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| Product | Description | |
|---|---|---|
| DOPE | DOPE (1,2-Dioleoyl-sn-glycero-3-phosphoethanolamine) is a membrane phospholipid emulsifier to improve the transfection of DNA. Synonyms: 18:1 PE; 1,2-Dioleoyl-sn-glycero-3-PE; 1,2-Dioleoyl-sn-glycero-3-Phosphoethanolamine; 1,2-DOPE. Grades: >98.0%(T). CAS No. 4004-5-1. Molecular formula: C41H78NO8P. Mole weight: 744.1. |  |
| DOPE | DOPE (Dioleoylphosphatidylethanolamine) is a neutral helper lipid for cationic liposome and combines with cationic phospholipids to improve transfection efficiency of naked siRNA [1]. Uses: Scientific research. Group: Biochemical assay reagents. Alternative Names: Dioleoylphosphatidylethanolamine; 1,2-Dioleoyl-sn-glycero-3-phosphoethanolamine. CAS No. 4004-5-1. Pack Sizes: 25 mg; 50 mg; 100 mg; 250 mg. Product ID: HY-112005. |  |
| Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Alcohols(DTO), 20wt% | Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Alcohols(DTO), 20wt%. Uses: Heat and ir shielding, antistatic, solar, displays, conductors. Group: Doped nanoparticles. |  |
| Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Alcohols(DTO), 40wt% | Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Alcohols(DTO), 40wt%. Uses: Heat and ir shielding, antistatic, solar, displays, conductors. Group: Doped nanoparticles. | |
| Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Aromatic(DTO), 20wt% | Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Aromatic(DTO), 20wt%. Uses: Heat and ir shielding, antistatic, solar, displays, conductors. Group: Doped nanoparticles. | |
| Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Aromatic(DTO), 40wt% | Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Aromatic(DTO), 40wt%. Uses: Screen technology, electronics, solar, heat and em shielding, conductive coatings. Group: Doped nanoparticles. | |
| Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Water(DTO), 20wt% | Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Water(DTO), 20wt%. Uses: Heat and ir shielding, antistatic, solar, displays, conductors. Group: Doped nanoparticles. | |
| Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Water(DTO), 40wt% | Doped Tin Oxide Nanoparticles/Nanopowder Dispersion in Water(DTO), 40wt%. Uses: Heat and ir shielding, antistatic, solar, displays, conductors. Group: Doped nanoparticles. | |
| Dopentacontane | Dopentacontane. Uses: Designed for use in research and industrial production. Additional or Alternative Names: DOPENTACONTANE;ALKANE C52;N-DOPENTACONTANE;DOPENTACONTANE, STANDARD FOR GC. Product Category: Heterocyclic Organic Compound. CAS No. 7719-79-1. Molecular formula: C52H106. Mole weight: 731.4. Product ID: ACM7719791. Alfa Chemistry ISO 9001:2015 Certified. |  |
| Dopexamine | Dopexamine. Uses: Designed for use in research and industrial production. Additional or Alternative Names: DOPEXAMINE;4-[2-[[6-[(2-Phenylethyl)amino]hexyl]amino]ethyl]-1,2-benzenediol;Dopacard;FPL-60278;FPL-60278AR;4-[2-[[6-(Phenethylamino)hexyl]amino]ethyl]-1,2-benzenediol;1,2-Benzenediol, 4-(2-((6-((2-phenylethyl)amino)hexyl)amino)ethyl)-;86484-91-5 (Di-hyd. Product Category: Heterocyclic Organic Compound. CAS No. 86197-47-9. Molecular formula: C22H32N2O2. Mole weight: 356.507. Product ID: ACM86197479. Alfa Chemistry ISO 9001:2015 Certified. | |
| Dopexamine hydrochloride | Dopexamine hydrochloride is a β2 adrenergic receptor agonist. Uses: Scientific research. Group: Signaling pathways. Alternative Names: FPL60278AR. CAS No. 86484-91-5. Pack Sizes: 10 mM * 1 mL; 5 mg; 10 mg; 25 mg; 50 mg; 100 mg. Product ID: HY-U00205. | |
| Dopexamine Hydrochloride | Dopexamine is a synthetic dopamine analog and acts as a a β2-adrenergic receptor agonistt as well as an agonist at peripheral dopamine receptors. Dopexamine has been used to improve myocardial and renal performance in patients suffering from low cardiac output states. Group: Biochemicals. Alternative Names: 4- [2- [ [6- [ (2-Phenylethyl) amino] hexyl] amino] ethyl] -1, 2-benzenediol Dihydrochloride; Dopacard; Dopexamine Dihydrochloride; FPL 60278AR. Grades: Highly Purified. CAS No. 86484-91-5. Pack Sizes: 10mg. US Biological Life Sciences. |  Worldwide |
| 0.5% NBD-DOPE Encapsulated DC-Chol:DOPE (1:2) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. |  |
| 0.5% NBD-DOPE Encapsulated DC-Chol:DOPE (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% NBD-DOPE Encapsulated DDAB:Chol (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% NBD-DOPE Encapsulated DDAB:DOPE (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% NBD-DOPE Encapsulated DDAB Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% NBD-DOPE Encapsulated DOTAP:Chol (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% NBD-DOPE Encapsulated DOTAP:Chol:DOPE (10:75:5) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% NBD-DOPE Encapsulated DOTAP:DOPE (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% NBD-DOPE Encapsulated DOTMA:Chol (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% NBD-DOPE Encapsulated DOTMA:DOPE (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% NBD-DOPE Encapsulated GL-67:DOPE (1:2) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% Rhod-PE Encapsulated DC-Chol:DOPE (1:2) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% Rhod-PE Encapsulated DC-Chol:DOPE (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% Rhod-PE Encapsulated DDAB:DOPE (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% Rhod-PE Encapsulated DOTAP:Chol:DOPE (10:75:5) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% Rhod-PE Encapsulated DOTAP:DOPE (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% Rhod-PE Encapsulated DOTMA:DOPE (50:50) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 0.5% Rhod-PE Encapsulated GL-67:DOPE (1:2) Liposomes | Cationic liposomes are used for the delivery of genetic materials such as various types of DNA and RNA. In order to capture more plasmid efficiently, the negative charge of pDNA is neutralized with positive charge of cationic lipids due to electrostatic interaction and deliver them into cells. So they are researched for use as delivery vectors in gene therapy. Uses: Cancer research; target delivery. Group: Cationic liposome. Categories: Niosomes, ethosomes, and transfersomes. | |
| 1, 2-Dioleoyl -sn-glycero-3-phosphatidyl ethanolamine (DOPE) | 1, 2-Dioleoyl -sn-glycero-3-phosphatidyl ethanolamine (DOPE) is a synthetic analog of naturally-occurring PE containing 18:1 fatty acids at the sn-1 and sn-2 positions. DOPE can be used as an emulsifier to facilitate DNA-liposome complex transport across membranes. It is used in combination with cationic phospholipids to increase efficiency during DNA transfection studies as a non-viral method of gene delivery. Group: Biochemicals. Grades: Highly Purified. CAS No. 4004-5-1. Pack Sizes: 25mg, 100mg. Molecular Formula: C41H78NO8P, Molecular Weight: 744.03. US Biological Life Sciences. | Worldwide |
| Ag-Doped Antibacterial Agent Nanopowder | Ag-Doped Antibacterial Agent Nanopowder. Group: Doped nanoparticles. 99.9%. | |
| Aluminum doped silica | Aluminum doped silica. Group: Mesoporous materials. | |
| Aluminum doped silica | mesoporous MCM-48, <150 ?m particle size, pore size 3 nm, Cubic pore morphology. Group: Mesoporous materials. |  |
| Aluminum Doped Zinc Oxide (AZO) Sputtering Targets | Aluminum Doped Zinc Oxide (AZO) Sputtering Targets. Group: Sputtering targets. Alternative Names: Aluminum Doped Zinc Oxide (AZO) Sputtering Targets, AZO Sputtering Target, AZO Sputter Target, AZO Target, Aluminum Doped Zinc Oxide Sputtering Target, Aluminum Doped Zinc Oxide Sputter Target, Aluminum Doped Zinc Oxide Target. CAS No. 7783-40-6. 99.99%. | |
| Aluminum-doped zinc oxide ink for inkjet printing | H-DZ01015 semi conductive ink developed for the printed electronics is particularly well suited for OPV and PV. This ink shows great performance on Drop On Demand (DOD) inkjet printers. The use of H-DZ01015 semiconductive ink is greatly improving the devices performances by reducing the roughness of the TCE without a negative impact on the electrical conductivity and the transparency. Life time of the devices is also increased. The use of H-DZ01015 provides ETL layer with high performances. In addition, compared to standard ETL, the PCE not retained even with higher thickness. Group: 3d printing materials organic solar cell (opv) materials printed electronic materials. Alternative Names: AZO dispersion,AZO ink,Al-doped ZnO ink. Mole weight: ZnO. | |
| Aluminum-doped zinc oxide ink for spin coating/slot-die coating | Helios'Ink H-DZ41006 semiconductive ink developed for the printed electronics is particularly well suited for OPV and PV.This ink shows great performance on spin coating and slot die coating and is compatible with various flexible substrates. Life time of the devices is also increased.The use of Helios'Ink H-DZ41006 provides ETL layer with high performances. In addition, compared to standard ETL, the PCE not retained even with higher thickness. Group: 3d printing materials organic solar cell (opv) materials printed electronic materials. Alternative Names: AZO dispersion, AZO ink, Al-doped ZnO ink. Mole weight: ZnO. | |
| Aluminum-doped Zinc Oxide Nanoparticle Dispersion | Aluminum-doped Zinc Oxide Nanoparticle Dispersion. Uses: Designed for use in research and industrial production. Additional or Alternative Names: AZO, Aluminum Zinc Oxide; dialuminum zinc oxide, AZO dispersion, AZO ink, Al-doped ZnO ink, Al:ZnO ink, Aluminum doped zinc oxide nanoparticle dispersion, Aluminum-doped zinc oxide suspension, Nanograde N-10X. Product Category: Nanoparticle Dispersions. Appearance: Solid in various forms. CAS No. 37275-76-6. Molecular formula: Al2O4Zn. Mole weight: 183.34. Product ID: ACM37275766-1. Alfa Chemistry ISO 9001:2015 Certified. | |
| Aluminum-doped zinc oxide nanoparticle ink | Aluminum-doped zinc oxide nanoparticle ink. Uses: Al-doped zno nanoparticle ink is for screen printing for the use as electron transport layer in printed electronics. al-doped zno nanoparticle ink is universally applicable in normal and inverted architecture with performance comparable to evaporated calcium. Group: 3d printing materials organic solar cell (opv) materials printed electronic materials. Alternative Names: AZO ink,Al-doped ZnO dispersion,Al-dopend ZnO suspension,Al:ZnO ink,Avantama N-20X-Screen. Pack Sizes: 10 mL in poly bottle. | |
| Aluminum-doped Zinc Oxide Nanoparticles / Nanopowder (AZO) | Aluminum-doped Zinc Oxide Nanoparticles / Nanopowder (AZO). Group: Vapor deposition precursors. Alternative Names: Aluminum Zinc Oxide. CAS No. 37275-76-6. Product ID: dialuminum; zinc; oxygen(2-). Molecular formula: 183.34. Mole weight: Al2O4Zn. [O-2].[O-2].[O-2].[O-2].[Al+3].[Al+3].[Zn+2]. InChI=1S/2Al.4O.Zn/q2*+3;4*-2;+2. DSRXRJYQGIXPCQ-UHFFFAOYSA-N. 99%, 99.9%, 99.99%, 99.999%. | |
| Antimony Doped Tin Oxide | Antimony Doped Tin Oxide. Group: Nanoparticles. | |
| Antimony (Sb) doped Bismuth Telluride | Antimony (Sb) doped Bismuth Telluride. Group: other nano materials. CAS No. 1304-82-1. Molecular formula: 800.76 g/mol. Mole weight: Bi0.5 Sb1.5 Te [3-0.1]. 99.99%. | |
| AZO - Zinc Oxide Nanoparticles Doped with 2wt% Aluminum | AZO - Zinc Oxide Nanoparticles Doped with 2wt% Aluminum. Group: Oxides nanoparticles. Molecular formula: 81.3794 g/mol. 99.99+%. | |
| Barium magnesium aluminate, europium doped | Barium magnesium aluminate, europium doped. Group: 3d printing materials phosphors - phosphor materials. CAS No. 724792-82-9. | |
| B-doped Graphene Sponges (Foams, Aerogels) | Carbon black oil appears as a dark colored liquid with a petroleum-like odor. Less dense than water and insoluble in water. Vapors heavier than air.;Carbon, activated is a black grains that have been treated to improve absorptive ability. May heat spontaneously if not properly cooled after manufacture.;Carbon, animal or vegetable origin appears as a black powder or granular mixed with a tar or starch and water binder pressed into regular lumps or briquettes. Heats slowly and ignites in air especially if wet.;Graphite (natural) appears as a mineral form of the element carbon. Hexagonal crystals or thin leaf-like layers. Steel-gray to black with a metallic luster and a greasy feel. An electrical conductor. Used for high-temperature crucibles, as a lubricant and in "lead" pencils.;DryPowder; DryPowder, Liquid; DryPowder, PelletsLargeCrystals; DryPowder, PelletsLargeCrystals, WetSolid, OtherSolid, Liquid; DryPowder, WetSolid, Liquid; Liquid; OtherSolid; OtherSolid, GasVapor, Liquid; PelletsLargeCrystals; PelletsLargeCrystals, OtherSolid, Liquid; WetSolid; WetSolid, Liquid;OtherSolid; PelletsLargeCrystals;DryPowder; DryPowder, OtherSolid; DryPowder, PelletsLargeCrystals; OtherSolid; PelletsLargeCrystals; PelletsLargeCrystals, OtherSolid; WetSolid;DryPowder; DryPowder, OtherSolid; DryPowder, PelletsLargeCrystals; DryPowder, WetSolid; Liquid; OtherSolid; PelletsLargeCrystals; PelletsLargeCrystals, Othe | |
| Bismuth Telluride Doped - Based Composite Thermoelectric Materials | Bismuth Telluride Doped - Based Composite Thermoelectric Materials. Group: Nanopowder compounds. CAS No. 1304-82-1. Molecular formula: 800.76 g/mol. Mole weight: Bi2 Te3-0.1. 99.99%. | |
| Boron-doped graphene | Typical thickness: 1-5 layers. Typical size : 0.5-5 μm. Uses: Bioimaging photocatalysis led energy conversion sensing. Group: Carbon nano materials. Molecular formula: 12.01. | |
| Boron-doped graphene | Typical thickness: 1-5 layers. Typical size : 0.5-5 μm. Uses: Bioimaging photocatalysis led energy conversion sensing. Group: other nano materials. Molecular formula: 12.01. | |
| Boron-Doped P-Type Silicon Wafer | Boron-Doped P-Type Silicon Wafer. Group: Silicon / cellulose wafers. | |
| Boron/Nitrogen co-doped Graphene | Typical thickness: 1-5 layers. Typical size : 0.5-5 μm. Uses: Bioimaging photocatalysis led energy conversion sensing. Group: Carbon nano materials. Molecular formula: 12.01. | |
| Boron/Nitrogen co-doped Graphene | Typical thickness: 1-5 layers. Typical size : 0.5-5 μm. Uses: Bioimaging photocatalysis led energy conversion sensing. Group: other nano materials. Molecular formula: 12.01. | |
| Carbon Doped Boron Nitride Nanotubes | Carbon Doped Boron Nitride Nanotubes. Group: Graphene nanopowders. CAS No. 308068-56-6. >99% (SWCNT). | |
| Cerium Doped Barium Titanate (Ce: BaTiO3) Crystal | Cerium Doped Barium Titanate (Ce: BaTiO3) Crystal. Group: Magnetic nanoparticles. Alternative Names: Cerium Doped Barium Titanate Crystal, Ce: BaTiO3 Crystal, Ce: BaTiO3 Wafers, Ce: BaTiO3 Substrate, Ce: BaTiO3 Slice. | |
| Cerium-doped Lutetium Oxyorthosilicate | Cerium-doped Lutetium Oxyorthosilicate. Group: Graphene nanopowders. Mole weight: Lu2SiO5(Ce). 99.9%. | |
| Cerium-Doped Yttrium Aluminum Garnet (Ce: YAG) Scintillation Crystal | Cerium-Doped Yttrium Aluminum Garnet (Ce: YAG) Scintillation Crystal. Group: Magnetic nanoparticles. Alternative Names: Ce: YAG Wafers, Ce: YAG Substrate, Ce: YAG Slice, Cerium-Doped Yttrium Aluminum Garnet Wafers, Cerium-Doped Yttrium Aluminum Garnet Substrate, Cerium-Doped Yttrium Aluminum Garnet Slice. | |
| Cerium(IV) oxide-gadolinium doped | Cerium(IV) oxide-gadolinium doped. Group: Electrolytessolid oxide fuel cell materials. Product ID: dioxocerium; gadolinium. Molecular formula: 329.4g/mol. Mole weight: CeGdO2. O=[Ce]=O.[Gd]. InChI=1S/Ce.Gd.2O. ZBPTVGKVCOMWPA-UHFFFAOYSA-N. | |
| Cerium(IV) oxide-samarium doped | Cerium(IV) oxide-samarium doped. Group: Electrolytessolid oxide fuel cell materials. Molecular formula: 172.11. | |
| Cerium(IV) oxide-yttria doped | Cerium(IV) oxide-yttria doped. Group: Electrolytes. CAS No. 170033-03-1. | |
| Cerium magnesium aluminate, terbium doped | 99% trace metals basis. Group: Oxides for 3d printing. | |
| Cerium magnesium aluminate, terbium doped | Cerium magnesium aluminate, terbium doped. Group: 3d printing materials phosphors - phosphor materials. CAS No. 106495-57-2. | |
| Cerium oxide, praseodymium doped | Cerium oxide, praseodymium doped. Group: Electrolytessolid oxide fuel cell materials. CAS No. 130071-47-5. | |
| Cerium oxide, praseodymium doped | nanopowder, <100 nm particle size. Group: Electrolytes. | |
| Cerium Oxide Yttria doped Nanoparticle Dispersion | Cerium Oxide Yttria doped Nanoparticle Dispersions are suspensions of cerium oxide yttria doped nanoparticles in water or various organic solvents such as ethanol or mineral oil. Group: Solid oxide fuel cell materials. Alternative Names: Cerium(IV) Oxide, Yttria Doped, 10YDC, Cerium yttrium oxide, YDC-10, YDC10, YDC, Yttria doped ceria, Yttrium doped ceria, cerium oxide stabilized by yttrium oxide, Cerium Oxide Yttria doped nanopowder suspension, aqueous Cerium Oxide Yttria doped nanoparticle solution, Cerium Oxide Yttria doped nanofluid. CAS No. 170033-03-1. Molecular formula: 398g/mol. Mole weight: CeO2/Y2O3. | |
| Cerium Oxide Yttria doped Nanoparticles / Nanopowder | Cerium Oxide, Yttria-doped Nanopowder or Nanoparticles, nanodots or nanocrystals are spherical or faceted hHigh surface area oxide magnetic nanostructure particles. Uses: Designed for use in research and industrial production. Additional or Alternative Names: Cerium(IV) Oxide. Product Category: Nanoparticles & Nanopowders. Appearance: Faint to light yellow powder. CAS No. 170033-03-1. Molecular formula: CeO2/Y2O3. Mole weight: 398g/mol. Purity: 10 mol % yttria, 20 mol % yttria. Product ID: ACM170033031-1. Alfa Chemistry ISO 9001:2015 Certified. | |
| Chromium Doped Silicon Monoxide (Cr-SiO) Sputtering Targets | Chromium Doped Silicon Monoxide (Cr-SiO) Sputtering Targets. Group: Sputtering targets. Alternative Names: Chromium Doped Silicon Monoxide (Cr-SiO) Sputtering Targets, Cr-SiO Alloy Sputtering Target, Cr-SiO Alloy Sputter Target, Cr-SiO Alloy Target, Chromium Doped Silicon Monoxide Alloy Sputter Target, Chromium Doped Silicon Monoxide Alloy Target. CAS No. 12019-52-2. 99.9%-99.99%. | |
| Chromium-doped Yttrium-Aluminum Garnet (Cr: YAG) Crystal, Passive Q-switch | Chromium-doped Yttrium-Aluminum Garnet (Cr: YAG) Crystal, Passive Q-switch. Group: Alloys nanopowders. Alternative Names: Chromium-doped Yttrium-Aluminum Garnet Crystal, Cr: YAG Crystal, Cr: YAG Wafers, Cr: YAG Substrate, Cr: YAG Slice. | |
| Cobalt-doped Magnesium Aluminate (Co: MgAl2O4) Crystal, Passive Q-switch | Cobalt-doped Magnesium Aluminate (Co: MgAl2O4) Crystal, Passive Q-switch. Group: Magnetic nanoparticles. Alternative Names: Cobalt-doped Magnesium Aluminate Crystal, Co: MgAl2O4 Crystal, Co: MgAl2O4 Wafers, Co: MgAl2O4 Substrate, Co: MgAl2O4 Slice. | |
| Co-doped Nb2CTx Multilayer Mxene | Co-doped Nb2CTx Multilayer Mxene. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors. Group: Mxene materials. 99%, Co doping amount 1%. | |
| Co-doped Ti2CTx Multilayer Mxene | Co-doped Ti2CTx Multilayer Mxene. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors. Group: Mxene materials. 99%, Co doping amount 1%. | |
| Co-doped Ti3C2Tx Multilayer Mxene | Co-doped Ti3C2Tx Multilayer Mxene. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors. Group: Mxene materials. 99%, Co doping amount 1%. | |
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