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| Product | Description | |
|---|---|---|
| phaseollidin hydratase | The enzyme from Fusarium solani, which is distinct from kievitone hydratase (EC 4.2.1.95), hydrates the methylbutenyl side-chain of the isoflavonoid phytoalexin, phaseollidin. Group: Enzymes. Synonyms: phaseollidin-hydrate hydro-lyase. Enzyme Commission Number: EC 4.2.1.97. CAS No. 143597-34-6. Storage: Store it at +4 ?C for short term. For long term storage, store it at -20 ?C?-80 ?C. Form: Liquid or lyophilized powder. EXWM-5081; phaseollidin hydratase; EC 4.2.1.97; 143597-34-6; phaseollidin-hydrate hydro-lyase. Cat No: EXWM-5081. |  |
| α1-6 Mannosidase, Xanthomonas phaseoli | α1-6 Mannosidase, Xanthomonas phaseoli is a highly specific exoglycosidase that removes unbranched α1-6 linked mannose residues from oligosaccharides [1]. Uses: Scientific research. Group: Signaling pathways. CAS No. 9025-42-7. Pack Sizes: 500 U. Product ID: HY-P2950A. |  |
| Calcium phosphate, 98%,β-phase basis | Calcium phosphate is an odorless white solid. Sinks and mixes with water. (USCG, 1999);DryPowder; OtherSolid;DryPowder; OtherSolid;A white, odourless powder which is stable in air. Group: Biocompatible ceramics. CAS No. 7758-87-4. Product ID: tricalcium; diphosphate. Molecular formula: 310.2g/mol. Mole weight: Ca5(PO4)3?OH or Ca3(PO4)2;Ca3(PO4)2;Ca3O8P2. [O-]P(=O)([O-])[O-]. [O-]P(=O)([O-])[O-]. [Ca+2]. [Ca+2]. [Ca+2]. InChI=1S/3Ca.2H3O4P/c;;;2*1-5(2, 3)4/h;;;2*(H3, 1, 2, 3, 4)/q3*+2;;/p-6. QORWJWZARLRLPR-UHFFFAOYSA-H. |  |
| Cr2AlC MAX phase ceramic material | Cr2AlC MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. ≥99%. | |
| Cr2TiAlC3 MAX phase material | Excellent Mxene precursor can be processed by HF or HCl+LiF to obtain MXene. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. 0.99. | |
| Grapefruit Water Phase | Water Phase Aroma. Grapefruit Water Phase Group: Essences. Grade: Food. CAS Number: 8016-20-4. Pack Sizes: Pails to Drums. |  Bradenton, FL |
| Guava Water Phase | Water Phase Aroma. Uses: Flavors. Group: Essences. Grade: Food. Pack Sizes: Pails to Drums. | Bradenton, FL |
| Lemon Water Phase | Water Phase Aroma. Lemon Water Phase Group: Essences. Grade: Food. CAS Number: 977091-76-2. Pack Sizes: Pails to Drums. | Bradenton, FL |
| Mango Water Phase | Water Phase Aroma. Uses: Flavor. Group: Essences. Grade: Food. Pack Sizes: Pails to Drums. | Bradenton, FL |
| (Mo2/3Sc1/3)2AlC MAX phase material | Excellent Mxene precursor can be processed by HF or HCl+LiF to obtain MXene. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. 0.99. | |
| (Mo2/3Y1/3)2AlC phase material | Excellent Mxene precursor can be processed by HF or HCl+LiF to obtain MXene. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. 0.99. | |
| Mo2Ga2C MAX phase ceramic material | Mo2Ga2C MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. ≥99%. | |
| Mo2Ti2AlC3 (MAX) Phase Ceramic Material | Mo2Ti2AlC3 (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >90%. | |
| Mo2Ti2AlC3 MAX phase material | Excellent Mxene precursor can be processed by HF or HCl+LiF to obtain MXene. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. 0.99. | |
| Mo2TiAlC2 (MAX) Phase Ceramic Material | Mo2TiAlC2 (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >90%. | |
| 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. | |
| Mo3AlC2 MAX phase ceramic material | Mo3AlC2 MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. ≥98%. | |
| 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. | |
| Nb2AlC MAX phase ceramic material | Nb2AlC MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. ≥99%. | |
| 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%. | |
| Nb4AlC3 MAX phase ceramic material | Nb4AlC3 MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. ≥99%. | |
| Nb4AlC3 (MAX) Phase Ceramic Material | Nb4AlC3 (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. CAS No. 12069-94-2. ≥90%. | |
| Orange Water Phase | Water Phase Aroma. Orange Water Phase Group: Essences. Grade: Food. CAS Number: 68514-75-0. Pack Sizes: Pails to Drums. | Bradenton, FL |
| Passion Fruit Water Phase | Water Phase Aroma. Uses: Flavors. Group: Essences. Grade: Food. Pack Sizes: Pails to Drums. | Bradenton, FL |
| Peach Water Phase | Water Phase Aroma. Uses: Flavor. Group: Essences. Grade: Food. Pack Sizes: Pails to Drums. | Bradenton, FL |
| Pineapple Water Phase | Water Phase Aroma. Uses: Flavor. Group: Essences. Grade: Food. CAS Number: 97676-27-2. Pack Sizes: Pails to Drums. | Bradenton, FL |
| Poly(ethylene succinate), SU,Liquid Phase for GC | Poly(ethylene succinate), SU,Liquid Phase for GC. Group: Polymers. CAS No. 25569-53-3. Product ID: butanedioic acid; ethane-1,2-diol. Molecular formula: 180.16g/mol. Mole weight: C6H12O6. C(CC(=O)O)C(=O)O.C(CO)O. InChI=1S/C4H6O4. C2H6O2/c5-3(6)1-2-4(7)8; 3-1-2-4/h1-2H2, (H, 5, 6)(H, 7, 8); 3-4H, 1-2H2. VJVOPINBJQWMNY-UHFFFAOYSA-N. | |
| Resins For Solid-Phase Peptide And Organic Synhesis | Resins For Solid-Phase Peptide And Organic Synhesis. Product ID: 1-01232. Purity: 0.99. |  |
| rHis-tag Two Phase Purification System, BioSeparation | BioSeparation rHis-tag Two Phase Protein Purification System is based on the use of two aqueous components. The method relies on the preferential partitioning of polyhistidine tagged proteins in one of the two phase components, allowing recombinant protein separation and purification from celular extracts or culture media. Group: Molecular Biology. Pack Sizes: 20ml, 80ml. US Biological Life Sciences. |  Worldwide |
| rHis-tag Two Phase Purification System, Elution Solution (2X), BioSeparation | BioSeparation rHis-tag Two Phase Protein Purification System is based on the use of two aqueous components. The method relies on the preferential partitioning of polyhistidine tagged proteins in one of the two phase components, allowing recombinant protein separation and purification from celular extracts or culture media. Group: Molecular Biology. Pack Sizes: 40ml. US Biological Life Sciences. | Worldwide |
| rHis-tag Two Phase Purification System, Lower Solution, BioSeparation | BioSeparation rHis-tag Two Phase Protein Purification System is based on the use of two aqueous components. The method relies on the preferential partitioning of polyhistidine tagged proteins in one of the two phase components, allowing recombinant protein separation and purification from celular extracts or culture media. Group: Molecular Biology. Pack Sizes: 20ml. US Biological Life Sciences. | Worldwide |
| rHis-tag Two Phase Purification System, LYT 2-Phase Wash Solution (2X), BioSeparation | BioSeparation rHis-tag Two Phase Protein Purification System is based on the use of two aqueous components. The method relies on the preferential partitioning of polyhistidine tagged proteins in one of the two phase components, allowing recombinant protein separation and purification from celular extracts or culture media. Group: Molecular Biology. Pack Sizes: 30ml. US Biological Life Sciences. | Worldwide |
| rHis-tag Two Phase Purification System, Top Solution, BioSeparation | BioSeparation rHis-tag Two Phase Protein Purification System is based on the use of two aqueous components. The method relies on the preferential partitioning of polyhistidine tagged proteins in one of the two phase components, allowing recombinant protein separation and purification from celular extracts or culture media. Group: Molecular Biology. Pack Sizes: 10ml. US Biological Life Sciences. | Worldwide |
| ScAl3C3 MAX phase material | ScAl3C3 MAX phase material. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. 0.99. | |
| STAT3 Control Cell Extracts (Signal Transducer and Activator of Transcription 3, Acute-phase Response Factor, APRF) | Stat3 is a key signaling molecule for many cytokines and growth-factor receptors and is required for murine fetal development. Additionally, Stat3 is constitutively activated in a number of human tumors and possesses oncogenic potential and anti-apoptotic activities. Stat3 is activated by tyrosine phosphorylation at Tyr705, which induces dimerization, nuclear translocation and DNA binding. Transcriptional activation seems to be regulated by serine phosphorylation at Ser727, apparently via the MAPK or mTOR pathways. Stat3 isoform expression appears to reflect biological function: the relative expression levels of Stat3alpha (86kD) and Stat3beta (79kD) depend on cell type, ligand exposure or maturation stage of the cells. It is notable that Stat3beta lacks the serine phosphorylation site within the C-terminal transcriptional activation domain. Group: Biologicals. Grades: Lysate. Pack Sizes: 10Blots. US Biological Life Sciences. | Worldwide |
| Ta2AlC MAX phase ceramic material | Ta2AlC MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, high-temperature heating materials. Group: Mxenes materials. ≥99%. | |
| Ta4AlC3 (MAX) Phase Ceramic Material | Ta4AlC3 (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. CAS No. 12070-06-3. ≥90%. | |
| Ta4AlC3 MAX phase material | Excellent Mxene precursor can be processed by HF or HCl+LiF to obtain MXene. 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. | |
| Tangerine Water Phase | Water Phase Aroma. Uses: Flavors, Fragrances, Aroma Therapy. Group: Essences. Grade: Food. Pack Sizes: Pails to Drums. | Bradenton, FL |
| Ti2AlC composite Ti3AlC2 MAX phase material | Ti2AlC composite Ti3AlC2 MAX phase material. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 12537-81-4. 0.99. | |
| Ti2AlC MAX phase ceramic material | Ti2AlC MAX phase ceramic 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. ≥99%. | |
| Ti2AlC MAX phase material | Ti2AlC MAX phase material. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. 0.99. | |
| Ti2AlN MAX phase ceramic material | Ti2AlN MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. ≥98%. | |
| Ti2AlN (MAX) Phase Ceramic Material | Ti2AlN (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >80%. | |
| Ti2AlN MAX phase material | Excellent Mxene precursor can be processed by HF or HCl+LiF to obtain MXene. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. 0.99. | |
| Ti2SnC MAX phase ceramic material | Ti2SnC MAX phase ceramic 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. ≥98%. | |
| Ti2TaAlC2 (MAX) Phase Ceramic Material | Ti2TaAlC2 (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >90%. | |
| Ti2VAlC2 MAX phase ceramic material | Excellent Mxene precursor can be processed by HF or HCl+LiF to obtain MXene. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. 0.99. | |
| Ti2VAlC2 (MAX) Phase Ceramic Material | Ti2VAlC2 (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >90%. | |
| Ti3Al (C0.5N0.5) 2 MAX phase material | Ti3Al (C0.5N0.5) 2 MAX phase material. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 196506-01-1. 0.99. | |
| Ti3AlC2 (MAX) Phase Ceramic Material | Ti3AlC2 (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. CAS No. 196506-01-1. ≥90%. | |
| Ti3AlC2 (MAX) Phase Ceramic Material (400 mesh) | Ti3AlC2 (MAX) Phase Ceramic Material (400 mesh). Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. CAS No. 196506-01-1. ≥80%. | |
| Ti3AlC2 MAX phase 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. ≥99.5%. | |
| Ti3AlC2 max phase target | Ti3AlC2 max phase target. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 196506-01-1. 0.99. | |
| Ti3AlCN MAX phase ceramic material | Ti3AlCN MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. ≥99%. | |
| Ti3AlCN (MAX) Phase Ceramic Material | Ti3AlCN (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >90%. | |
| Ti3GeC2 MAX phase material | Excellent Mxene precursor can be processed by HF or HCl+LiF to obtain MXene. 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. | |
| Ti3SiC2 MAX phase ceramic material | Ti3SiC2 MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. ≥99%. | |
| Ti3SiC2 max phase target | Ti3SiC2 max phase target. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. CAS No. 12202-82-3. 0.99. | |
| Ti4AlN3 (MAX) Phase Ceramic Material | Ti4AlN3 (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >99%. | |
| Ti4AlN3 MAX phase material | Excellent Mxene precursor can be processed by HF or HCl+LiF to obtain MXene. 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. | |
| TiNbAlC MAX phase ceramic material | TiNbAlC MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, high-temperature heating materials. Group: Mxenes materials. ≥99%. | |
| TiNbAlC (MAX) Phase Ceramic Material | TiNbAlC (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >90%. | |
| TiTaAlC (MAX) Phase Ceramic Material | TiTaAlC (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >90%. | |
| Titanium Dioxide Nanopowder, Anatase Phase | Produced by chemical synthesis. Loss on thempering (800°C, 2 h) about 32%. Does not contain organic stabilizers. Easy to form colloidal solution in water. Group: other s. | |
| Titanium Dioxide Nanopowder, Anatase Phase, Hydrophobic | Stabilized by dodecylphosphonic acid and hexylamine. Forms transparent colloidal solutions in chloroform. Group: other s. | |
| Titanium Dioxide Nanopowder, Rutile Phase | Readily forms colloidal solutions in water (up to 900g/L) and methanol. Group: other s. | |
| TiVAlC (MAX) Phase Ceramic Material | TiVAlC (MAX) Phase Ceramic Material. Uses: High temperature coating, mxene precursor, conductive self-lubricating ceramic, lithiumionbattery, super capacitor, electrochemical catalysis. Group: Mxene materials. >90%. | |
| TiVAlC MAX phase material | TiVAlC MAX phase material. Uses: Energy storage, catalysis, analytical chemistry, mechanics, adsorption, biology, microelectronics, sensors, etc. Group: Mxenes materials. 0.99. | |
| V2AlC MAX phase ceramic material | V2AlC MAX phase ceramic material. Uses: Max special ceramics, mxene precursors, high-temperature coating materials, conductive self-lubricating materials, electronic materials, high-temperature structural materials, chemical anti-corrosion materials, and high-temperature heating materials. Group: Mxenes materials. ≥99%. | |
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