ellison lab overview
DESCRIPTION
Ellison Lab Overview. Current members Jeff Easley , PhD Candidate Josh Katzenstein , PhD Candidate Alfredo Clemente Cruz , Masters Candidate Bobby Sankhagowit , Undergraduate Amanda Beck , Undergraduate Looking to add 1 or more PhD student. Ellison Research Overview. mechanical - PowerPoint PPT PresentationTRANSCRIPT
• Current members– Jeff Easley, PhD Candidate– Josh Katzenstein, PhD Candidate– Alfredo Clemente Cruz, Masters Candidate– Bobby Sankhagowit, Undergraduate– Amanda Beck, Undergraduate
• Looking to add 1 or more PhD student
Ellison LabOverview
anionic, RAFT,ATRP, NMRP,new functional
monomers
1 Å – 100’s nmmonomer
macromolecularbulk
shear and extensional flows
electric and magnetic fields
mechanical electromagnetic
conductivethermalbarrier
Synthesis Structure Processing Properties
Ellison ResearchOverview
Our research theme is connecting nanoscale / molecular level detail to macroscopic function for designing next
generation materials.
Nanostructured Polymers: Technological Impact
• Asymmetric membranes for gas separation– Koros and Pasek (J. Membr. Sci. 1993)
• Polysulfone (Udel) skin layers 20-80 nm thick
• Photoresist, production of microelectronics– Okoroanyanwu (J. Vac. Sci. Tech. B 2000)
• Understanding properties of polymer confined to feature sizes < 100 nm needed for future devices
• Nanocomposites– Vaia and Giannelis (MRS Bulletin 2001)
• Low loading levels (~several vol%), all polymer lies < 100 nm from composite interface
Hinsberg, et al. IBMJ. Vac. Sci. Tech. B 1998
Li, et al. J. Membr. Sci. 2002
Ellison Lab: “Active” Projects• New “Designer” Materials – molecular design via synthesis for tailored
properties (responsive, conductive, mechanical, separations, etc)
Project 1: Directing Nanoscale Fillers for Recyclable Barrier Materials, Nanocomposite Solar Cells, etc.
• Novel Characterization Tech. – attaining critical pieces of information others cannot using fluorescence approaches (focused on surfaces and interfaces and in-situ)
Project 2: Understanding the “Interphase” in Nanocomposites, Polymer Self-Diffusion in Thin Films
• “Green” Polymer Strategies – processing in the absence of volatile solvents, additives, etc., renewable materials
Project 3: “Green” Processing Route to Polymer Nanofibers, Designer Materials from Renewable Resources, etc.
Polymer Diffusion Near Surfaces / Interfaces
• Why is it important?
Disk Drive Lubricant Recovery
www.phi.com
Latex Film Formationhttp://www.chem.utoronto.ca/staff/MAW/
Nanocomposite Exfoliation
Fluorescence Recovery After Photobleaching (FRAP)
• Model geometry of thin and ultrathin films: In-plane diffusion– Demonstrated as viable approach, single MW and temp.1
• Start with simple system: anthracene labeled homopolymer
Fra
ctio
nal
Rec
ove
red
Flu
ore
scen
ce In
ten
sity
f(t) e It
It
t r / D
D /t D D
D i
20 1
2
2 2
4
characteristic diffusion time
t = 0
t = t1
t = t2
Photobleaching
Recovery
2ri
1 Frank B., et al, Macromolecules 29, 1996.
Melt Blowing: Green Polymer Nanofibers
Tg or Tc
Processing variables:• Polymer and air temperatures (Tp, Ta)• Polymer and air flow rates
• Solventless, environmentally benign process• Method of choice for many nonwoven products – low cost, high prod. rates• Produces microfibers with diameter > 2 μm
Fiber formation:• Hot air jet draws fiber• Active T window: Tg or Tc < T < Tp
Compared to electrospinning:• Higher production rate• No solvent
PBT
PP
PS
PBT
PP
Ellison, Phatak, Giles, Macosko, BatesPolymer 48, 2007.