Dark Matter eLiquid
Enjoy the wonderful flavor of our latest VapeSafe eLiquid - Dark Matter.
Dark Matter tastes like German chocolate cake. For those of you who have not had the fortunate to try a piece German chocolate cake recently, this is a great way to experience the flavor without getting any of the calories. German chocolate cake is a layered cake filled and topped with a coconut-pecan frosting. Traditionally sweet baking chocolate is used for the chocolate flavor in the actual cake. The robust filling and topping is a caramel made with egg yolks and evaporated milk. Once the caramel is cooked, coconut and pecans are stirred into the mixture. Finally, rich chocolate frosting is spread around the sides of the cake to hold in the filling.
Dark Matter eLiquid by VapeSafe captures the essence of German chocolate cake. Dark Matter eLiquid delivers plumes of vapor and rich chocolatey flavor that you'll want to enjoy again and again. Try Dark Matter today!
Technology Information:
Resonance penetration of gas bubbles through a thin liquid layer: a capillary resonator and its use for the generation of droplets [An article from: Journal of Aerosol Science]
![Resonance penetration of gas bubbles through a thin liquid layer: a capillary resonator and its use for the generation of droplets [An article from: Journal of Aerosol Science]](http://ecx.images-amazon.com/images/I/5181HBQEK2L._SL160_.jpg)
Product Type: Book
Product Price: $8.95
Manufacturer: Elsevier
Purchase
Description
This digital document is a journal article from Journal of Aerosol Science, published by Elsevier in 2004. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.
Description:
As it is well known, a bounded layer of liquid forms an oscillatory system (resonator) for surface waves. We consider a capillary wave resonator that is composed by a thin liquid layer placed on a substrate and surrounded by a solid ring. The dimensions of the system are chosen so that gravity forces are small compared with forces from surface tension. Standing capillary waves are excited by a gas flow supplied through a small orifice in the substrate. Stable oscillations in various resonator modes are described which are accompanied by ordered formation and destruction of gas bubbles producing the regular streams of identical droplets. The mechanism of self-oscillatory behaviour based on the correspondence between bubble growth time and oscillation period is proposed and analysed. Possible applications of the phenomenon, in particular, for the generation of monodisperse droplets without special periodic stimulation, are discussed.
Reviews
None