutical ingredients and excipients in a tablet using Raman and IR spectroscopy
Characterization and mapping of active pharmaceutical ingredients and excipients in a tablet using Raman and IR spectroscopy
Microscopic Measurement of Diffusion
Microscopic Measurement of Diffusion
In order to engineer materials with controlled diffusive properties, we need to be able to measure the diffusive process in situ. Ideally, we would like a technique that provides molecular information with resolution on a microscopic scale, that is non destructive of the samples, and can be set up and used on a laboratory bench top with a minimum of time and effort involved in sample preparation. Raman microprobe spectroscopy is an ideal candidate for this type of studies. Use of visible light combined with a confocal microscope provides a probe with spatial resolution of a micron or better, and coupling of such a microscope to a modern Raman spectrometer equipped with holographic notch filters and CCD multi channel detectors allows rapid acquisition of Raman spectra which can be correlated with the chemical state of the species and its physical environment.
Raman Microscopy in Pharmaceutical Salt Analysis
Raman Microscopy in Pharmaceutical Salt Analysis
Pharmaceutical and crystallographic samples typically require detailed characterization and analysis to optimize a samples stability, physical properties and indeed general efficacy where an active drug substance is involved.
Investigating the atherosclerosis process by monitoring lipid deposits including cholesterol and free fatty acids
Investigating the atherosclerosis process by monitoring lipid deposits including cholesterol and free fatty acids
In Vivo Raman measurements of Human Skin
In Vivo Raman measurements of Human Skin
Confocal Raman spectroscopy is beginning to be recognized as a high potential technique for the non invasive study of biological tissues and human skin under in vivo conditions. Raman spectroscopy can be applied to obtain information regarding the molecular composition of the skin down to several hundred micrometers below the skin surface.
Raman Analysis of Sperm Nuclear DNA Integrity
Raman Analysis of Sperm Nuclear DNA Integrity
Raman Spectroscopy was evaluated as a non-invasive method of analysis of sperm DNA and the influence of UV irradiation on the sperm. The results show that Raman Spectroscopy, combined with multivariate analysis provide the reproducible and accurate information on DNA of sperm and the effect and location of damage.
Raman Imaging of monkey brain tissue
Raman Imaging of monkey brain tissue
Fast and non-invasive methods for clinical and non clinical investigations for biological tissue are more and more required. Raman imaging at micro scale can answer to crucial questions about the monkey brain tissue morphology and structural evolution.
Raman and Resonance Raman Spectroscopy of Enzymes
Raman and Resonance Raman Spectroscopy of Enzymes
The TRIAX and iHR series spectrometers used in Raman system configurations provide superior imaging performance with no re-diffracted light and maximized optical throughput.
Raman Investigation of Micro-organisms on a single cell level
Raman Investigation of Micro-organisms on a single cell level
Raman Analysis of Single Bacteria Cells
Raman Analysis of Single Bacteria Cells
Traditionally, Raman has been a technique of the material scientist, physicist or chemist, but as instrumentation continues to evolve, the power of Raman in biological and medical applications is fast being realized, not least because of the high information content provided and an excellent tolerance for water.
Direct identification of clinically relevant microorganisms
Direct identification of clinically relevant microorganisms
Insights into thrombosis mechanisms using high resolution SERS
Insights into thrombosis mechanisms using high resolution SERS
Raman Spectroscopy Applied to the Lithium-ion Battery Analysis
Raman Spectroscopy Applied to the Lithium-ion Battery Analysis
The application note explains how the Raman Spectroscopy can be helpful in the analysis of cathodes and anodes in Li-ion batteries. Today’s state of art of technology requires more reliable, more efficient and powerful energy sources. Lithium-ion batteries are thus of high interest. Raman spectroscopy adapts to the different stages of life of these batteries, such as the characterization of new materials for more flexible systems, failure analysis; but also more standard analysis of used material during charge/discharge process, including structural and electronic properties, and even robust, automated QC tests.

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Accessoires du produit

CaptuR
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Laser Trapping Solution - Raman Accessory for Life Science

DuoScan™ Macro and Sub-Micron Raman Mapping
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Fast Feed Back Auto Focus
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LabSpec 6 Spectroscopy Suite Software
LabSpec 6 Spectroscopy Suite Software

Profitez d'une expérience utilisateur exceptionnelle grâce aux fonctionnalités uniques du logiciel d'imagerie et de spectroscopie Labspec 6

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Fiber probes: High Efficiency Raman sensors

XD-100
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Versatile Hyperspectral Cathodoluminescence

iHR Series
iHR Series

Mid-Focal Length Imaging Spectrometers

LabRAM Odyssey
LabRAM Odyssey

Imagerie Confocale Raman et Spectromètre à Haute Résolution

LabRAM Odyssey Nano
LabRAM Odyssey Nano

AFM-Raman pour l'imagerie physique et chimique

LabRAM Soleil
LabRAM Soleil

Microscope Confocal Multimodal Raman

LabRAM Soleil Nano
LabRAM Soleil Nano

Nanoscopie corrélative directe en temps réel

Logiciel GDOES
Logiciel GDOES

Quantum et Image

MultiWell Module
MultiWell Module

Expériences de criblage chimique à haut rendement

MVAPlus
MVAPlus

Application d'analyse multivariée pour toutes les cartographies Raman

nanoGPS navYX
nanoGPS navYX

Microscopie corrélative collaborative

OmegaScope
OmegaScope

Plateforme optique AFM

Smart SE
Smart SE

Powerful and Cost Effective Spectroscopic Ellipsometer

Synapse InGaAs/Symphony II InGaAs
Synapse InGaAs/Symphony II InGaAs

Deep Cooled NIR Scientific Cameras

Triax Series
Triax Series

Short Focal Length Triple Grating Imaging Spectrographs

TRIOS
TRIOS

Couplage optique AFM polyvalent

UVISEL Plus
UVISEL Plus

Spectroscopic Ellipsometer from FUV to NIR: 190 to 2100 nm

XGT-9000
XGT-9000

Microscope d'analyse X (Micro-XRF)

XploRA Nano
XploRA Nano

AFM-Raman pour l'imagerie physique et chimique

XploRA™ PLUS
XploRA™ PLUS

Spectromètre Raman – Microscope confocal Raman

DeltaFlex
DeltaFlex

TCSPC/MCS Fluorescence Lifetime System

DeltaPro
DeltaPro

TCSPC Lifetime Fluorometer

Duetta
Duetta

Fluorescence and Absorbance Spectrometer

FluoroMax Plus
FluoroMax Plus

Steady State and Lifetime Benchtop Spectrofluorometer

LabRAM Odyssey
LabRAM Odyssey

Imagerie Confocale Raman et Spectromètre à Haute Résolution

LabRAM Odyssey Nano
LabRAM Odyssey Nano

AFM-Raman pour l'imagerie physique et chimique

LabRAM Odyssey Semiconductor
LabRAM Odyssey Semiconductor

Cartographie Raman et Photoluminescence de wafers

LabRAM Soleil
LabRAM Soleil

Microscope Confocal Multimodal Raman

LabRAM Soleil Nano
LabRAM Soleil Nano

Nanoscopie corrélative directe en temps réel

MacroRAM™
MacroRAM™

Spectromètre Raman de paillasse abordable

MicOS
MicOS

Photoluminescence Microspectrometer

Microscope Raman modulaire
Microscope Raman modulaire

Système Raman Polyvalent

nanoGPS navYX
nanoGPS navYX

Microscopie corrélative collaborative

Nanolog
Nanolog

Steady State and Lifetime Nanotechnology EEM Spectrofluorometer

ProteusQ
ProteusQ

Scanning NV Magnetometry

Raman Spectrometer - MINI-CCT+
Raman Spectrometer - MINI-CCT+

MINI-CCT+ Mini Raman Spectrometer

Sondes à fibre Raman
Sondes à fibre Raman

Spectromètres Raman

Sondes Raman miniatures OEM
Sondes Raman miniatures OEM

Systèmes et composants Raman miniatures OEM

Spectrographe HE
Spectrographe HE

Spectromètre Raman haute efficacité dédié pour un suivi Raman des procédés

Spectromètre Raman térahertz modulaire
Spectromètre Raman térahertz modulaire

Spectromètre Raman abordable à ultra-basse fréquence, jusqu'à 10 cm-1

Spectromètre Raman UV
Spectromètre Raman UV

pour les spectroscopistes Raman UV

XploRA Nano
XploRA Nano

AFM-Raman pour l'imagerie physique et chimique

XploRA™ PLUS
XploRA™ PLUS

Spectromètre Raman – Microscope confocal Raman

Corporate