| NANOMATERIALS. ELECTROCHEMICAL REAGENTS. |
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Multi-Walled Nanotubes produced through CVD (Chemical Vapor Deposition). Also functionalized with -COOH and -NH2 groups. Suitable for mechanical and electrical applications.
Gold Nanoparticles, Palladium Nanoparticles, Platinum Nanoparticles, Nickel Nanowires and Gold Nanowires produced via electrochemical deposition in an alumina template
and Quantum Dots.
Different solutions: Carbon Nanofibres Solution, Carbon Nanotubes Solution, Graphene Solution, Graphene Oxide Solution, Aqueous Graphene Oxide Solution and Mesoporous Carbon Solution.
Also p-AminoPhenyl Phosphate, Hydroquinone Diphosphate and Phosphorylated Paracetamol: electrochemical substrates of Alkaline Phosphatase.
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| QUANTUM DOTS |
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QDCORE
QDCORESHELL |
 MSDS |
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Quantum Dots
Quantum Dots are nanocrystals of inorganic semiconductors that have all three dimensions restricted to the 2 to 8 nm length scale. Core CdSe and core/shell CdSe/ZnS are produced via chemical synthesis at high temperature in organic solvent.
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| QDCORESHELL-575-STR-AQU |
| MSDS |
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Quantum Dots modified with streptavidin
These fluorescent nanoparticles covalently functionalized with biotin-binding proteins, are an excellent option for the detection of a large amount of biotinylated molecules, in a wide range of experiments, such as electrochemical (bio)assays, optical (bio)assays, western blot protocols, flow cytometry, and more.
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| QDCORESHELL-585-AQU |
| QDCORESHELL-615-AQU |
| MSDS |
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Quantum Dots in aqueous solution
This aqueous soluble fluorescent nanocrystals presents carboxyl groups in the free end which make them very interesting nanoparticles for conjugation procedures through the covalent attachment of amine groups of proteins, amine-modified oligonucleotides, or others.
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| GQD |
| MSDS |
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Graphene Quantum Dots in aqueous solution
Aqueous soluble fluorescent nanoparticles exhibit extraordinary optical and electronic properties. Graphene Quantum Dots are characterized by their chemical inertness and biocompatibility, high fluorescent activity and photostability.
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| MESOPOROUS CARBON SOLUTION |
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| MCSOL |
| MSDS |
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Mesoporous Carbon Solution
Mesoporous Carbon Solution is a homogeneous, black solution with a high purity of mesoporous carbon nanopowder. Carbon nanoparticles have a surface area >200 m2/g and 64 Å of average pore diameter.
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| CARBON NANOFIBRES SOLUTION |
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| CNFSOL |
| MSDS |
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Carbon Nanofibres Solution
They are produced via the catalytic carbon vapour deposition process. The manufacturing processes provide a highly graphitized material without amorphous carbon. Nanofibres present in solution have an average diameter of 40-80 nm and an average length varying from 0.5 to 1.5 µm. Most of the nanofibres have helicoidal structure.
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| CARBON NANOTUBES SOLUTION |
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| CNTSOL |
| MSDS |
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Carbon Nanotubes Solution
Carbon nanotubes are produced via CVD and purified to remove free amorphous carbon deposits and catalyst metallic particles. They are functionalized with -COOH groups.
Volume: 0,5 ml - 1 ml |
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| GRAPHENE SOLUTION |
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| GPHSOL |
| MSDS |
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Graphene Solution
Graphene is a two dimensional sheet of sp2-bonded carbon atoms tightly
packed into a hexagonal configuration. Graphene possesses exceptional properties, such as large surface area and high electrical and thermal conductivity, which made it of significant interest in electrochemistry.
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| GRAPHENE OXIDE SOLUTION |
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| GPHOXSOL |
| MSDS |
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Graphene Oxide Solution
Graphene Oxide Solution, based in the modification of the Hummer's Method specially designed for electrode modification providing an enhanced electrochemical active area and improved electronic transfer properties. |
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| AQUEOUS GRAPHENE OXIDE SOLUTION |
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GPHOXSOL-AQU |
| MSDS |
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Aqueous Graphene Oxide Solution
Aqueous graphene Oxide Solution, based in the modification of the Hummer's Method specially designed for electrode modification providing an enhanced electrochemical active area and improved electronic transfer properties. |
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| MULTI-WALLED CARBON NANOTUBES |
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MWCNT
MWCNTCOOH |
| MSDS |
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Multi-Walled Carbon Nanotubes
Multiwalled carbon nanotubes grown by CVD process.
They are purified to more than 95% C. Approximate dimensions are d: 10 nm, L: 1-2 µm. Optimum for electronic, mechanical or analytic applications.
DropSens offers non-functionalised nanotubes (ref. MWCNT), functionalised with –NH2 groups (ref. MWCNTNH2; approx. 0,5% functionalisation) and functionalised with –COOH groups (ref. MWCNTCOOH; approx. 5% functionalisation) to modify their surface chemistry characteristics and to ease their dispersion in solvents.
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| GRAPHENE OXIDE |
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| GPHOX |
| MSDS |
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Graphene oxide
Graphene oxide has been prepared by a modification of the Hummer's method. This yields a material with a significant number of oxygen-containing functional groups which assures homogeneous colloidal suspensions in polar solvents without addition of any surfactant. Different applications are solar energy, conductive films, nonvolatil memory technology…
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| GOLD NANOPARTICLES |
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AUNP-COL
AUNP-PUR |
| MSDS |
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Gold Nanoparticles
Gold Nanoparticles are produced through colloidal synthesis methods, reducing a metal salt precursor in a solution and with the present of a stabilizer agent. Colloidal nanospheres Nanoparticles can be later purified and concentrated removing any stabilizing agent.
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| PALLADIUM NANOPARTICLES |
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PDNP-COL
PDNP-PUR |
| MSDS |
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Palladium Nanoparticles
Palladium Nanoparticles are produced through colloidal synthesis methods, reducing a metal salt precursor in a solution and with the present of a stabilizer agent. Colloidal nanospheres Nanoparticles can be later purified and concentrated removing any stabilizing agent.
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| PLATINUM NANOPARTICLES |
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PTNP-COL
PTNP-PUR |
| MSDS |
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Platinum Nanoparticles
Platinum Nanoparticles are produced through colloidal synthesis methods, reducing a metal salt precursor in a solution and with the present of a stabilizer agent. Colloidal nanospheres Nanoparticles can be later purified and concentrated removing any stabilizing agent.
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| RHODIUM NANOPARTICLES |
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RHNP-COL |
| MSDS |
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Rhodium Nanoparticles
Rhodium Nanoparticles are produced through colloidal synthesis methods, reducing a metal salt precursor in a solution and with the presence of a stabilizer agent. This stabilized dispersion in citrate has a narrow size distribution and it is ready to be used.
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| BISMUTH NANOPARTICLES |
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BINP-PUR |
| MSDS |
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Bismuth Nanoparticles
Bismuth Nanoparticles are produced through colloidal synthesis methods, reducing a metal salt precursor in a solution and with the presence of a stabilizer agent. They are later purified and concentrated removing any stabilizing agent and dispersed in acetone.
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| TIN NANOPARTICLES PURIFIED |
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SNNP-PUR |
| MSDS |
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Tin nanoparticles purified
Tin Nanoparticles are produced through colloidal synthesis methods, reducing a metal salt precursor in a solution and with the presence of a stabilizer agent. They are later purified and concentrated removing any stabilizing agent and dispersed in acetone.
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| COPPER NANOPARTICLES PURIFIED |
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CUNP-PUR |
| MSDS |
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Copper nanoparticles purified
Cupper Nanoparticles are produced through colloidal synthesis methods, reducing a metal salt precursor in a solution and with the presence of a stabilizer agent. They are later purified and concentrated removing any stabilizing agent and dispersed in acetone.
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| ANTIMONY NANOPARTICLES PURIFIED |
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SBNP-PUR |
| MSDS |
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Antimony nanoparticles purified
Antimony Nanoparticles are produced through colloidal synthesis methods, are produced through colloidal synthesis methods, reducing a metal salt precursor in a solution and with the presence of a stabilizer agent. They are later purified and concentrated removing any stabilizing agent and dispersed in acetone.
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| IRIDIUM NANOPARTICLES |
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IRNP-COL |
| MSDS |
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Iridium nanoparticles purified
Iridium Nanoparticlesare produced through colloidal synthesis methods, reducing a metal salt precursor in a solution and with the presence of a stabilizer agent. This stabilized dispersion in citrate has a narrow size distribution and it is ready to be used.
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| NICKEL NANOWIRES |
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| NINW |
| MSDS |
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Nickel Nanowires
Nickel Nanowires are produced via the electrochemical deposition in an alumina template. After dissolving the alumina, purified metal nanowires are obtained. Our magnetic Nickel Nanowires have an average diameter of 150-250 nm and an average length that can be tuned from 6 to 8 µm.
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| STREPTAVIDIN COATED NICKEL NANOWIRES |
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| NINW-STR |
| MSDS |
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Streptavidin-modified Nickel Nanowires
Streptavidin-modified nickel nanowires (NiNW-STR) are an excellent option for the immobilization of a large amount of biotinylated molecules. Due to the extraordinary ferromagnetic properties of nickel, DRP-NINW-STR is a perfect candidate to be use in magnet-based (bio)assays.
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| GOLD NANOWIRES |
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| AUNW |
| MSDS |
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Gold Nanowires
Gold Nanowires are produced via the electrochemical deposition in an alumina template. After dissolving the alumina, purified metal nanowires are obtained. Our Gold Nanowires have an average diameter of 150-250 nm and an average length varying in two ranges: 2- 6 µm or 12-18 µm. |
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| PALLADIUM NANOWIRES |
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| PDNW |
| MSDS |
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Palladium Nanowires
Palladium Nanowires are produced via the electrochemical deposition on an alumina template. After dissolving the alumina, purified metal nanowires are obtained. Our Palladium Nanowires have an average diameter of 150-250 nm and an average length of 10-16 µm. |
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| PLATINUM NANOWIRES |
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| PTNW |
| MSDS |
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Platinum Nanowires
Platinum Nanowires are produced via the electrochemical deposition on an alumina template. After dissolving the alumina, purified metal nanowires are obtained. Our Platinum Nanowires have an average diameter of 150-250 nm and an average length of 10-16 µm. |
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| SILVER NANOWIRES |
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| AGNW |
| MSDS |
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Silver Nanowires
Silver Nanowires are produced via the electrochemical deposition in an alumina template. After dissolving the alumina, purified metal nanowires are obtained. Our Silver Nanowires have an average diameter of 150-250 nm and an average length varying in two ranges: 6-9 µm or 12-18 µm. |
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| PLATINUM-GOLD-NICKEL NANOWIRES |
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| PTAUNINW |
| MSDS |
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Platinum-Gold-Nickel Nanowires
Platinum-gold-nickel (Pt-Au-Ni) Nanowires are produced via the electrochemical deposition on an alumina template. After dissolving the alumina, purified three-metal nanowires are obtained. Our Pt-Au-Ni Nanowires have an average diameter of 150-250 nm and an average length varying in two ranges: Pt (1.5 µm) - Au (5 µm) - Ni (2 µm) or Pt (1.5 µm) - Au (2 µm) - Ni (2 µm).
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| p-AMINOPHENYL PHOSPHATE |
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| PAPP |
| MSDS |
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p-AminoPhenyl Phosphate
This electrochemical substrate of Alkaline Phosphatase (AP) generates electrochemically active p -aminophenol as the product after its hydrolysis. Voltammetric and amperometric measurements can be easily carried out for the quantification of p -aminophenol in affinity assays using the p -APP/AP detection system.
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| HYDROQUINONE DIPHOSPHATE |
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| HQDP |
| MSDS |
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Hydroquinone Diphosphate
Hydroquinone diphosphate is intended for its use as electrochemical substrate of Alkaline Phosphatase (AP). This reagent generates electrochemically active hydroquinone as the product after its hydrolysis. Voltammetric and amperometric measurements can be easily carried out for the quantification of hydroquinone in affinity assays using the HQDP/AP detection system.
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| PHOSPHORYLATED PARACETAMOL |
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| PPAR |
| MSDS |
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Phosphorylated Paracetamol
Phosphorylated Paracetamol is intended for its use as electrochemical substrate of Alkaline Phosphatase (AP). This reagent generates electrochemically active Paracetamol as the product after its hydrolysis. Voltammetric and amperometric measurements can be easily carried out for the quantification of Paracetamol in affinity assays using the PPAR/AP detection system.
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