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Merck
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資料

安全性情報

267481

Sigma-Aldrich

チタン

foil, thickness 0.25 mm, 99.99% trace metals basis

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About This Item

実験式(ヒル表記法):
Ti
CAS番号:
7440-32-6
分子量:
47.87
EC Number:
231-142-3
MDL番号:
MFCD00011264
UNSPSCコード:
12141746
PubChem Substance ID:
24856227
NACRES:
NA.23

アッセイ

99.99% trace metals basis

形状

foil

自己発火温度

860 °F

抵抗性

42.0 μΩ-cm, 20°C

厚さ

0.25 mm

bp

3287 °C (lit.)

mp

1660 °C (lit.)

密度

4.5 g/mL at 25 °C (lit.)

アプリケーション

battery manufacturing

SMILES記法

[Ti]

InChI

1S/Ti

InChI Key

RTAQQCXQSZGOHL-UHFFFAOYSA-N

詳細

Ti has low thermal and electrical conductivity. It is highly corrosion-resistant and has a high strength to weight ratio. A few angstroms thick layer of titania on the surface of Ti products makes its corrosion resistant.5 Ti foils could be employed as a substrate to grow arrays of hematite nanorods by hydrothermal method. A study reports pressure less sintering of SiC pieces and single crystals to Ti foils at 1500oC.Ti foil may be applied as an interlayer, diffusion bonded during the self joining of Si3N4. Si3N4/Ti-foil/Si3N4.

数量

700 mg = 25 × 25 mm; 2.8 g = 50 × 50 mm

保管分類コード

11 - Combustible Solids

WGK

nwg

引火点(°F)

Not applicable

引火点(℃)

Not applicable

個人用保護具 (PPE)

Eyeshields, Gloves, type N95 (US)

適用法令

試験研究用途を考慮した関連法令を主に挙げております。化学物質以外については、一部の情報のみ提供しています。 製品を安全かつ合法的に使用することは、使用者の義務です。最新情報により修正される場合があります。WEBの反映には時間を要することがあるため、適宜SDSをご参照ください。

労働安全衛生法名称等を表示すべき危険物及び有害物

名称等を表示すべき危険物及び有害物

労働安全衛生法名称等を通知すべき危険物及び有害物

名称等を通知すべき危険物及び有害物

Jan Code

267481-VAR:
267481-2.8G-PW:
267481-BULK:
267481-700MG:
267481-700MG-PW:
267481-2.8G:

試験成績書(COA)

製品のロット番号・バッチ番号を入力して、試験成績書(COA) を検索できます。ロット番号・バッチ番号は、製品ラベルに「Lot」または「Batch」に続いて記載されています。

以前この製品を購入いただいたことがある場合

文書ライブラリで、最近購入した製品の文書を検索できます。

文書ライブラリにアクセスする

Bonding mechanism between silicon carbide and thin foils of reactive metals
Morozumi S, et al.
J. Mater. Sci., 20(11), 3976-3982 (1985)
Joining of silicon nitride with a titanium foil interlayer
Lemus J and Drew RAL
Materials Science & Engineering. A, Structural Materials : Properties, Microstructure and Processing, 352, 169-178 (2003)
Large-Scale Porous Hematite Nanorod Arrays: Direct Growth on Titanium Foil and Reversible Lithium Storage.
Song Y et al.
The Journal of Physical Chemistry C, 114(49), 21158-21164 (2010)
A Kurbad et al.
International journal of computerized dentistry, 16(2), 125-141 (2013-08-13)
This article presents two novel options for lithium-disilicate restorations supported by single-tooth implants. By using a Ti-Base connector, hybrid abutments and hybrid abutment crowns can be fabricated for different implant systems. The latter option in particular is an interesting new
J H Kim et al.
Journal of nanoscience and nanotechnology, 13(7), 4601-4607 (2013-08-02)
Nanocytalline TiN films were deposited on non-alkali glass and Al substrates by reactive DC magnetron sputtering (DCMS) with an electromagnetic field system (EMF). The microstructure and corrosion resistance of the TiN-coated Al substrates were estimated by X-ray diffraction (XRD), scanning
関連する文献をすべて表示

資料

Combinatorial Materials Science for Energy Applications

Can there be an effective strategy for finding breakthrough materials, since they are, by definition, unpredictable? One answer is found in Combinatorial Materials Science techniques, which represent a powerful approach to identifying new and unexpected materials.

Biomedical Implant Devices Fabricated from Low Young’s Modulus Titanium Alloys Demonstrating High Mechanical Biocompatibility

Biomedical implants are essentially foreign substances within the human body that must survive many years’ exposure to demanding mechanical and physiological conditions. Despite these challenges, metal implants have been widely used to substitute for or rebuild hard tissues such as bones and teeth.

Biomedical Implant Devices Fabricated from Low Young’s Modulus Titanium Alloys Demonstrating High Mechanical Biocompatibility

Biomedical implants are essentially foreign substances within the human body that must survive many years’ exposure to demanding mechanical and physiological conditions. Despite these challenges, metal implants have been widely used to substitute for or rebuild hard tissues such as bones and teeth.

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