LINQBOND SMA3611 | SMT Chipbonder
Main features
- solvent-free
- low stress
- low water absorption
Product Description
LINQBOND SMA3611 is a one-component epoxy designed for chip bonding. This resin has medium viscosity and thixotropy. It cures at low temperatures and is suitable for screen printing and dispensing applications. The resin forms strong cured shapes without stringing or slumping, even at high-speed dispensing and with very small dots. The hardened surface does not exhibit surface oiliness.
Once cured, LINQBOND SMA3611 offers good adhesive strength, electrical insulation properties, and excellent chemical and solvent resistance. Stable adhesive strength can be achieved with various SMT (Surface-Mount Technology) applications. This product is well-suited for electronic device encapsulation and chip bonding.
Technical Specifications
General Properties | |||||||
Appearance Appearance Appearance at room temperature. | Red liquid | ||||||
Pot Life Pot Life Pot life is the amount of time it takes for the viscosity of a material to double (or quadruple for lower viscosity materials) in room temperature after a material is mixed. It is closely related to work life but it is not application dependent, less precise and more of a general indication of how fast a system is going to cure. | 72 hours | ||||||
Specific Gravity Specific Gravity Specific gravity (SG) is the ratio of the density of a substance to the density of a reference substance; equivalently, it is the ratio of the mass of a substance to the mass of a reference substance for the same given volume. For liquids, the reference substance is almost always water (1), while for gases, it is air (1.18) at room temperature. Specific gravity is unitless. | 1.36 | ||||||
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Physical Properties | |||||||
Thixotropic index Thixotropic index Thixotropic Index is a ratio of a material s viscosity at two different speeds in Ambient temperature, generally different by a factor of ten. A thixotropic material s viscosity will decrease as agitation or pressure is increased. It indicates the capability of a material to hold its shape. Mayonnaise is a great example of this. It holds its shape very well, but when a shear stress is applied, the material easily spreads. It helps in choosing a material in accordance to the application, dispense method and viscosity of a material. | 7–8.2 | ||||||
Viscosity Viscosity Viscosity is a measurement of a fluid’s resistance to flow. Viscosity is commonly measured in centiPoise (cP). One cP is defined as the viscosity of water and all other viscosities are derived from this base. MPa is another common unit with a 1:1 conversion to cP. A product like honey would have a much higher viscosity -around 10,000 cPs- compared to water. As a result, honey would flow much slower out of a tipped glass than water would. The viscosity of a material can be decreased with an increase in temperature in order to better suit an application | 450000 - 750000 mPa.s | ||||||
Chemical Properties | |||||||
Water Absorption | 0.17 % | ||||||
Electrical Properties | |||||||
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Surface Resistivity | 4.5 × 10(E14) Ohms/sq | ||||||
Volume Resistivity Volume Resistivity Volume resistivity, also called volume resistance, bulk resistance or bulk resistivity is a thickness dependent measurement of the resistivity of a material perpendicular to the plane of the surface. | 2.2x10(E15) Ohms⋅cm | ||||||
Mechanical Properties | |||||||
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Thermal Properties | |||||||
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Degradation temperature Degradation temperature The temperature at which the materials start losing their properties | 364 °C | ||||||
Glass Transition Temperature (Tg) Glass Transition Temperature (Tg) The glass transition temperature for organic adhesives is a temperature region where the polymers change from glassy and brittle to soft and rubbery. Increasing the temperature further continues the softening process as the viscosity drops too. Temperatures between the glass transition temperature and below the decomposition point of the adhesive are the best region for bonding. The glass-transition temperature Tg of a material characterizes the range of temperatures over which this glass transition occurs. | 121 °C | ||||||
Thermal Conductivity Thermal Conductivity Thermal conductivity describes the ability of a material to conduct heat. It is required by power packages in order to dissipate heat and maintain stable electrical performance. Thermal conductivity units are [W/(m K)] in the SI system and [Btu/(hr ft °F)] in the Imperial system. | 0.3 W/m.K | ||||||
Curing Conditions | |||||||
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