Electroplating of Carbon Aerogels By Naser AlMufachi Reminder
Electroplating of Carbon Aerogels By Naser Al-Mufachi
Reminder of Aerogels l l l l l Its appearance is similar to glass, however resembles solidified smoke. Is a microporous, transparent silicate foam composed of ~99. 8% air. It is a stiff foam with a density ranging from 0. 1 -0. 01 g/cm 3. Is currently the worlds lowest density solid and hence the worlds lightest solid. Can provide 39 times the insulation capabilities of the best insulating fiberglass material. 1000 times less dense than glass. Was used on the Mars Path Finder Rover for insulation. Can support 500 -4000 times its own weight in applied force. Has a high surface area (250 -3000 m 2/g).
…. and of Carbon Aerogels Electrically conductive Carbon nanofoams. l Available in forms of monoliths, granules, powders and papers. l The Carbon Aerogel has a high capacitance. l Commonly used as a high temperature insulator, coatings, electrodes fuel cells to name a few. l Properties of Carbon Aerogel Available Ranges Density 0. 25– 1. 0 g/cm 3 Surface Area 400 m 2/g Average Pore Size 0. 7 nm Electrical Resistivity 0. 01 -0. 04 Ωcm Capacitance 30 F/g
What the Carbon Aerogel should look like
What was observed
Carbon family Carbon Aerogel Carbon Felt Carbon Graphite Rod
Recipe for Electrolyte Solutions Solution Constituent Quantity of Constituent (g/L) Nickel Ni. SO 4· 7 H 2 O Ni. Cl 2· 6 H 2 O H 3 BO 3 Wetting Agent (Isopropanol) 300 50 30 1 Iron Fe 2 SO 4· 7 H 2 O Fe. Cl 2· 4 H 2 O (NH 4)2 SO 4 Na. COOH H 3 BO 3 Wetting Agent (Isopropanol) 300 42 15 15 30 1 Chromium Cr. O 3 H 2 SO 4 400 4
Initial Approach: Plating with Nickel l l l In order to get an idea of the electroplating process, a piece of copper sheet was plated with nickel. Adhesion of the Ni plate was excellent and the coating was uniform. The idea would then be to move onto carbon articles which are similar to that of carbon aerogel. Carbon Graphite was chosen for its conductive and brittle nature. Carbon felt was selected for its porous features. Both of these were used to model the effects and outcome of nickel plating Carbon Aerogels. Nickel was initially used for plating since it is the easiest to electroplate with in general.
Plating Carbon Graphite l l l The Carbon graphite rods were prepared by wiping down the outer surface and cleaning with acetone. The outcome revealed nonuniform plating. Carbon is difficult to wet since it has a low surface energy. A wetting agent was selected to help wet the graphite rod. Different quantities were experimented with in order to decide which was the most effective in plating the rod. Voltage (V) Current (m. A) Time (sec) Observatio n 1 60 120 Blotchy plating i. e. very little 1. 5 200 120, then further 180 One side plated thick, the other side plated nonuniformly
It was observed that at 2% isopropanol in nickel electrolyte solution yielded the best plating. l Conditions: 1. 5 V for 120 sec l Current readings were increasing during the plating session. l Vol. (%) Isopropanol (ml) Observation 10 Very mild plating 8 Mild plating 6 Mild plating 4 Mild plating 2 Good plating 1 Mild plating 0. 5 Very mild plating
Plating Carbon felt l l l 2 min at 3 V in 2% isoprop. solution yielded mild plating on outer surface. Another sample was done for 5 min at 3 V in 2% isoprop. Which showed much improved coverage. This suggests that plating is time dependent. However, the isopropanol is not ample enough to provide sufficient wetting. Placing the sample in a vacuum chamber would help draw the air out of the pores and allow the electrolyte solution to infiltrate into the felt
Data collected for felt l l l The procedure involved attaching a strip of carbon felt to a copper rod. The sample was then put in a 50 ml beaker and sealed at the top using wax paper. Holes were made to allow for air to pass out. The sample was then evacuated for 30 min runs, electroplated for 30 sec and massed after being further evacuated for 2 hrs. The results show a relative increase in mass however a dramatic drop in mass occurs at 150 sec. Could be put down to the electrolysing of water in the aqueous electrolyte. Time elapsed (sec) Mass (g) 0 0. 1886 30 0. 1897 60 0. 2060 90 0. 3653 120 0. 4078 150 0. 2154 180 -
Electroplating Set up The sample was connected to the black chord which acts as the cathode electrode. l The red chord is attached to the metal desired for plating and plays the role of the anode. l The solution in the beaker is the electrolyte containing freely moving metal ions. l Plating is controlled using the voltage dial. l
Preparation method Samples are typically washed in distilled water and cleaned using acetone. l The samples were then fixed to a paperclip which was connected to a protruding copper wire and immersed in a batch of electrolyte. l The sample was then covered using wax paper and evacuated for 2 hrs. l
SEM Apparatus The SEM and FESEM have been used to provide detailed images of the interior plating. l Unfortunately they have been unsuccessful in capturing any images which confirm metal plating. l EDS analysis has confirmed, at least, the presence of metal in the interior. l
Nickel plated Carbon Aerogel
EDS Analysis
XRD Analysis
Nickel plate analysis
Iron plated Carbon Aerogel
EDS Analysis
A large piece of aerogel broke off the original sample, hence the abrupt drop in mass.
In general Massing the sample after successive plating sessions is a crude technique and yields no real useful data unfortunately. l The adhesion of the outer surface plating is poor and can peel off rendering the mass data inaccurate. l XRD scans are inconclusive and is a technique not suitable for analyzing on the scale being dealt with. l Only real evidence that plating occurs within the carbon aerogel is shown by the EDS scans. l
Chromium plated Carbon Aerogel l In the making! l All necessary data should be collected by Monday. l Research will continue.
Acknowledgement l Prof. Young Blood l Prof. Trumble l Ben, Brad, John, Raghavan, Butur, Dave l Entire Materials department. Thank you for your time…. Questions?
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