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| Product | Description | |
|---|---|---|
| 1-Allyl-3-methylimidazolium bromide | 1-Allyl-3-methylimidazolium bromide can be used to methylimidazolium based ionic liquids with varying anions as electrolytes in graphene nanosheet-based supercapacitors. Uses: Ionic liquids. Group: Electrolytes. Alternative Names: 1-Allyl-3-methylimidazolium bromide ,1-allyl-3-Methyl-1H-iMidazol-3-iuM broMide; AMIMBr; 1-Allyl-3-methylimidazolium bromide. CAS No. 31410-07-8. Product ID: 1-methyl-3-prop-2-enylimidazol-1-ium; bromide. Molecular formula: 203.08. Mole weight: C7H11N2Br. C[N+]1=CN(C=C1)CC=C.[Br-]. 1S/C7H11N2.BrH/c1-3-4-9-6-5-8(2)7-9; /h3, 5-7H, 1, 4H2, 2H3; 1H/q+1; /p-1. KLFDZFIZKMEUGI-UHFFFAOYSA-M. ≥97.0%. |  |
| 1-Allyl-3-methylimidazolium bromide | 1-Allyl-3-methylimidazolium bromide can be used to methylimidazolium based ionic liquids with varying anions as electrolytes in graphene nanosheet-based supercapacitors. Uses: Ionic liquids. Group: Functionized ionic liquids. Alternative Names: 1-Allyl-3-methylimidazolium bromide ,1-allyl-3-Methyl-1H-iMidazol-3-iuM broMide; AMIMBr;1-Allyl-3-methylimidazolium bromide. CAS No. 31410-07-8. Molecular formula: C7H11N2Br. Mole weight: 203.08. Appearance: Liquid. Purity: ≥97.0%. IUPACName: 1-methyl-3-prop-2-enylimidazol-1-ium;bromide. Canonical SMILES: C[N+]1=CN(C=C1)CC=C.[Br-]. Catalog: ACM31410078. |  |
| 2,2'-Bithiophene | 2,2'-Bithiophene is an electron transporting material with the π-electrons present in the system that facilitate charge mobility. Uses: 2,2'-bithiophene can be polymerized to form poly(2,2'-bithiophene) which can be electrodeposited on indium tin oxide (ito) substrates for the fabrication of electrochromic devices. it can also be used in the formation of electrode material for the development of supercapacitors. substrate used in a rhodium-catalyzed c-h arylation of heteroarenes with aryl iodides. Group: Electroluminescence materials other electronic materials synthetic tools and reagents polymers. Alternative Names: 2-(2'-Thieno)thiophene. CAS No. 492-97-7. Pack Sizes: Packaging 10 g in glass bottle. Product ID: 2-Thiophen-2-ylthiophene. Molecular formula: 166.3. Mole weight: C8H6S2. C1=CSC(=C1)C2=CC=CS2. InChI=1S/C8H6S2/c1-3-7 (9-5-1)8-4-2-6-10-8/h1-6H. OHZAHWOAMVVGEL-UHFFFAOYSA-N. 95%+. | |
| 2,2'-Bithiophene | 2,2'-Bithiophene is an electron transporting material with the π-electrons present in the system that facilitate charge mobility. Uses: 2,2'-bithiophene can be polymerized to form poly(2,2'-bithiophene) which can be electrodeposited on indium tin oxide (ito) substrates for the fabrication of electrochromic devices. it can also be used in the formation of electrode material for the development of supercapacitors. substrate used in a rhodium-catalyzed c-h arylation of heteroarenes with aryl iodides. Group: Thiophenes. Alternative Names: 2-(2'-Thieno)thiophene. CAS No. 492-97-7. Molecular formula: C8H6S2. Mole weight: 166.3. Appearance: Solid. Purity: 95%+. IUPACName: 2-Thiophen-2-ylthiophene. Canonical SMILES: C1=CSC(=C1)C2=CC=CS2. Density: 1.2±0.1 g/cm³. ECNumber: 207-767-2. Catalog: ACM492977-1. | |
| 3,4-Ethylenedioxythiophene | 3,4-Ethylenedioxythiophene (EDOT) is an electro-active conductive monomer with a thiol group that combines an electron donor and electron acceptor in a donor-acceptor-donor arrangement. Monomer used in the synthesis of conducting polymers. Uses: Edot can be polymerized to form poly(3,4-ethylenedioxythiophene) (pedot) for use as an electrochromic polymer (ec) based coating for a variety of s like solid state organic electrochemical supercapacitors (oescs), electrochromic devices (ecds), and carbon nanotubes (cnts) based electrochemical devices for diabetes monitoring. it can be used: as a reductant in a one-pot synthesis of gold nanoparticles from haucl4 (254169). as a starting material used in palladium-catalyzed mono- and bis-arylation reactions. in the synthesis of conjugated polymers and copolymers, with potential optical s. Group: Electroluminescence materials synthetic tools and reagents polymers. Alternative Names: EDOT. CAS No. 126213-50-1. Pack Sizes: Packaging 10 g in glass bottle. Product ID: 2,3-Dihydrothieno[3,4-b][1,4]dioxine. Molecular formula: 142.18. Mole weight: C6H6O2S. C1COC2=CSC=C2O1. InChI=1S/C6H6O2S/c1-2-8-6-4-9-3-5 (6)7-1/h3-4H, 1-2H2. GKWLILHTTGWKLQ-UHFFFAOYSA-N. 95%+. | |
| 3,4-Ethylenedioxythiophene | 3,4-Ethylenedioxythiophene (EDOT) is an electro-active conductive monomer with a thiol group that combines an electron donor and electron acceptor in a donor-acceptor-donor arrangement. Monomer used in the synthesis of conducting polymers. Uses: Edot can be polymerized to form poly(3,4-ethylenedioxythiophene) (pedot) for use as an electrochromic polymer (ec) based coating for a variety of s like solid state organic electrochemical supercapacitors (oescs), electrochromic devices (ecds), and carbon nanotubes (cnts) based electrochemical devices for diabetes monitoring. it can be used: as a reductant in a one-pot synthesis of gold nanoparticles from haucl4 (254169). as a starting material used in palladium-catalyzed mono- and bis-arylation reactions. in the synthesis of conjugated polymers and copolymers, with potential optical s. Group: Thiophenes. Alternative Names: EDOT. CAS No. 126213-50-1. Molecular formula: C6H6O2S. Mole weight: 142.18. Appearance: Liquid. Purity: 95%+. IUPACName: 2,3-Dihydrothieno[3,4-b][1,4]dioxine. Canonical SMILES: C1COC2=CSC=C2O1. Density: 1.3±0.1 g/cm³. ECNumber: 415-450-7;603-128-0. Catalog: ACM126213501-2. | |
| 4,4'-Stilbenedicarboxylic acid | 4,4'-Stilbenedicarboxylic acid (SDA) is a luminescent ligand that is useful as an organic linker due to the presence of two carboxylic groups, which form bridges between metallic centers. It has conjugated aromatic rings that facilitate the formation of a rigid linker. SDA can be used in the hydrothermal synthesis of three-dimensional (3D) metal-organic frameworks, which have potential usage in sensing, drug delivery, luminescence, and gas adsorption. It may also be used in energy storage applications such as supercapacitors and batteries. Group: Hydrogen storage materials monomers. Alternative Names: 4, 4'-(1, 2-Ethenediyl)bisbenzoicacid, 4, 4'-Dicarboxystilbene, Biphenylethene-4, 4·-dicarboxylicacid, H2BPEA, H2SDC. CAS No. 100-31-2. Product ID: 4-[(E)-2-(4-carboxyphenyl)ethenyl]benzoic acid. Molecular formula: 268.26. Mole weight: C10H6(CO2H)2. C1=CC (=CC=C1C=CC2=CC=C (C=C2)C (=O)O)C (=O)O. 1S/C16H12O4/c17-15 (18)13-7-3-11 (4-8-13)1-2-12-5-9-14 (10-6-12)16 (19)20/h1-10H, (H, 17, 18) (H, 19, 20)/b2-1+. SBBQDUFLZGOASY-OWOJBTEDSA-N. 98%. | |
| [5,6]-Fullerene-C70 | (5,6)-Fullerene-C70 (C70) is an ellipsoidal fullerene which has stable spheroidal carbon molecules. C70 is an n-channel organic semiconductor. High reactivity of fullerenes is attributed to its characteristic pyramidalization of the sp2 carbons. Vacuum dried to remove residual solvent.Typical hydrocarbon content <0.25%. Uses: C70 may be incorporated into titanium oxide (tio2) based nanowires and it forms a nanocomposite for light responsive photocatalyst. it can also be used as a photo-absorptive material in the fabrication of high performance organic photovoltaic (opv) cells. Group: Supercapacitorscarbon nano materials organic field effect transistor (ofet) materials organic solar cell (opv) materials sublimed materials. Alternative Names: BuckminsterfullereneC70,Fullerene-C70. CAS No. 115383-22-7. Pack Sizes: 250 mg in glass insert. Product ID: (C\{70}-D\{5h(6)})fullerene. Molecular formula: 840.75. Mole weight: C70. C1CC2C3CCC4C5C3C6C2C7C1CC8CC9CC% 10CC% 11C% 12CC% 13CC4C% 13% 14C% 12C% 15C% 11C% 16C% 10C9C% 17C8C7C% 18C% 17C% 16C% 15C (C6% 18) C5% 14. 1S / C70 / c1-2-22-5-6-24-13-14-26-11-9-23-4-3 (21 (1) 51-52 (22) 54 (24) 55 (26) 53 (23) 51) 33-31 (1) 61-35-7-8-27-15-16-29-19-20-30-18-17- 28-12-10 (25 (7) 56-57 (27) 59 (29) 60 (30) 58 (28) 56) 37 (35) 63 (33) 65-36 (4) 40 (9) 67 (44 (17) 42 (12) 65 ) 69-46 (11) 47 (14) 70 (50 (20) 49 (18) 69) 68-43 (13) 39 (6) 66 (45 (16) 48 (19) 6 8) 64-34 (5) 32 (2) 62 (61) 38 | |
| 99.7% TI3AlC2 powder material | MAX phase ceramics (including titanium silicon carbide, Ti3AlC2 materials, etc.) is a new type of machinable conductive ceramic material that has attracted much attention. Ti3SiC2 is the most extensively studied. Uses: Max has been widely used in nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. CAS No. 196506-01-1. 0.997. | |
| Activated charcoal | Activated charcoal (AC) powder, -100 particle size (mesh), decolorizing, is a carbonaceous material that is majorly used in a variety of applications due to its abundance, cost effectiveness and environmentally safe nature. It can be used in the fabrication of energy devices. Group: Supercapacitors. Alternative Names: Charcoalactivated. CAS No. 7440-44-0. Product ID: carbon. Molecular formula: 12.01. Mole weight: C. [C]. 1S/C. OKTJSMMVPCPJKN-UHFFFAOYSA-N. powder, -100particlesize(mesh), decolorizing. | |
| Aminated monolayer Ti3C2 dispersion | Aminated monolayer Ti3C2 dispersion. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. ≥98%. | |
| Aminated monolayer Ti3C2 powder | Aminated monolayer Ti3C2 powder. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. ≥98%. | |
| Carbon Black Nanoparticles / Nanopowder | Carbon Black Nanoparticles / Nanopowder. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: other nano materials. CAS No. 1333-86-4. Product ID: Carbon. Molecular formula: 12.01. C. | |
| Carbon nanotube, double-walled | DWNTs exhibit excellent field emission properties and may be potentially useful as field emission displays (FEDs) and field emission transistors (FETs). Group: 3d printing materials supercapacitorscarbon nano materials. Alternative Names: DWNT, Doublewallcarbonnanotubes. CAS No. 308068-56-6. Molecular formula: 12.01. Mole weight: C, >90% (trace metal basis). 50-80%carbonbasis,O.D.×I.D.×L5 nm×1.3-2.0 nm×50 μm. | |
| Carbon Nanotube Ink | Carbon Nanotube Ink is a solution of single-walled carbon nanotubes in dimethyl sulfoxide for electronics and thin film applications. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: other nano materials. Alternative Names: CNT Ink, NINK. CAS No. 7440-44-0. Product ID: Carbon. Molecular formula: 12.01. Mole weight: C. C. | |
| Carbon nanotube, multi-walled | O.D.×L7-12 nm×0.5-10 μm. Multi-walled carbon nanotube core surrounded by a fused carbon shell, the remainder being multi-layer polygonal carbon nanoparticles and amorphous and graphitic carbon nanoparticles.It contains approximately 5-20 graphitic layers. Carbon nanotubes produced by arc discharge technique contain very low impurity and possesses very high crystallinity. Group: 3d printing materials supercapacitorscarbon nano materials. Alternative Names: MWCNT, MWNT, Multiwallcarbonnanotube. CAS No. 308068-56-6. Molecular formula: 12.01. Mole weight: C. powdered cylinder cores,20-30% MWCNT basis. | |
| Carbon nanotube, single-walled | ≥90% carbon basis (≥80% as carbon nanotubes), 1.3 nm diameter. Uses: Carbon nanotube, single-walled (swnt) belongs to the class of carbonaceous materials with excellent physiochemical, thermo-mechanical and electrochemical properties. this material can be used in a variety of sustainable energy applications such as solar cells, photocatalysis, thin film conductors, field effect transistors (fets), biosensor, gas sensor, supercapacitor and nanomechanical resonators.suitable for use in conductive composites and coatings.functionalized single-walled carbon nanotubes (swnts) embedded in an insulating polymer matrix may be used as stable hole collection layer in perovskite solar cells.manufacturing, characterization and use of swcnts. Group: 3d printing materials supercapacitorscarbon nano materials. Alternative Names: SWCNT, SWNT, Signis Cg200, CHASM, CNT, Single wall carbon nanotube. CAS No. 308068-56-6. Pack Sizes: 250 mg/1 g. Molecular formula: 12.01. Mole weight: C. ≥98%carbonbasis. | |
| Carbon nanotube, single-walled, solvent-based conductive ink, SWCNT | Single walled carbon nanotubes offer an alternative to metallic conductive inks. The nanotubes exhibit high conductivity, oxidation resistance. Carbon nanomaterial based conductive inks are used in printed and flexible electronics, thin film transistors, electrochemical sensors, supercapacitors and photovoltaics. Uses: This solvent based conductive ink is primarily formulated for screen printing transparent conductors. Group: 3d printing materials carbon nano materials printed electronic materials. Alternative Names: SWCNT Ink, SWNT Ink, SWeNT V2V ink, SWeNT VC101 ink, Single-Walled Carbon Nanotube Ink, conductive ink. Pack Sizes: 25, 100 mL in glass bottle. | |
| Carboxylated monolayer Ti3C2 dispersion | Carboxylated monolayer Ti3C2 dispersion. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. ≥98%. | |
| Carboxylated monolayer Ti3C2 powder | Carboxylated monolayer Ti3C2 powder. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. ≥98%. | |
| Chlorine-terminated monolayer Ti3C2 | Chlorine-terminated monolayer Ti3C2. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. 65~75%. | |
| CVD Graphene on Si/SiO2 (Graphene Factory) | CVD Graphene on Si/SiO2 (Graphene Factory). Uses: 1) catalyst2) supercapacitors3) solar energy4) graphene semiconductor chips5) conductive graphene film6) graphene computer memory7) biomaterials8) transparent conductive coatings. Group: other nano materials. | |
| Fullerene-C60 | Buckyballs are also known as C60 molecules, Fullerenes, or Buckminsterfullerene. Buckyballs are molecules made up of 60 carbon atoms arranged in a series of interlocking hexagons and pentagons, forming a structure that looks similar to a soccer ball. C60 is actually a "truncated icosahedron", consisting of 12 pentagons and 20 hexagons. Uses: C60 has a broad range of applications which include catalysis, optical materials, polymer modification, solar cells, fuel cells, lubricants, cosmetics, and biomedical applications. Group: Supercapacitorscarbon nano materials organic field effect transistor (ofet) materials organic solar cell (opv) materials sublimed materials. Alternative Names: Buckminsterfullerene. CAS No. 99685-96-8. Pack Sizes: 1g, 5g. Product ID: (C\{60}-I\{h})[5,6] fullerene. Molecular formula: 720.64. Mole weight: C60. c12c3c4c5c1c6c7c8c2c9c% 10c3c% 11c% 12c4c% 13c% 14c5c% 15c6c% 16c7c% 17c% 18c8c9c% 19c% 20c% 10c% 11c% 21c% 22c% 12c% 13c% 23c% 24c% 14c% 15c% 25c% 16c% 26c% 17c% 27c% 18c% 19c% 28c% 20c% 21c% 29c% 22c% 23c% 30c% 24c% 25c% 26c% 31c% 27c% 28c% 29c% 30% 31. 1S/C60/c1-2-5-6-3 (1)8-12-10-4 (1)9-11-7 (2)17-21-13 (5)23-24-14 (6)22-18 (8)28-20 (12)30-26-16 (10)15 (9)25-29-19 (11)27 (17)37-41-31 (21)33 (23)43-44-34 (24)32 (22)42-38 (28)48-40 (30)46-36 (26)35 (25)45-39 (29)47 (37)55-49 (41)51 (43)57-52 (44)50 (42)56 (48)59-54 (46)53 (45)58 (55)60 (57)59. XMWRBQBLMFGWIX-UHFFFAOYSA-N. 0.995. | |
| Fullerene-C76 | C76 is a higher fullerene with 76 carbon atoms. Electron affinity of C76 was determined to be 2.88+/- 0.05 eV. Fullerene-C76 is a higher order fullerene with good optical absorption, which can be potentially used for polymeric solar cells based applications. Uses: Fullerene-c76 is a higher order fullerene with good optical absorption, which can be potentially used for polymeric solar cells based applications. Group: Supercapacitorscarbon nano materials. Alternative Names: Fullerene-C76. CAS No. 142136-39-8. Pack Sizes: 5 mg in glass insert. Molecular formula: 912.81. 1S/C60/c1-2-5-6-3 (1)8-12-10-4 (1)9-11-7 (2)17-21-13 (5)23-24-14 (6)22-18 (8)28-20 (12)30-26-16 (10)15 (9)25-29-19 (11)27 (17)37-41-31 (21)33 (23)43-44-34 (24)32 (22)42-38 (28)48-40 (30)46-36 (26)35 (25)45-39 (29)47 (37)55-49 (41)51 (43)57-52 (44)50 (42)56 (48)59-54 (46)53 (45)58 (55)60 (57)59. XMWRBQBLMFGWIX-UHFFFAOYSA-N. 98%. | |
| Fullerene-c84 | Fullerene-c84. Group: Supercapacitorscarbon nano materials organic field effect transistor (ofet) materials organic solar cell (opv) materials. Alternative Names: FULLERENE-C84; FullereneCminblackpowder; FULLERENECARBON 84, 99.0+ %, PURIFIED; FULLERENECARBON 84, 95.0+ %, REAGENT; FULLERENECARBON 84, 98.0+ %, REAGENT; Fullerene-C84,min.95%; Fullerene-C84,min.99%; Fullerene - C84, min. 95%. CAS No. 135113-16-5. Molecular formula: 1008.9g/mol. Mole weight: C84. C12=C3C4=C5C6=C7C8=C9C% 10=C% 11C% 12=C% 13C% 14=C% 15C% 16=C% 17C% 18=C% 19C% 20=C% 21C% 22=C (C1=C1C (=C36) C (=C7% 10) C (=C% 11% 14) C (=C% 18% 15) C1=C% 22% 19) C1=C2C2=C4C3=C4C5=C8C5=C6C9=C% 12C7=C8C% 13=C% 16C9=C% 10C% 17=C% 20C% 11=C% 12C% 21=C1C1=C2C2=C3C3=C% 13C% 14=C2C1=C% 12C1=C% 14C2=C (C% 10=C% 111) C9=C8C1=C2C% 13=C (C5=C43) C6=C71. InChI= 1S / C84 / c1-2-26-29-9-11-36-39-16-18-42-44-22- 21-43-41-14-13-35-32-7-5 (27-25 (1) 61 (26) 73-74 (62 (27) 32) 77 (67 (35) 41) 81 ( 70 (43) 44) 78 (68 (39) 42) 75 (73) 64 (29) 36) 51-6-8-33-38-15 (55 (13) 53 (7) 8) 17-45-46-23 (59 (21) 57 (14) 17) 24-48-47-20 (58 (18) 60 (22) 24) 19-40-37-12 (54 (11) 56 (16) 19) 10-34-30-4 (50 (2) 52 (9) 10) 3 (49 (1) 51) 2 8-31 (6) 65 (33) 79-76 (63 (28) 30) 80 (66 (34) 37) 83 ( 71 (40) 47) 84 (72 (46) 48) 82 (79) 69 (38) 45. FQRWAZOLUJHNDT-UHFFFAOYSA-N. | |
| Fullerene Soot | Fullerene Soot is a fine powder composed of a mix of C60 and C70 fullerenes in a ration of roughly 22% C60 to 76% C70. Fullerene Soot is generally immediately available in most volumes. Uses: Fullerene soot is a carbonaceous material that can be used in a variety of sustainable applications such as double-layer capacitor (dlc), water purification, hydrogen storage, supercapacitor, and nanoelectronics. fullerene soot is a low cost nanomaterial that finds applications in superconductors, photoconductors and semiconductor based industries. Group: Supercapacitorscarbon nano materials. Pack Sizes: 5 g in poly bottle. Product ID: carbon. Molecular formula: 912.81. Mole weight: C60 / C70. [C]. 1S/C. OKTJSMMVPCPJKN-UHFFFAOYSA-N. 99% | 99.9% | 99.99% | 99.999%. | |
| General Purpose Adsorbent | General Purpose Adsorbent. Group: Supercapacitors. | |
| Graphene Nanoplatelets | Graphene Nanoplatelets. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: other nano materials. CAS No. 1034343-98-0. Molecular formula: 12.01. | |
| Graphene on PET | Graphene on PET. Uses: ?energy electrode (solar cells, secondary batteries, fuel cells, supercapacitors) ?functional composite materials (ultra-light strong composite for cars & aerospace) ?heat dissipation (led lighting & ecu units) ?barrier (gas barriers, electromagnetic wave barriers) ?biomedical applications (substrate for stem cell therapy, graphene liquid cells for electron microscopy) ?transparent electrode (flexible display & touch screen). Group: Cvd graphene. | |
| Graphene Oxide (GO) TEM Support Films | Graphene Oxide (GO) support film is available as Single Layer (0.6~1nm) or Double Layer (1~1.5nm) measured by EELS. It is hydrophilic and naturally placed over the ultra-flat Silicon Dioxide Substrate, Lacey Carbon (300 Mesh Copper TEM Grids) or Holy Silicon Nitride Membranes with typically 50-70% coverage. Available in package of 5, 10 or 25 pieces. A. 300 Mesh Copper TEM grid with Lacey Carbon film; B. 00nm-thick 2μm Diameter Holey Silicon Nitride Membrane on 200μm-thick Silicon Substrate; C. 5x5mm 675μm-thick Silicon Die with 200nm Thermal Oxide. Uses: 1) catalyst2) supercapacitors3) solar energy4) graphene semiconductor chips5) conductive graphene film6) graphene computer memory7) biomaterials8) transparent conductive coatings. Group: Graphenes. | |
| Graphene Oxide (GO) TEM Support Films | Graphene Oxide (GO) support film is available as Single Layer (0.6~1nm) or Double Layer (1~1.5nm) measured by EELS. It is hydrophilic and naturally placed over the ultra-flat Silicon Dioxide Substrate, Lacey Carbon (300 Mesh Copper TEM Grids) or Holy Silicon Nitride Membranes with typically 50-70% coverage. Available in package of 5, 10 or 25 pieces. A. 300 Mesh Copper TEM grid with Lacey Carbon film; B. 00nm-thick 2μm Diameter Holey Silicon Nitride Membrane on 200μm-thick Silicon Substrate; C. 5x5mm 675μm-thick Silicon Die with 200nm Thermal Oxide. Uses: 1) catalyst2) supercapacitors3) solar energy4) graphene semiconductor chips5) conductive graphene film6) graphene computer memory7) biomaterials8) transparent conductive coatings. Group: other nano materials. | |
| Graphene Oxide Thin Film | Graphene Oxide Thin Films are composed of graphene oxide (GO), a novel advanced material that consists of graphene, a single atom thick layer of carbon atoms, with various oxygen-containing functionalities. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: other nano materials. Mole weight: CxOzyHz. | |
| Hydroxylated monolayer Ti3C2 dispersion | Hydroxylated monolayer Ti3C2 dispersion. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. ≥98%. | |
| Metal-supported monolayer Ti3C2 | Metal: Fe, Co, Mn, Pt. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. ≥98%. | |
| Mn3O4/reduced graphene oxide nanocomposite | Mn3O4/reduced graphene oxide nanocomposite. Uses: High capacity anode material for supercapacitors and lithium ion batteries. Group: 3d printing materials carbon nano materials. | |
| Mo2TiAlC2 MAX phase material | Mo2TiAlC2 MAX phase material. Uses: Max has been widely used in nano-adsorption, biosensors, ion screening, catalysis, lithium ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. 0.99. | |
| MoAlB MAX phase material | MoAlB MAX phase material. Uses: Max has been widely used in nano-adsorption, biosensors, ion screening, catalysis, lithium ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. 0.99. | |
| Molybdenum disulfide ink for inkjet printing | Curing condition: 400° C, 3 hours in Ar/H2 environment. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: Carbon nano materials printed electronic materials. | |
| Monolayer Graphene Oxide | Monolayer Graphene Oxide. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: other nano materials. | |
| Monolayer Mo2C dispersion | Monolayer Mo2C dispersion. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. >95%. | |
| Monolayer Mo2C powder | Monolayer Mo2C powder. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. >95%. | |
| Monolayer Nb4C3 dispersion | Monolayer Nb4C3 dispersion. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. CAS No. 12316-56-2. >95%. | |
| Monolayer Ta4C3 dispersion | Monolayer Ta4C3 dispersion. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. >95%. | |
| Monolayer Ta4C3 powder | Monolayer Ta4C3 powder. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. >95%. | |
| Monolayer Ti2C dispersion | Monolayer Ti2C dispersion. Uses: Mxenes and mxenes-based nanocomposites have been widely used in nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. CAS No. 12316-56-2. >95 wt%. | |
| Monolayer Ti2C powder | Monolayer Ti2C powder. Uses: Mxenes and mxenes-based nanocomposites have been widely used in nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. CAS No. 12316-56-2. >95 wt%/70-80 wt%. | |
| Monolayer Ti2N dispersion | Monolayer Ti2N dispersion. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. >95%. | |
| Monolayer Ti3C2 dispersion | The solution is dark green at low concentration and black at high concentration. Due to the dispersibility of the material itself, if you need a single-layer MXene dispersion with a concentration exceeding the specification or other organic solvents, it is recommended to purchase a single-layer freeze-dried powder to disperse by yourself. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. CAS No. 12363-89-2. | |
| Monolayer Ti3CN dispersion | Monolayer Ti3CN dispersion. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. >95%. | |
| Monolayer Ti3CN powder | Monolayer Ti3CN powder. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. >95%. | |
| Multilayer Nb4C3 powder | Multilayer Nb4C3 powder. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. CAS No. 12316-56-2. 80~90%. | |
| Multilayer Ta4C3 powder | Multilayer Ta4C3 powder. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. 80~90%. | |
| Multilayer Ti3C2 dispersion | Multilayer Ti3C2 dispersion. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. CAS No. 12363-89-2. 75-85%. | |
| Multilayer Ti3CN powder | Multilayer Ti3CN powder. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. 50-60%. | |
| Nb2AlC (MAX) Phase Ceramic Material (400 mesh) | Nb2AlC (MAX) Phase Ceramic Material (400 mesh). Uses: Nano-adsorption, biosensors, ionsieving,catalysis, lithium-ion batteries, supercapacitors. Group: Mxene materials. ≥90%. | |
| Nb2CTx (MXene) Multilayer Nanoflake | Nb2CTx (MXene) Multilayer Nanoflake. Uses: Nano-adsorption, biosensors, ionsieving,catalysis, lithium-ion batteries, supercapacitors. Group: Mxene materials. CAS No. 12069-94-2. 40-50%. | |
| Nb4C3Tx (MXene) Multilayer Nanosheet | Nb4C3Tx (MXene) Multilayer Nanosheet. Uses: Nano-adsorption, biosensors, ionsieving,catalysis, lithium-ion batteries, supercapacitors. Group: Mxene materials. CAS No. 12069-94-2. ≥80%. | |
| Nitrogen-doped graphene | This highly exfoliated nitrogen-doped graphene exhibits high electrochemical activity towards oxygen reduction in alkali medium providing an affordable industrial alternative to currently used noble metal-based catalysts (i.e. Pt, Pd). This nitrogen-doped graphene shows high onset potential (ca. 940 mV vs. RHE) carrying out the electrochemical oxygen reduction reaction (ORR) towards a 4 electron pathway avoiding the production of H2O2. Furthermore, this material is reported to be more stable (to MeOH) and durable (CO tolerance) than Pt-based catalysts.This highly exfoliated nitrogen-doped graphene exhibits high electrochemical activity towards oxygen reduction in alkali medium providing an affordable industrial alternative to currently used noble metal-based catalysts (i.e. Pt, Pd). This nitrogen-doped graphene shows high onset potential (ca. 940 mV vs. RHE) carrying out the electrochemical oxygen reduction reaction (ORR) towards a 4 electron pathway avoiding the production of H2O2. Furthermore, this material is reported to be more stable (to MeOH) and durable (CO tolerance) than Pt-based catalysts. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: Carbon nano materials. Molecular formula: 12.01. | |
| Nitrogen-doped graphene | This highly exfoliated nitrogen-doped graphene exhibits high electrochemical activity towards oxygen reduction in alkali medium providing an affordable industrial alternative to currently used noble metal-based catalysts (i.e. Pt, Pd). This nitrogen-doped graphene shows high onset potential (ca. 940 mV vs. RHE) carrying out the electrochemical oxygen reduction reaction (ORR) towards a 4 electron pathway avoiding the production of H2O2. Furthermore, this material is reported to be more stable (to MeOH) and durable (CO tolerance) than Pt-based catalysts.This highly exfoliated nitrogen-doped graphene exhibits high electrochemical activity towards oxygen reduction in alkali medium providing an affordable industrial alternative to currently used noble metal-based catalysts (i.e. Pt, Pd). This nitrogen-doped graphene shows high onset potential (ca. 940 mV vs. RHE) carrying out the electrochemical oxygen reduction reaction (ORR) towards a 4 electron pathway avoiding the production of H2O2. Furthermore, this material is reported to be more stable (to MeOH) and durable (CO tolerance) than Pt-based catalysts. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: Graphene series. Molecular formula: 12.01. | |
| Nitrogen-doped Graphene Oxide | Nitrogen-doped Graphene Oxide. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: other nano materials. Molecular formula: 14.5. | |
| Nitrogen/Phosphorus co-doped graphene | Typical thickness: 1-5 layers.Typical size : 0.5-5 μm. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: Carbon nano materials. Molecular formula: 12.01. | |
| Nitrogen/Phosphorus co-doped graphene | Typical thickness: 1-5 layers.Typical size : 0.5-5 μm. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: other nano materials. Molecular formula: 12.01. | |
| Oxygen-terminated monolayer Ti3C2 | Oxygen-terminated monolayer Ti3C2. Uses: Nano-adsorption, biosensors, ion screening, catalysis, lithium-ion batteries, supercapacitors, lubrication and many other fields. Group: Mxenes materials. ≥98%. | |
| Phosphorus-doped graphene | Typical thickness: 1-5 layers.Typical size : 0.5-5 μm. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: Carbon nano materials. | |
| Phosphorus-doped graphene | Typical thickness: 1-5 layers.Typical size : 0.5-5 μm. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: other nano materials. | |
| Poly(9-vinylcarbazole) | Poly(9-vinylcarbazole) (PVK) is a conductive polymer which is mainly used as a hole transporting medium at high efficiencies with low driving voltage. It can also be used as an anode for hole injection and can act as an effective charge transferring gate by co-doping it with organic dyes. Uses: Pvk:graphene oxide composite can be used as a hybrid film which can be coated on silica substrate for the fabrication of organic field effect transistors (ofets). it can also form a nano-composite film with carbon nanospheres (cns) which can be potentially used in supercapacitors and sensor based applications. Group: Organic light-emitting diode (oled) materials. Alternative Names: PVK. CAS No. 25067-59-8. Pack Sizes: 5, 25 g in poly bottle. Product ID: 9-ethenylcarbazole. Molecular formula: 193.24g/mol. Mole weight: C14H11N. C=CN1C2=CC=CC=C2C3=CC=CC=C31. 1S/C14H11N/c1-2-15-13-9-5-3-7-11 (13)12-8-4-6-10-14 (12)15/h2-10H, 1H2, KKFHAJHLJHVUDM-UHFFFAOYSA-N. KKFHAJHLJHVUDM-UHFFFAOYSA-N. | |
| Polyaniline (emeraldine base) | Polyaniline (PAni) emeraldine salt can be prepared by protonation of PAni emeraldine base (PAni-EB). PAni-EB forms at pH>7. Its mechanism against corrosive agents has been explained in a study. Uses: Pani forms a conjugating polymeric system that can be used for a variety of semiconducting applications. it can be used in the fabrication of a variety of devices which include fuel cells, light emitting diodes supercapacitors,[10] chemical sensors and rechargeable batteries. Group: Bioelectronic materials. Alternative Names: Emeraldine base polyaniline. CAS No. 25233-30-1. Pack Sizes: 10, 50 g in glass bottle. | |
| Polyaniline (emeraldine salt) | Inherently conductive polymer. Stable at 100 °C and at 200 °C for short periods. Dispersed particles tend to reaggregrate in molded articles forming conductive pathways. Acidic salt of an organic acid, incompatible with most bases. Form of polyaniline complexed (doped) with proprietary organic sulfonic acid Form of polyaniline complexed (doped) with proprietary organic sulfonic acid. Polyaniline is environmentally stable and with tunable conductivity. Synthesis of polyaniline (PANI) emeraldine salt by chemical oxidation has been reported. It was observed that sulfonated dyes chemically interact with the charged backbone of PANI. PANI selectively adsorbs the sulfonated dye. Spectral, diffraction and conductivity measurements of the polymer has been reported in the same study. Uses: A variety of nanomaterials like silver nanoparticles (agnps), graphene oxide(go), aluminum oxide(α-al2o3), carbon fiber and graphite can be potentially used in conjunction with pani for the development of translational medicine, supercapacitors, triboelectric nanogenerators, and other energy storage applications. additive in polymer blends and liquid dispersions for electromagnetic shielding. Group: 3d printing materials bioelectronic materials organic light-emitting diode (oled) materials. Alternative Names: PANI. Pack Sizes: 10 g in poly bottle. Molecular formula: average Mw >15,000. | |
| Polypyrrole | Polypyrrole (PPy) is a conductive and highly stable polymer, doped with proprietary organic acids. It may be prepared by standard electrochemical technique. PPy may also be prepared by reacting β-napthalene sulfonic acid (NSA) and ammonium peroxo-disulphate in aqueous medium. The charges on the surfaces can be easily modified by doping the polymer during its synthesis.Solubility and conductivity measurements of PPy doped with camphor sulfonic and dodecyl benzene sulfonic acid has been reported. Polypyrrole(PPy) is a π-conjugated conductive polymer that can be electrochemically synthesized and deposited on a variety of surfaces. The deposited PPy can be used in a wide range of sensor based applications due to the following properties: Ion exchange capacity. Electrochromic effects. Redox activity. Corrosion resistant. Catalytic activity. Uses: Conducting polymers may be used in electronics, chemical sensors. ppy can be used in the development of devices including: conductive sensors for quality monitoring blended with nanotubes for supercapacitors nanowire actuators biosensors for drug delivery co2 absorption materials. Group: Bioelectronic materials. Alternative Names: PPy. Pack Sizes: 100 mL in poly bottle. Product ID: 1H-pyrrole. Molecular formula: 67.09g/mol. Mole weight: C4H5N. C1=CNC=C1. InChI=1S/C4H5N/c1-2-4-5-3-1/h1-5H. KAESVJOAVNADME-UHFFFAOYSA-N. | |
| Reduced Graphene Oxide Powder, decorated with Palladium Nanoparticles | Reduced Graphene Oxide (RGO) Powder decorated with Palladium Nanoparticles is graphene-metal hybrid material composed of reduced graphene oxide (r-GO) and a broad distribution of nanoscale palladium particles. Applications include electron microscopy imaging and as a catalyst material in fuel cells. Uses: Electrocatalyst. field-effect transistors. sensors. lithium ion batteries. supercapacitors. Group: other nano materials. Alternative Names: RGO-Pd, reduced graphene oxide nanosheets decorated with Pd NPs. Mole weight: CxOzyHz. | |
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