929727
ElectroGreen®
Methyl Amyl Ketone substitute for electronics, bio-sourced
About This Item
Recommended Products
vapor pressure
6.4 mmHg ( 20 °C)
Quality Level
description
Relative Evaporation rate: 0.247
Hansen SolubilityParameters: SPd = 7.7; SPp = 3.4; SPh = 6.7
Assay
99% (GC)
form
liquid
greener alternative product characteristics
Design for Energy Efficiency
Use of Renewable Feedstocks
Learn more about the Principles of Green Chemistry.
impurities
≤0.09 wt. % Acidity (as lactic acid)
≤0.2% Water (Karl Fischer)
≤1 ppm As, Cr, Cd, Cu, Hg, Mn, Ni, Pb, Zn, trace (each)
evapn. residue
≤0.05%
color
colorless
viscosity
15.7 cP(20 °C)
bp
111 °C
greener alternative category
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General description
This solvent blend consists of Ethyl lactate 50-70%, iso-butanol 30-50%.
Application
Additionally, it is an excellent solvency for ink formulations with 20% to 30% more efficient in viscosity reduction than MAK, and it allows high loading capacity on ink formulations.
Storage and Stability
Legal Information
Signal Word
Danger
Hazard Statements
Precautionary Statements
Hazard Classifications
Eye Dam. 1 - Flam. Liq. 3 - Skin Irrit. 2 - STOT SE 3
Target Organs
Central nervous system, Respiratory system
Storage Class Code
3 - Flammable liquids
WGK
WGK 1
Flash Point(F)
102.2 °F
Flash Point(C)
39 °C
Certificates of Analysis (COA)
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Articles
Carbon-based Sustainable Organic Electronics (SOE) limit the use of critical elements and biodegrade at their end-of-life. This review offers insight on how structural and energy disorder in these materials influence device performance and includes evaluations of various transport models and their limitations.
Carbon-based Sustainable Organic Electronics (SOE) limit the use of critical elements and biodegrade at their end-of-life. This review offers insight on how structural and energy disorder in these materials influence device performance and includes evaluations of various transport models and their limitations.
Carbon-based Sustainable Organic Electronics (SOE) limit the use of critical elements and biodegrade at their end-of-life. This review offers insight on how structural and energy disorder in these materials influence device performance and includes evaluations of various transport models and their limitations.
Carbon-based Sustainable Organic Electronics (SOE) limit the use of critical elements and biodegrade at their end-of-life. This review offers insight on how structural and energy disorder in these materials influence device performance and includes evaluations of various transport models and their limitations.
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