 Go ahead, Kathy. Soclave number two is very similar. Suspected gel particles, a couple of bubbles mixed in. And I don't believe there's any zeolites here at this time. Just a glove box camera, Dave. Happy to have you. Space Lab Huntsville-Farrell, we're receiving the microscope view now. As you can see, we've got a uniform population of what I suspected, gel particles. That's about it. You can see number seven is a gel. We don't really need to switch to something else. Eight is also a gel, less viscous. Nine are gels. 11 is still a gel, and 12 is still a gel. And they all look pretty much the same and pretty much like this one. Copy that. OK, Al. The pictures that you sent back on the last run show us that the crystal lights are much bigger and better than we expected. And the red scattering that we're getting is saturating the screen, so we can't get a good reading of what the crystal structure is. So the idea is to do a run again of some of the old samples with a lower aperture setting, and also to try and homogenize the samples and get smaller crystal lights for comparison for what we get on the ground. That's where we want to do why we change procedures so we can do the samples that we've already run again. We also want to see whether they've annealed and grown bigger and things like that, because they've just grown much better than we expected. That's essentially the rationale. And since the crystal lights are much bigger, we think we can get away with a shorter run for the averaging for the Bragg scattering. Sounds good to me. And it's nice to hear that you're getting something unexpected but on a positive name. Copy. They're beautiful pictures and beautiful crystals. And I'd like a question on homogenization procedure. We are now receiving live video downlink from inside the Glovebox facility. The Colloidal Disorder Order Transition Experiment, or CDOT, is being performed in this Glovebox facility at the moment. Earlier in the mission, this experiment was set up and at various times throughout the mission, crew members set up cameras in the Glovebox facility in order to view the progress of the crystals that are growing in this colloidal solution. We are now receiving live video downlink looking at the top view of the Drop Physics Module Chamber. The experiment team on the ground has the capability to view both of these experiment cameras simultaneously due to the high-packed digital television technology demonstration. The direction of the force being applied to the drop is from the top and the bottom. This causes the drop to be squeezed or compressed in the center and causes the drop to elongate in a horizontal direction. If you look at the top view of this drop on the left side of the screen, you can see that there is very little change in the dimensions of the drop looking at the top. However, from the side, looking from the side or the right hand view, the drop continues to be compressed from the top and bottom directions of the vertical direction. As Kathy Thornton continues to increase the strength of the acoustic force that is compressing this drop, the width of the drop continues to become larger and the height continues to decrease. The experiment team for this experiment is looking, we are receiving live video downlink from a brag camera that is located in the glove box facility. This is used on the colloidal disorder order transition experiment. This is an experiment that looks at glass spheres to look at how liquids form solids. These glass spheres are used because the forces that act on these glass spheres are very simple and they can be used to model other materials that would be composed of atoms. These atoms would have a much more complicated force acting upon these atoms and therefore the interaction of the liquid and the solid would be much more difficult to understand. So they use these glass spheres in order to look at the transition that these glass spheres go through when they change from a liquid state to a solid state. The equipment seen here is part of an apparatus designed to help meet the needs of growing food and plant items in space. Right now we're looking at some footage of a potato plant being grown aboard the Space Shuttle Columbia right now. The special systems built into the astroculture equipment include systems for the delivery of nutrients to the plants. The modes for fluid flow and fluid delivery to the plants are different in the microgravity environment of space and the astroculture team has developed specialized equipment to help feed and water the potato plant we see growing here. Additionally, they have developed subsystems which provide for the control of the humidity or the level of water in the air around the plant. And also they've developed some special lighting systems which are very low power consumption lighting systems so that they're very efficient for use in the spacecraft environment. It's Huntsville, go ahead. Edgy, it's Mike L.A. Good morning. Listen, I was wondering if we could get a head start on the PAO event set up and be able to reconfigure some of the switches down here with the VAS. Stand by L.A. and I'll check for you and let you know. And payload specialist Fred Leslie is taking a brief exercise break before his shift will begin in a short while. What I wanted to do was take your DPM2 orbital one slash high-pact two channel. So I could use the orbital one channel for something else. Copy that L.A. and that'll be fine. You can go ahead and do that.