Shannon Cattie. How does temperature affect the rate of aggregation of colloidal gold?
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The Effect of Temperature on the Aggregation of Colloidal Gold Shannon Cattie
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Transcript of Shannon Cattie. How does temperature affect the rate of aggregation of colloidal gold?
The Effect of Temperature on the Aggregation of Colloidal Gold
Shannon Cattie
Problem
How does temperature affect the rate of aggregation of colloidal gold?
Background Information
What is Colloidal Gold? Binary liquid mixture, containing gold nanoparticles Can be ingested orally to treat arthritis, hypertension, skin
conditions, heart rhythm, depression, inflammation, circulation, pain and stress relief, nerve complaints, and act as an IQ booster
History of Colloidal Gold Appearance in the Old Testament of the Bible (Exodus 32) ▪ Moses makes a make-shift colloidal gold to cure the impatience and
disobedience of the nation of Israel Alexandria, Egypt▪ Alchemists discussed the Elixir of Life▪ 16th century: alchemist, Paracelsus, founded the school of iatrochemistry,
the chemistry of medicines - beginning of modern pharmacology Ancient Rome▪ Used to stain glass a deep red
Used for photography in 1842 in the process of crysotype
Background Information
Nanotechnology Deals with processes that take place on the
nanometer scale, which is one billionth of a meter. Properties of metals are different on the Nano scale
than in bulk.▪ Gold in bulk is a yellowish color, but gold’s nanoparticles
are a wine-red Aggregation
The formation of aggregates causing a change in color
For the most part, irreversible An aggregate is a group of particles which are held
together; they can be held together in any way
Background Information
Why add Salt to Aggregate Colloidal Gold? Gold particles in colloidal solutions are negatively charged,
so they repel each other. They cannot clump together. Salt is added:▪ Shields the negative charges▪ Able to clump together and aggregate
Why does Colloidal Gold turn Blue after Aggregation? Because of the change in the light spectra
Salt Sodium chloride Suppose to lower the temperature in which aggregation
occurs Enhances aggregation
Hypothesis
If the temperature of colloidal gold is raised, then the particles of the colloidal gold will aggregate more readily than those at lower temperatures.
Materials
Journal Pen Aluminum foil Refrigerator Thermometer A micro pipette Spectro Vis Logger Pro 10mL graduated cylinder Paper towels
Materials
TO MAKE THE COLLOIDAL GOLD
20 mL of 1mM hydrogen tetrachloroaurate solution
Distilled water 2mL of 1% trisodium
citrate solution A hot plate An Erlenmeyer flask Graduated cylinder Crucible tongs
FOR EACH TRIAL
A cuvette and cap 1000 μL of 1 M
sodium chloride solution
3mL of colloidal gold 100μL of the solution
Procedure – Making the Colloidal Gold
Make the Colloidal Gold1. Measure 20 mL of 1mM hydrogen tetrachloroaurate solution in a
graduated cylinder2. Pour the 20 mL of 1mM hydrogen tetrachloroaurate solution into a 250
mL Erlenmeyer Flask3. Add distilled water to the 200 mL mark on the Erlenmeyer flask4. Place the Erlenmeyer flask onto a hot plate and turn the hot plate on a
medium-high setting5. Bring to a gentle boiling6. Measure 2mL of 1% trisodium citrate solution using a 10 mL graduated
cylinder 7. Add the 2mL of 1% trisodium citrate solution to the boiling solution in the
Erlenmeyer flask8. Continue heating the solution at a gentle boil for about 10 minutes until
the solution is stable at a ruby or wine-red color and no longer changes color
9. After the color stabilizes, remove the Erlenmeyer flask from the hot plate and allow to cool
10. Add distilled water until the solution reaches 200 mL again
Procedure – Testing the Aggregation
1. Begin by hooking up the spectrometer to the computer and opening Logger Pro
2. Measure 3 mL of Colloidal gold into a 10 mL graduated cylinder
3. Pour it into a cuvette
4. Cap the cuvette, wipe the sides of excess liquid, and place into the spectrometer
5. Locate the peak of absorption on the graph and record
6. Heat colloidal gold to 30°C by using a hot plate, let sit for the day and accumulate to room temperature (10°C), or place in refrigerator and cool to 10°C
Procedure – Testing the Aggregation
7. Collect the location of the peak of absorption on each graph after following this procedure:
a. Add the colloidal gold to the cuvette
b. Measure 100 microliters of sodium chloride solution using a micropipette
c. Add the 100 microliters of sodium chloride solution into the cuvette
d. Shake the cuvette once, and let sit for approximately 20 seconds
e. Place into Spectro Vis
f. Collect data
g. Repeat ten times
Variables
Independent variable: Sodium chloride solution
Dependent variable: Aggregation rate
Control: Room temperature Constants: Colloidal gold and
amount of sodium chloride solution added
Data – Colloidal Gold at 10°C
0 100 200 300 400 500 600 700 800 900 10000
100
200
300
400
500
600
700R² = 0.856479451489212
Colloidal Gold at 10°C
Sodium Chloride Solution (μL)
Peak o
f G
raph (
nm
)
0 100 200 300 400 500 600 700 800 900 10000
100
200
300
400
500
600
700
Colloidal Gold at 10°C
Sodium Chloride Solution (μL)
Peak o
f G
raph (
nm
)
Data – Colloidal Gold at 20°C
0 100 200 300 400 500 600 700 80 900 10000
100
200
300
400
500
600
700R² = 0.784995317000277
Colloidal Gold at 20°C
Sodium Chloride Solution (μL)
Peak o
f G
raph (
nm
)
0 100 200 300 400 500 600 700 80 900 10000
100
200
300
400
500
600
700
Colloidal Gold at 20°C
Sodium Chloride Solution (μL)
Peak o
f G
raph (
nm
)
Data – Colloidal Gold at 30°C
0 100 200 300 400 500 600 700 800 900 10000
100
200
300
400
500
600
700
R² = 0.877308187502859
Colloidal Gold at 30°C
Sodium Chloried Solution (μL)
Peak o
f G
raph (
nm
)
0 100 200 300 400 500 600 700 800 900 10000
100
200
300
400
500
600
700
Colloidal Gold at 30°C
Sodium Chloried Solution (μL)
Peak o
f G
raph (
nm
)
Data – Comparison of all Three
0 100 200 300 400 500 600 700 800 900 1000400
450
500
550
600
650
700
Rate of Aggregation Between Three Temperatures
10C20C30C
Sodium Chloride Solution (μL)
Peak
of G
raph
(nm
)
Data – Comparison of all Three
0 100 200 300 400 500 600 700 800 900 1000400
450
500
550
600
650
700
R² = 0.856479451489212R² = 0.784995317000277R² = 0.877308187502859
Rate of Aggregation Between Three Temperatures
10C Linear (10C)
20C Linear (20C)
30C Linear (30C)
Sodium Chloride Solution (μL)
Peak
of G
raph
(nm
)
Conclusion
The data received showed all three temperatures aggregated similarly.
The hypothesis was rejected at the temperatures tested. Further testing would be needed to conclude whether
higher temperatures of colloidal gold increase the rate of aggregation.
Importance of this experiment: Pertains much to recent scientific discoveries about
nanotechnology Nanotechnologists are testing the ability of colloidal
gold to target cancer tumors.
Possible Errors and Improvements
Possible Errors: The testing taking place on different days
o Slight temperature, humidity, and weather change Change in temperature as the trials were being done
o Temperature was not monitored after being placed in the cuvetteo Solution could have accumulated to room-temperature without
acknowledgement, although efforts were made to work quickly in order to manage this temperature change.
Sodium chloride solution not beginning at the same temperature as the colloidal gold
Improvements to this experiment: Make the sodium chloride solution the same temperature as the
colloidal gold, removing any difference in temperature between what was recorded
Monitor the solution temperature during procedure
Works Cited
Aslan, K., Lakowicz, J. R., & Geddes, C. D. (2004, Winter/Spring). Nanogold-plasmon-resonance-based glucose sensing. Retrieved from http://www.theinstituteoffluorescence.com/Publications%20PDF/23.pdf Colloidal Gold [Medical treatments using colloidal gold]. (1971). Retrieved from http://www.alchemistsworkshop.com/ CytImmune Sciences. (2011). What is Colloidal Gold? Retrieved from http://www.cytimmune.com/ go.cfm?do=Page.View&pid=15 Goldman, M. V. (n.d.). Absorption Spectra. In Absorption Spectra. Retrieved from Colorado Commission on Higher Education and the National Science Foundation website: http://www.colorado.edu/ physics/2000/quantumzone/fraunhofer.html IUPAC. (2002, September 5). STABILITY OF COLLOIDAL SYSTEMS, AGGREGATION, COAGULATION, FLOCCULATION. Retrieved from http://old.iupac.org/reports/2001/colloid_2001/manual_of_s_and_t/node35.html Malvern Instruments Ltd. (2011). Colloidal Aggregation. Retrieved from http://www.malverninstruments.fr/LabEng/industry/nanotechnology/colloids_aggregation.htm NANOYOU. (2011, July/August). Experiment with colorimetric gold nanosensors - Teacher guide (age 11-13) [A Teacher's guide for experiments with colloidal gold]. Retrieved from http://www.slideshare.net/NANOYOUproject/ experiment-with-colorimetric-gold-nanosensors-teacher-guide-age-1113 Otwinowski, J. (2007, August 26). Temperature Induced Aggregation of Colloids [Journal testing the effects of temperature on aggregation of colloids]. Retrieved from http://staff.science.uva.nl/ ~pschall/People/Alumni/Thesis_JakubOtwinowski.pdf Science In Motion. (2010). #24 Study of Colloidal Gold Solution. Retrieved from http://www.philasim.org/newmanual/exp24.pdf Solomatin, S. V., Bronich, T. K., Eisenberg, A., Kabanov, V. A., & Kabanov, A. (2004, February 17). Colloidal Stability of Aqueous Dispersions of Block Ionomer Complexes: Effects of Temperature and Salt [The effects temperature has on colloidal gold]. Retrieved from http://pubs.acs.org database. Space Today Online. (2003). Understanding Space Technology Spectrometers . Retrieved from http://www.spacetoday.org/SolSys/Spectrometers/Spectrometers.html The Physics Classroom. (1996-2012). Color and Vision. Retrieved from comPADRE website: http://www.physicsclassroom.com/class/light/u12l2a.cfm Utopia Silver Supplements. (2005). The First Spiritual Recipe by The Great Physician [The history of Colloidal Gold]. Retrieved from http://www.colloidalgold.com/history.htm
