CCP Meeting

When:
April 18, 2013 @ 7:00 pm – 7:45 pm
2013–04-18T19:00:00–04:00
2013–04-18T19:45:00–04:00
Where:
Dou­ble­Tree Hotel
4727 Con­cord Pike
Wilm­ing­ton, DE 19803
USA

 

Meeting Program — April 2013

 
John Kitchin
Depart­ment of Chem­i­cal Engi­neer­ing,
Carnegie Mel­lon Uni­ver­si­ty

 
Abstract — Elec­tro­chem­i­cal water split­ting may be in inte­gral part of future ener­gy stor­age strate­gies by enabling ener­gy stor­age in chem­i­cal bonds. One of the pri­ma­ry sources of inef­fi­cien­cy in the water split­ting reac­tion is the oxy­gen evo­lu­tion reac­tion, which has high reac­tion bar­ri­ers that require addi­tion­al applied elec­tric poten­tial to dri­ve the reac­tions at prac­ti­cal rates. The most active elec­trode mate­ri­als in acid elec­trolytes include ruthe­ni­um and irid­i­um oxides, which are expen­sive but nec­es­sary for sta­bil­i­ty. In alka­line envi­ron­ments, many base met­al oxides become sta­ble, although they are still less active than Ru and Ir oxides. It has been known that small amounts of Fe can pro­mote the elec­tro­chem­i­cal activ­i­ty of nick­el oxides, mak­ing it almost as active as cobalt oxide. We have inves­ti­gat­ed the mech­a­nisms behind the pro­mo­tion using in situ Raman and syn­chro­tron spec­tro­scopies as well as ex situ char­ac­ter­i­za­tion tech­niques. Inter­est­ing­ly, we found the elec­trode changes under oxy­gen evo­lu­tion con­di­tions, turn­ing from an oxide to an oxy­hy­drox­ide phase. Fur­ther­more, the com­po­si­tion of the elec­trolyte has a sig­nif­i­cant effect on the oxy­gen evo­lu­tion activ­i­ty. We will dis­cuss these results and their impli­ca­tions in find­ing bet­ter oxy­gen evo­lu­tion elec­tro­cat­a­lysts.
 

John Kitchin

John Kitchin

Biog­ra­phy — John Kitchin com­plet­ed his B.S. in Chem­istry at North Car­oli­na State Uni­ver­si­ty. He com­plet­ed a M.S. in Mate­ri­als Sci­ence and a PhD in Chem­i­cal Engi­neer­ing at the Uni­ver­si­ty of Delaware in 2004 under the advise­ment of Dr. Jing­guang Chen and Dr. Mark Barteau. He received an Alexan­der von Hum­boldt post­doc­tor­al fel­low­ship and lived in Berlin, Ger­many for 1 ½ years study­ing alloy seg­re­ga­tion with Karsten Reuter and Matthias Schef­fler in the The­o­ry Depart­ment at the Fritz Haber Insti­tut. Pro­fes­sor Kitchin began a tenure-track fac­ul­ty posi­tion in the Chem­i­cal Engi­neer­ing Depart­ment at Carnegie Mel­lon Uni­ver­si­ty in Jan­u­ary of 2006. He is cur­rent­ly an Asso­ciate Pro­fes­sor. At CMU, Pro­fes­sor Kitchin is active in a major research effort with­in the Nation­al Ener­gy Tech­nol­o­gy Lab­o­ra­to­ry Region­al Uni­ver­si­ty Alliance in CO2 cap­ture, chem­i­cal loop­ing and super­al­loy oxi­da­tion. Pro­fes­sor Kitchin also uses com­pu­ta­tion­al meth­ods to study adsor­bate-adsor­bate inter­ac­tions on tran­si­tion met­al sur­faces for appli­ca­tions in catal­y­sis. He was award­ed a DOE Ear­ly Career award in 2010 to inves­ti­gate mul­ti­func­tion­al oxide elec­tro­cat­a­lysts for the oxy­gen evo­lu­tion reac­tion in water split­ting using exper­i­men­tal and com­pu­ta­tion­al meth­ods. He received a Pres­i­den­tial Ear­ly Career Award for Sci­en­tists and Engi­neers in 2011.