1. Elena Cox, Ph. D., Curriculum & Instruction, Texas A&M University, Commerce The 7 th Annual Texas STEM Conference Dallas February 6, 2014

2.  Research Experience for Teachers (RET) program at Georgia Institute of Technology  Research team at Mechanical Engineering worked with developing and designing microelectromechanical gas sensors

3. Air Clothing Rules of behavior and safety Introduction to the latest equipment and advances in science and technology available in the area of nanotechnology.

4.  Micro gas sensors are fabricated on silicon wafers which I saw there for the first time.

5.  One thing is to see the pictures of computer chips in textbooks, and another thing is to actually to learn how to make them yourself.

6.  The professor in charge of the research team has more than 200 patents and supervises a research group of graduate students, always found the time to introduce me to microelectronic fabrication and to teach me how to work with silicon wafers.

7.  Most of the time during the Summer RET program was spent learning about and working with nano photolithography

8. As a part of research team, I was allowed to work in a clean room performing the following operations:  Spinning of photoresist:

9.  Aligning the mask:

10.  Developing photoresist:

11.  The pattern quality check by using profilometer and a microscope:

12.  Chemical and plasma etching

13.  Cutting the wafer and glass bonding:

14.  All this work was required to manufacture a gas chromatographic column less than 1/3 of an inch but 2 meters long.

15. (4) Science concepts. The student knows the characteristics of matter and can analyze the relationships between chemical and physical changes and properties. The student is expected to: (D) classify matter as pure substances or mixtures through investigation of their properties.

16. http://en.wikipedia.org/wiki/Gas_chromatography

20. 2 cm

21. Noh et al., 2002

22. Noh, 2004

23. Noh et al., 2002

24.  I could talk to students about the properties of atoms in more detail because I was working with structures on atomic level.  I was able to develop a lesson plan and conduct a lesson based on the knowledge I gained during RET on chromatography pertaining in a separation of mixtures unit.

25. The chromatography lesson was presented at teacher conferences in Washington and San Francisco.

30. In your bag: small bowl coffee filters droppers Plate 2 Clear drinking glasses filled with water Drinking glass filled with salt water Skittles, Gobstoppers, M&M's Ruler Pencil Food colors Silica gel

31.  Put silica gel into one of the clear glasses filled with water. Wait for about 1 minute for crystals to absorb water.

32.  Using dropper, put several drops of food color mixture on the silica gel after it increase in size.

33.  Put silica gel into one of the clear glasses filled with water. Wait for about 1 minute for crystals to absorb water.  Using dropper, put several drops of food color mixture on the silica gel after it increase in size.  Pour some water over the silica gel/the drops.

35.  What do you observe?  What food colors were mixed?

36.  Take the unused tall clear glass filled with water covering the bottom of the glass.

37.  Take a strip of filter paper. Roll it over the Q- tip

38.  Take the unused tall clear glass filled with water covering the bottom of the glass.  Take a strip of filter paper. Roll it over the Q- tip  Using a pencil and a ruler, draw the line about ¼” from the edge of the paper  Mark a dot where you will put your separation mixture with a pencil

39.  Take the unused tall clear glass filled with water covering the bottom of the glass.  Take a strip of filter paper. Roll it over the Q- tip  Using a pencil and a ruler, draw the line about ¼” from the edge of the paper  Mark a dot where you will put your separation mixture with a pencil

40.  Using a dropper, put one drop of a food color mixture on the dot on the filter paper

41.  Carefully place the Q-tip with filter paper inside your glass with water.  Wait for the water to start rising on the filter paper.

43.  What changes of your dot do you observe?  What colors do you think were mixed together? Can you tell the difference between colors?

44.  Take out a dinner plate and lay one of each color of Skittles, leaving a little space around each one.

45.  Using a pipette or dropper, squeeze a little water onto each piece of candy to start dissolving the shell.

46.  While you wait for the candy to dissolve, draw a pencil line about 2 cm from the bottom edge of the paper. Do not use pen, because the ink will run. This is your origin line.

47.  When the water around the candy has turned color, squeeze the colored water into the pipette bulb.

48.  Drop a few drops of colored water on the origin line on your filter paper. You may need to add several drops to ensure you have enough dye.

49.  Repeat this with each color, leaving about 2 cm between each color

50.  Let the filter paper dry completely.

51.  Place filter paper in the glass with salt water so that it is standing up and the bottom is barely touching the surface of the salt solution.

52.  You can tape the top of the filter paper to a pencil and hang it down into the solution if you have a hard time getting it to stay right at the surface.

53.  Observe the salt water rising up the paper by capillary action until it is almost at the top.

54.  Remove the paper from the glass and mark with a pencil where the solvent stopped.

55.  Let the paper dry completely.

56.  Repeat the experiment using M&M's, Gobstoppers or other dyed candy and compare like colors. Is the red dye the same in all of the candies, or do the colors run differently?