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GRAdient Driven FLuctuation EXperiment (GRADFLEX)


    GRADFLEX on frront-cover of Applied Optics
 
    GRADFLEX on frront-cover of Applied Optics  
    Foton-M3 satellite  
    Foton-M3 satellite  
    Gradient driven fluctuations visible with a shadowgraph  
    Gradient driven fluctuations visible with a shadowgraph  
    GRADFLEX Sample Degassing Configuration  
    GRADFLEX Sample Degassing Configuration  
    GRADFLEX Sample Filling  
    GRADFLEX Sample Filling  
       
       
     
   

The GRAdient Driven FLuctuation EXperiment (GRADFLEX) involves the investigation of fluctuations induced in simple fluids and in binary mixtures by imposing a macroscopic temperature or concentration gradient under microgravity conditions. Recent experiments have shown that giant nonequilibrium fluctuations are present during diffusion processes in liquid mixtures and in the presence of a heat flux through a fluid. These fluctuations occur at all length scales between the microscopic and a macroscopic scale set by the sample dimensions. The fluctuations are due to corrugations in the diffusing front, whose fractal properties explain the presence of fluctuations involving all length scales. The fluctuations are generated by coupling between velocity fluctuations and the macroscopic gradient (concentration or temperature) which drives the flux. The amplitude of these fluctuations diverges as q-4, where q is the wave vector of the fluctuation. Long wavelength fluctuations are stabilized by gravity, which quenches the q-4 divergence at the smallest wave vectors.

On Earth, gravity suppresses the long wavelength fluctuation below a typical cutoff wave vector. The aim of the GRADFLEX project is to investigate these fluctuations in the absence of gravity, where the long wavelength fluctuations are no longer predicted to be stabilized by gravity, and to compare the results with those obtained on Earth. Many materials science processes (for example, crystallization and growth of materials) are performed in microgravity because of advantages expected from the absence of convection. However, the presence of nonequilibrium fluctuations could lead to the unexpected presence of large scale inhomogeneities that could impair processing under microgravity conditions.

Two prototype systems to guide the engineering of flight hardware have been developed, one in the Optics and Microgravity Laboratory at the University of Milan by the Istituto Nazionale per la Fisica della Materia (INFM) and one in the Physics Department at the University of California at Santa Barbara (UCSB). Both systems use the shadowgraph method to measure the fluctuations. The system developed at INFM is devoted to the investigation of concentration fluctuations occurring during a Soret induced mass diffusion process, while that developed at UCSB is designed to investigate fluctuations induced by a thermal gradient in a single-component fluid. The project is scheduled for flight in 2008 onboard the Russian satellite capsule FOTON M3.

The current sensitivity of the shadowgraph method is now sufficiently developed to measure the scattering from the fluctuations, both on Earth and in microgravity. Samples are contained between parallel sapphire windows to provide the necessary thermal boundary conditions. The fluctuations give rise to phase perturbations in the wavefronts of a beam of light passing through the sample, resulting in measurable intensity modulation a sufficient propagation distance beyond the sample. This intensity modulation is time-dependent, and it can be analyzed to obtain both the mean squared amplitude of the fluctuations S(q), and their power spectrum S(q,ω), for wave vectors as small as 20 cm-1. Thus the method is useful well below the range where small angle light scattering is typically impossible because of stray light and other effects. The resulting data are the product of S(q) and the shadowgraph transfer function T(q) = Sin2 (q2z/2ko).


Objective


• Study gradient driven density and concentration fluctuations that are strongly enhanced in fluids by the absence of gravity.

• Achieve a quantitative understanding of gradient driven fluctuations, both on Earth and in the microgravity environment provided during a Foton-M3 mission.



Relevance / Impact


• In reduced gravity, gradients drive giant fluctuations that may impact processes such as crystal growth.

• This experiment was featured on the front-cover of the April 1, 2006 issue of Applied Optics.



Development Approach


• ESA / ESTEC is funding the flight hardware and provides ground-based support in Italy.

• NASA funding allowed the development of essential prototype hardware and provides ground-based support in the U.S.





Project Management:


Contacts at NASA Glenn Research Center

Project Manager: Dr. William V. Meyer, NCSER at NASA GRC
william.v.meyer@nasa.gov
216-433-5011

Project Scientist: Dr. William V. Meyer, NCSER at NASA GRC
william.v.meyer@nasa.gov
216-433-5011

Principal Investigator: Professor David Cannell, UCSB

 

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