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Manganese-Doped Zinc Oxide Quantum Dots

Linear Formula:

Mn/ZnO

ORDER

PRODUCT Product Code ORDER SAFETY DATA TECHNICAL DATA
Mn/ZnO Quantum Dot - 500 nm
ZNO-MN-01-QD.500E
Pricing > SDS > Data Sheet >
Mn/ZnO Quantum Dot - 540 nm
ZNO-MN-01-QD.540E
Pricing > SDS > Data Sheet >
Mn/ZnO Quantum Dot - 580 nm
ZNO-MN-01-QD.580E
Pricing > SDS > Data Sheet >

Manganese-Doped Zinc Oxide Quantum Dots Properties

Appearance

Solid

Manganese-Doped Zinc Oxide Quantum Dots Health & Safety Information

Signal Word N/A
Hazard Statements N/A
Hazard Codes N/A
Transport Information N/A
MSDS / SDS

About Manganese-Doped Zinc Oxide Quantum Dots

Manganese-Doped ZnO Quantum Dots are structured hydrophilic nanocrystals composed of zinc oxide doped with manganese. Mn/ZnO quantum dots' spectra emission peaks ranges from 500 to 580 nm. Typical and custom packaging is available, as is additional research, technical and safety (MSDS) data. Please contact us for information on lead time and pricing above. American Elements manufactures quantum dots from several semiconductor materials, including Cadmium Telluride (CdTe), Lead Selenide (PbSe), Zinc Indium Phosphide/Zinc Sulfide (ZnInP/ZnS), Zinc Cadmium Selenide/Zinc Sulfide (ZnCdSe/ZnS), and Graphene; for more information about uses and applications for quantum dots, please see our nanomaterials page.

Manganese-Doped Zinc Oxide Quantum Dots Synonyms

N/A

Manganese-Doped Zinc Oxide Quantum Dots Chemical Identifiers

Linear Formula

Mn/ZnO

Packaging Specifications

Typical bulk packaging includes palletized plastic 5 gallon/25 kg. pails, fiber and steel drums to 1 ton super sacks in full container (FCL) or truck load (T/L) quantities. Research and sample quantities and hygroscopic, oxidizing or other air sensitive materials may be packaged under argon or vacuum. Shipping documentation includes a Certificate of Analysis and Safety Data Sheet (SDS). Solutions are packaged in polypropylene, plastic or glass jars up to palletized 440 gallon liquid totes, and 36,000 lb. tanker trucks.

Related Elements

See more Manganese products. Manganese (atomic symbol: Mn, atomic number: 25) is a Block D, Group 7, Period 4 element with an atomic weight of 54.938045. Manganese Bohr ModelThe number of electrons in each of Manganese's shells is [2, 8, 13, 2] and its electron configuration is [Ar] 3d5 4s2. The manganese atom has a radius of 127 pm and a Van der Waals radius of 197 pm. Manganese was first discovered by Torbern Olof Bergman in 1770 and first isolated by Johann Gottlieb Gahn in 1774. In its elemental form, manganese has a silvery metallic appearance. Elemental ManganeseIt is a paramagnetic metal that oxidizes easily in addition to being very hard and brittle. Manganese is found as a free element in nature and also in the minerals pyrolusite, braunite, psilomelane, and rhodochrosite. The name Manganese originates from the Latin word mangnes, meaning "magnet."

See more Zinc products. Zinc (atomic symbol: Zn, atomic number: 30) is a Block D, Group 12, Period 4 element with an atomic weight of 65.38. The number of electrons in each of zinc's shells is 2, 8, 18, 2, and its electron configuration is [Ar] 3d10 4s2. Zinc Bohr ModelThe zinc atom has a radius of 134 pm and a Van der Waals radius of 210 pm. Zinc was discovered by Indian metallurgists prior to 1000 BC and first recognized as a unique element by Rasaratna Samuccaya in 800. Zinc was first isolated by Andreas Marggraf in 1746. In its elemental form, zinc has a silver-gray appearance. It is brittle at ordinary temperatures but malleable at 100 °C to 150 °C.Elemental Zinc It is a fair conductor of electricity, and burns in air at high red producing white clouds of the oxide. Zinc is mined from sulfidic ore deposits. It is the 24th most abundant element in the earth's crust and the fourth most common metal in use (after iron, aluminum, and copper). The name zinc originates from the German word "zin," meaning tin.

Recent Research

A novel one-step strategy toward ZnMn2O4/N-doped graphene nanosheets with robust chemical interaction for superior lithium storage., Wang, Dong, Zhou Weiwei, Zhang Yong, Wang Yali, Wu Gangan, Yu Kun, and Wen Guangwu , Nanotechnology, 2016 Jan 29, Volume 27, Issue 4, p.045405, (2016)

Toxicity of antimony, copper, cobalt, manganese, titanium and zinc oxide nanoparticles for the alveolar and intestinal epithelial barrier cells in vitro., Titma, T, Shimmo R, Siigur J, and Kahru A , Cytotechnology, 2016 Dec, Volume 68, Issue 6, p.2363-2377, (2016)

Insights into the effects of zinc doping on structural phase transition of P2-type sodium nickel manganese oxide cathodes for high-energy sodium ion batteries., Wu, Xuehang, Xu Gui-Liang, Zhong Guiming, Gong Zhengliang, McDonald Matthew J., Zheng Shiyao, Fu Riqiang, Chen Zonghai, Amine Khalil, and Yang Yong , ACS Appl Mater Interfaces, 2016 Aug 5, (2016)

Shaping and compositional modification of zinc oxide nanowires under energetic manganese ion irradiation., Möller, Wolfhard, Johannes Andreas, and Ronning Carsten , Nanotechnology, 2016 Apr 29, Volume 27, Issue 17, p.175301, (2016)

Synthesis and loading-dependent characteristics of nitrogen-doped graphene foam/carbon nanotube/manganese oxide ternary composite electrodes for high performance supercapacitors., Cheng, Tao, Yu Baozhi, Cao Linli, Tan Huiyun, Li Xinghua, Zheng Xinliang, Li Weilong, Ren Zhaoyu, and Bai Jinbo , J Colloid Interface Sci, 2017 Sep 01, Volume 501, p.1-10, (2017)

Formation and stability of manganese-doped ZnS quantum dot monolayers determined by QCM-D and streaming potential measurements., Oćwieja, Magdalena, Matras-Postołek Katarzyna, Maciejewska-Prończuk Julia, Morga Maria, Adamczyk Zbigniew, Sovinska Svitlana, Żaba Adam, Gajewska Marta, Król Tomasz, Cupiał Klaudia, et al. , J Colloid Interface Sci, 2017 Oct 01, Volume 503, p.186-197, (2017)

Facile hydrothermal synthesis of urchin-like cobalt manganese spinel for high-performance supercapacitor applications., Venkateswarlu, Pamidi, Umeshbabu Ediga, U Kumar Naveen, Nagaraja Pernapati, Tirupathi Patri, G Rao Ranga, and Justin Ponniah , J Colloid Interface Sci, 2017 Oct 01, Volume 503, p.17-27, (2017)

Removal of thallium from aqueous solutions using Fe-Mn binary oxides., Li, Huosheng, Chen Yongheng, Long Jianyou, Li Xiuwan, Jiang Daqian, Zhang Ping, Qi Jianying, Huang Xuexia, Liu Juan, Xu Ruibing, et al. , J Hazard Mater, 2017 May 25, Volume 338, p.296-305, (2017)

Designing of carbon based fluorescent nanosea-urchin via green-synthesis approach for live cell detection of zinc oxide nanoparticle., Choudhary, Raksha, Patra Santanu, Madhuri Rashmi, and Sharma Prashant K. , Biosens Bioelectron, 2017 May 15, Volume 91, p.472-481, (2017)

Permanganate-based synthesis of manganese oxide nanoparticles in ferritin., Olsen, Cameron R., Smith Trevor J., Embley Jacob S., Maxfield Jake H., Hansen Kameron R., J Peterson Ryan, Henrichsen Andrew M., Erickson Stephen D., Buck David C., Colton John S., et al. , Nanotechnology, 2017 May 12, Volume 28, Issue 19, p.195601, (2017)

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June 23, 2017
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