微生物燃料電池中的傳輸限制

1、Transport Limitations in a Microfluidic Fuel CellBy Jason TyserProfessor Debashis Dutta/masscrest/fuelingthefuture/images/fuelcell.jpg共二十四頁BackgroundWhat is a fuel cell?A fuel cell is an electrochemical conversion device. A fuel cell is made up of a fuel and an oxidant. A fuel cell is not a battery.

2、 A fuel cell is an open system. Batteries, in contrast, are considered a closed system.共二十四頁Background/wiki/File:PEM_fuelcell.svg共二十四頁BackgroundWhy my research is necessary:Deposited electrode vs. external electrode Deposited electrode External electrode in circular reservoirs= Cathode = Anode共二十四頁P

3、revious Research 共二十四頁Previous Hypotheses1) The current in the fuel cell with the Nafion membrane will be most affected by channel depth2) The larger membrane will yield higher currents3) Higher concentrations of formic acid and KMnO4 solutions will yield higher currents共二十四頁Previous ResearchWhat I

4、did:Fabricated fuel cell chip with micro channel depths of 50, 100, 140, 190, 240, 300, and 340 microns.Tested chips with a two sizes of a Nafion membrane: 50 and 115 microns.Tested chips with two concentrations of potassium permanganate: 0.15 M and 0.30 M KMnO4.Tested chips with five concentrations

5、 of formic acid: 1.0 M, 2.5 M, 5.0 M, 7.5 M, 10.0 M 共二十四頁Previous Research 共二十四頁Previous ResearchExperimentsAdding fuel (formic acid) and oxidant (KMnO4)Using the electrochemical analyzerTaking an open circuit potentialApplying voltages: 0.01, 0.05, 0.1, 0.2, 0.4, 0.6, 0.8, 1.0, and 1.2 each for 100

6、 seconds.共二十四頁Previous Research共二十四頁Previous ResultsThe 0.3 M KMnO4 did not produce higher currents than the 0.15.The large membrane did produce higher currents than the small membrane.Increasing the formic acid concentration did increase the current- although there was a consistent peak around 5 to

7、 7.5 MUsually the deeper the chip, the higher the current (but not always)The size of the anode was determined to be the rate determining step.共二十四頁Previous ResultsBy making loops in the anode, the surface area increased from 30.883 mm2 to 59.447 mm2共二十四頁Previous ConclusionThe area of the anode does

8、 affect the current and it was maximized in these last experiments. The micro channel depth is not the limiting factor once the anode surface area is maximized.We hypothesize that the membrane is the limiting factor. 共二十四頁Current Research 3 objectives共二十四頁Research, 1st ObjectiveUsed new membrane pre

9、paration technique outlined by Motokawa et. al. (2004)Boiled Nafion membrane in 1 M H2O2 solution for 1 hourRinsed it in boiling ultra-pure water for 1 hourTreated it with boiling 1 M H2SO4 for 1 hourRan same tests as before (using only 1.0 M and 7.5 M formic acid and 0.15 M KMnO4) 共二十四頁Results 1st

10、ObjectiveThere was still scatter in the data共二十四頁Results 1st Objective共二十四頁Research, 2nd ObjectiveBond the Nafion membrane to glass chips.Collaborated with Dr. Robert Corcoran, an organic chemist, to develop the process.Bonding solution was: 20% v/v solution of 3-aminopropyl-triethoxysilane in CH2Cl

11、2.This would give + charge to glass surface to bond with SO3- groups on the Nafion. 共二十四頁Results 2nd ObjectiveOnly the 300m chip was tested, but all of the tests (7.5M, 1M, small and large membrane) with the bonded fuel cell gave higher currents than the nonbonded fuel cell共二十四頁Research, 3rd Objecti

12、veDeposited electrodes in the channels of the glass chips. This involved many steps:Prepare chip and apply photo-resistUse a metal evaporator to apply chromium and gold.Deposit platinum through electrodeposition in a chemical bath containing 1mM K2PtCl6 in 0.1M HCl 共二十四頁Results 3rd ObjectiveUsing a

13、300 m chip, the deposited electrode fuel cell produced much higher currents than the external electrode fuel cell共二十四頁Conclusions & future researchUsing the Motokawa et. al. (2004) technique, better results were produced for the small Nafion membrane, but more research needs to be done to alleviate

14、scatter. Bonding microfluidic fuel cells produces better results than unbonded fuel cells.Deposited electrode fuel cells greatly outperform external electrode fuel cells; however, more research should be done to simplify deposition process.共二十四頁acknowledgementsDr. Debashis DuttaDutta Research Group:Naoki Yanagisawa, Tristan Kinde, Chandelle WadsworthDr. Robert CorcoranUW Chemistry DepartmentWyoming NSF/EPSCoR Undergraduate Resear