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Merck
CN

244651

Sigma-Aldrich

Tin(IV) oxide

greener alternative

−325 mesh, 99.9% trace metals basis

Synonym(s):

Stannic dioxide, Tin dioxide, Stannic oxide

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About This Item

Linear Formula:
SnO2
CAS Number:
18282-10-5
Molecular Weight:
150.71
EC Number:
242-159-0
MDL number:
MFCD00011244
UNSPSC Code:
12352303
PubChem Substance ID:
57648084
NACRES:
NA.23

Key Documents

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Quality Level

100

Assay

99.9% trace metals basis

form

powder

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Design for Energy Efficiency
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particle size

−325 mesh

density

6.95 g/mL at 25 °C (lit.)

application(s)

battery manufacturing

greener alternative category

Enabling

SMILES string

O=[Sn]=O

InChI

1S/2O.Sn

InChI key

XOLBLPGZBRYERU-UHFFFAOYSA-N

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General description

Tin(IV) oxide (SnO2) is an n-type wide band gap semiconductor with high transmittance at nearIR and visible region. It is scratch resistant and chemically inert.
We are committed to bringing you Greener Alternative Products, which belong to one of the four categories of greener alternatives. Tin oxide enhances lithium-ion batteries with high energy density, improved cycling stability, and efficient charge/discharge rates, supporting more sustainable energy storage. Click here for more information.

Application

Tin(IV) oxide has been used to prepare thin films of TiO2-doped SnO2 oxide nanocomposites.

It can be used as astarting material to prepare niobium and zinc-doped titanium-tin-oxidesolid-solution ceramics, which are applicable in the field of electronicdevices.

Storage Class Code

11 - Combustible Solids

WGK

nwg

Flash Point(F)

Not applicable

Flash Point(C)

Not applicable

Personal Protective Equipment

dust mask type N95 (US), Eyeshields, Gloves

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Certificates of Analysis (COA)

Lot/Batch Number
0000329495
0000329495
MKCT6155
MKCS9166
MKCR0354

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Jaewon Jang et al.
Advanced materials (Deerfield Beach, Fla.), 25(7), 1042-1047 (2012-11-20)
This work employs novel SnO(2) gel-like precursors in conjunction with sol-gel deposited ZrO(2) gate dielectrics to realize high-performance transparent transistors. Representative devices show excellent performance and transparency, and deliver mobility of 103 cm(2) V(-1) s(-1) in saturation at operation voltages
Hui Song et al.
Nanoscale, 5(3), 1188-1194 (2013-01-10)
One-dimensional (1-D) SnO(2) nanorods (NRs) with a rutile structure are grown on various substrates regardless of the lattice-mismatch by using a new nutrient solution based on tin oxalate, which generated supersaturated Sn(2+) sources. These affluent sources are appropriate for producing
Yinzhu Jiang et al.
ACS applied materials & interfaces, 4(11), 6216-6220 (2012-10-31)
Porous SnO₂/graphene composite thin films are prepared as anodes for lithium ion batteries by the electrostatic spray deposition technique. Reticular-structured SnO₂ is formed on both the nickel foam substrate and the surface of graphene sheets according to the scanning electron
Linlin Li et al.
Nanoscale, 5(1), 134-138 (2012-11-14)
Novel eggroll-like CaSnO(3) nanotubes have been prepared by a single spinneret electrospinning method followed by calcination in air for the first time. The electrospun sample as a lithium-ion battery electrode material exhibited improved cycling stability and rate capability by virtue
Ilsun Yoon et al.
Nanoscale, 5(2), 552-555 (2012-12-13)
Here we demonstrate a facile method of quantifying the decaying optical field surrounding free-standing tin dioxide (SnO(2)) nanofiber waveguides. Through the use of thin self-assembled polyelectrolyte coatings and fluorescent optical transmitters we map out the optical intensity as a function
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