nanostructured materials processing: powders, patterns & pores

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Nanostructured Materials Processing: Powders, Patterns & Pores 500nm 500nm 500nm Sundar V. Atre, Ph.D.

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Nanostructured Materials Processing: Powders, Patterns & Pores. 500nm. Sundar V. Atre, Ph.D. 500nm. 500nm. Research Overview. Nanomaterials. ceramics , polymers, metals, composites. Microfeatures. Applications. channels, pillars, wells. sensors, medical, energy storage, packaging. - PowerPoint PPT Presentation

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Page 1: Nanostructured Materials Processing: Powders, Patterns & Pores

Nanostructured Materials Processing: Powders, Patterns & Pores

500nm

500nm 500nm

Sundar V. Atre, Ph.D.

Page 2: Nanostructured Materials Processing: Powders, Patterns & Pores

Research Overview

Microfeatures

Nanomaterials

Applicationsceramics, polymers, metals, composites

channels, pillars, wells sensors, medical, energy storage, packaging

Page 3: Nanostructured Materials Processing: Powders, Patterns & Pores

Cellulose Nanocrystals-CNXLs

Top one-side plate

Film

Two-side plate

Film

Two-side plate

Film

Two-side plate

Top Support Plate

Bottom one-side plate

Film

Bottom Support Plate

Fluid Collection Cap

Fluid Collection Cap

Diffusion Area

CNXL composite membranes CNXL composite membranes for improved selectivity and stiffnessfor improved selectivity and stiffness

Goran JovanovicJohn SimonsenSweda Noorani

US Patent 7955504 B1

Page 4: Nanostructured Materials Processing: Powders, Patterns & Pores

Ceramic Nanoparticles: n-AlN

Valmika NathanGreg PurdyGrant Kim

(Powder Technology –submitted; Powdermet 2010; NSTI Nanotech 2010)

Page 5: Nanostructured Materials Processing: Powders, Patterns & Pores

AlN: Powder Injection Molding

shape

flow

debind

sinter

powder final

Powder Injection Molding International 2010; SME 2011; ABM 2011

Page 6: Nanostructured Materials Processing: Powders, Patterns & Pores

AlN PIM: Sintering

1100 °C 1300 °C 1500 °C

µ-n

AlN

• Liquid phase formation was observed at 1500 °C• n-Y2O3 and n-AlN lead to liquid phase formation at lower temperatures (100 °C

lower than prior reports)

• Nanorod formation was observed at 1100 °C for monomodal µ-AlN

500 °C

µ-A

lN500 °C 800 °C 1100 °C

Valmika Nathan

Page 7: Nanostructured Materials Processing: Powders, Patterns & Pores

AlN PIM: Sintering

• Higher initial solids loading lead to lower shrinkage for bimodal sample (14±1%) than the conventional monomodal ones (>20%)

(c) 1650 °C

Ceramics International 2012 Valmika Nathan

Page 8: Nanostructured Materials Processing: Powders, Patterns & Pores

Si3N4 UAV Engines

Juergen LenzJOM, 2012

• Higher fuel efficiency at higher operating temperature

• Light weight

• Smaller component size: better fit with process and materials

Page 9: Nanostructured Materials Processing: Powders, Patterns & Pores

PIM of Si3N4 Nanoparticles

Page 10: Nanostructured Materials Processing: Powders, Patterns & Pores

Green Sintered

PIM: BaTiO3 Microwells

Valmika NathanPowder Injection Molding International 2011

Page 11: Nanostructured Materials Processing: Powders, Patterns & Pores

Alternative: Green Micromachining

• Micromilling

a b

• Laser

Carl WuValmika Nathan

Burak Ozdoganlar

Page 12: Nanostructured Materials Processing: Powders, Patterns & Pores

Patterned Polymer Films

Valmika Nathan

Modified PVDF

Page 13: Nanostructured Materials Processing: Powders, Patterns & Pores

Ceramic Nanoparticles: n-SiC

Plasma Pressure Compaction

ρ

Work

Master Sintering Curve

Microstructure

Armor

Electronic Packages

Page 14: Nanostructured Materials Processing: Powders, Patterns & Pores

n-SiC: Microstructure-Properties

1600 1800 20000

8

16

24

Izhevskyi et al (5min, 1.5 MPa)Hilmas et al (1h, 25 MPa)Mulla et al (5min)Cao et al (1 h, 50 MPa)Tanaka et al (30 min)This Work (30 min, 20 MPa)

Har

dnes

s (G

Pa)

Sintering Temperature C)

1 μm

Manish Bothara, T. S. Sudarshan, Seong-Jin Park, Rand German

(Metallurgical & Materials Transactions, 2010, Science of Sintering 2011)

Page 15: Nanostructured Materials Processing: Powders, Patterns & Pores

Pores: Anodization

200 nmA

C

B

Negar Monfared

ABM 2011

Page 16: Nanostructured Materials Processing: Powders, Patterns & Pores

Pores: Nanorod Templates

Negar Monfared

PUSZ, 9 hr UV curing, 2 hr thermal curing at 600°C (1.2°C/min),

pyrolysis at 1100°C (1.2°C/min)

PUSZ , 5 minutes vacuum, 5 hr UV, no thermal curing, pyrolysis for 2 hr at

1100°C (5°C/min)

Polyurea silazane (PUSZ)

ABM 2012

Page 17: Nanostructured Materials Processing: Powders, Patterns & Pores

Pores: Biosensors

Nearly 5 Orders of MagnitudeIncrease In Performance

Shalini Prasad

Page 18: Nanostructured Materials Processing: Powders, Patterns & Pores

Hypothesis: Macromolecular Crowding

20 nm

A

C

B

D

Page 19: Nanostructured Materials Processing: Powders, Patterns & Pores

Integrating Length Scales

PAA functionalization: Langmuir 2011

Page 20: Nanostructured Materials Processing: Powders, Patterns & Pores

Summary

500nm500nm 500nm

• Nano-structured materials: particles, patterns, pores

• Integration with microsystems

• Material systems: polymers, metals, ceramics

• Applications: energy, healthcare, homeland security, packaging