methy­lam­mo­ni­um iodide CAS 14965-49-2

• Iden­ti­fi­ca­tion
• Prop­er­ties
• Safe­ty Data
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Iden­ti­fi­ca­tion

CAS Number

14965-49-2

Name

methy­lam­mo­ni­um iodide

Syn­onyms

14965-49-2 [RN]
239-037-4 [EINECS]
Great­cell Solar(R)
Iodure de méthanamini­um [French] [ACD/IUPAC Name]
Methanamine hydri­o­dide
Methanamine, hydri­o­dide
Methanamini­um iodide [ACD/IUPAC Name]
Methanamini­um, iodide (1:1) [ACD/​Index Name]
Methanamini­u­mio­did [Ger­man] [ACD/IUPAC Name]
Methy­lamine hydri­o­dide
Methy­lamine hydroio­dide
methy­lam­mo­ni­um iodide
MFCD28100833
Monomethy­lam­mo­ni­um iodide
N-methy­lam­­mo­ni­um iodide
[14965-49-2] [RN]
98%
hydroio­dide
Methanamine [ACD/​Index Name] [ACD/IUPAC Name]
methanamine hydroio­dide
Methanamine, hydri­o­dide (9CI)
Methanamine, hydri­o­dide(9CI)
methyl ammo­ni­um iodide
methy­lamine hydroio­dide (low water con­tent)
METHY­LAMINE HYDROIO­DIDE|METHANAMINE HYDROIO­DIDE
methylaminehydroiodide(lowwatercontent)

SMILES

C[NH3+].[I-]

Std­InChI

InChI=1S/CH5N.HI/c1-2;/h2H2,1H3 ;1H

Std­InChIKey

LLWRX­QX­PJM­PHLR-UHF­F­­FAOYSA-N

Mol­e­c­u­lar Formula

CH₆IN

Mol­e­c­u­lar Weight

158.969

MDL Number

MFCD28100833

Prop­er­ties

Appear­ance

White pow­der

Safe­ty Data

Sym­bol

GHS07

Sig­nal Word

Warn­ing

Haz­ard statements

Pre­cau­tion­ary Statements

RIDADR 

NONH for all modes of transport

WGK Germany

3

MSDS Download

Spec­i­fi­ca­tions and Oth­er Infor­ma­tion of Our methy­lam­mo­ni­um iodide CAS 14965-49-2

Iden­ti­fi­ca­tion Methods

HNMR

Puri­ty

99.99%min

Car­bon Content

7.3% ~7.8 %

Nitro­gen Conten

8.5% ~ 9.0 %

Shelf Life

1 year

Stor­age

Under room tem­per­a­ture away from light, Oxy­­gen-proof, water-proof, light-proof, low-humid­i­­ty, dry storage.

Known Appli­ca­tion

Methy­lam­mo­ni­um iodide (MAI), based on alkyl halides like iodides and bro­mides, serves as a cru­cial pre­cur­sor for the prepa­ra­tion of per­ovskite mate­ri­als used in pho­to­volta­ic appli­ca­tions. When com­bined with lead iodide (PbI₂), MAI plays a key role in form­ing methy­lam­mo­ni­um lead iodide per­ovskites (MAP­bI₃), which sig­nif­i­cant­ly impact the mor­phol­o­gy and crys­tal­liza­tion of the per­ovskite struc­ture. This mod­i­fi­ca­tion of the material’s struc­ture can improve its opto­elec­tron­ic prop­er­ties, mak­ing it high­ly effi­cient for ener­­gy-har­vest­ing applications.

Per­ovskite mate­ri­als are known for their excel­lent light absorp­tion, charge car­ri­er mobil­i­ty, and tun­able bandgaps, mak­ing them ide­al for use in next-gen­er­a­­tion ener­gy devices. In par­tic­u­lar, MAI-based per­ovskites are cen­tral to the devel­op­ment of per­ovskite solar cells (PSCs), which have shown rapid effi­cien­cy improve­ments in recent years. In addi­tion to their poten­tial in solar cells, these per­ovskite mate­ri­als are also being explored in the pro­duc­tion of light-emit­t­ing diodes (LEDs), offer­ing a promis­ing alter­na­tive for high-effi­­cien­­cy light­ing and dis­play technologies.

As the world shifts towards renew­able ener­gy, per­ovskite-based devices, enabled by pre­cur­sors like methy­lam­mo­ni­um iodide, are poised to play a crit­i­cal role in advanc­ing sus­tain­able ener­gy solutions.

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This prod­uct is devel­oped by our R&D com­pa­ny Warshel Chem­i­cal Ltd (https://​www​.warshel​.com/).

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