The Effect of Pressure on the Microstructure and Mechanical Properties of Spark Plasma Sintered...
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The Effect of Pressure on the Microstructure and Mechanical Properties of Spark Plasma Sintered Silicon Nitride Anne Ellis, Leah Herlihy, William Pinc, and Erica Corral Materials Science and Engineering Department, The University of Arizona, Tucson, AZ Properties of Silicon Nitride Spark Plasma Sintering SPS Conditions Grain Size of Si 3 N 4 Parts Abstract Densification Behavior Alpha to Beta Phase Transformation Mechanical Properties Discussion and Conclusion Silicon nitride (Si 3 N 4 ) is a useful ceramic in research and industry due its high thermal conductivity, high strength within a wide range of temperatures, and high fracture toughness. Si 3 N 4 has two different phases that exhibit different mechanical properties. α-Phase Crystal Structure Trigo nal β-Phase Crystal Structure Hexagonal • Pressure-less sintering, hot pressing, and spark plasma sintering of Si 3 N 4 can result in fully dense microstructures with room temperature strengths > 1 GPa. • Liquid forming sintering aids are required to achieve full density and beta growth. The alpha phase has high hardness and the beta phase forms long rods which increases the fracture toughness in the ceramic. Powder Manufacture r % α-Si 3 N 4 %- Additives Average Particle Size (nm) Theoretical Density (g/cc) RTP Grade P H.C. Starck 91% 1% MgO 5% Al 2 O 3 5% Y 2 O 3 580 ± 220 3.22 Silicon Nitride Powder Information Spark plasma sintering is an ideal method for the rapid densification of high temperature ceramics due to the high heating rates and short sintering times required. Sample Size 20 mm diameter Temperature 1800°C Sintering Pressures 5 MPa, 20 MPa, 30MPa Preload 5 MPa Loading Schedule Load applied at start of heating. Load removed at the end of the hold. Heating / Cooling Rate Used 100°C/min Chamber Environment N 2 Gas (~ 1 atm) • SPS uses a pulsing direct current to rapidly heat powders contained in graphite dies while simultaneously applying load. • The die is heated through joule heating and the powder is heated through heat transfer. - 10-3 Thermal Technology - 3,000 Amps at up to 10V - Max load of 10 tons - Heating rate 600°C/min+ Spark plasma sintering (SPS) is used to densify powder blends, which allows us to examine a large number of sintering parameters and control the microstructure of the material. Displacement of Si 3 N 4 Powders During SPS Densification • H.C. Starck Si 3 N 4 powder densifies by liquid phase sintering with oxide sintering aids and a higher sintering pressure results in a faster initial rate of densification. • The onset of densification begins at the same temperature (1200°C) for all three pressures. • Higher pressures result in higher initial rates of densification; as the glass is softening at these temperatures, higher pressures are able to better flow the glass. • Samples sintered at higher pressures completely densify sooner. • All samples reach full density. 5 MPa 20 MPa 30 MPa Early stages of densificati on Liquid phase formation -Onset of densification Completion of densificati on XRD Plot for SPS Si 3 N 4 at various pressures SPS Pressure Condition (MPa) % α-Si 3 N 4 % β- Si 3 N 4 5 21 79 20 30 70 30 42 58 XRD patterns show that a lower sintering pressure results in a higher β-Si 3 N 4 concentration in the sintered part. Alpha and Beta Si 3 N 4 Content After Sintering • Higher sintering pressures are inhibiting the α to β- Si 3 N 4 phase transformation. Grain Size (nm) The Effect of Pressure on Grain Size of SPS HC-Starck Si 3 N SPS Pressure Condition (MPa) Average Grain Size (nm) % β- Si 3 N 4 5 358 79 20 286 70 30 270 58 • Increases in grain size with lower sintering pressures correlate with increasing β-Si 3 N 4 content. • Increase in grain size is likely driven by the formation of elongated, rod-like β-Si 3 N 4 grains. Grain size is found to increase with lower sintering pressures. Average Grain Size of Si 3 N 4 After Sintering 1.00 μm 1.00 μm 1.00 μm 1800°C – 2 minute 5 MPa sample 358 nm SEM images of SPS samples 1800°C - 2 minute 20 MPa sample 286 nm 1800°C - 2 minute 30 MPa sample 270 nm Pressure Increases Grain Size Increases SPS Pressure Condition (MPa) % β- Si 3 N 4 Average Grain Size (nm) Vickers Hardness (GPa) Average Flexural Strength (MPa) Average Toughness (MPa m 1/2 ) 5 79 358 13.79 ± 0.25 720.4 ± 99.8 _ 20 70 286 15.02 ± 0.34 542.2 ± 119.2 _ 30 58 270 14.31 ± 0.51 869 ± 87.6 10.57 ± 0.74 The hardness and room temperature flexural strength of sintered Si 3 N 4 is dependent on both β-Si 3 N 4 content and average grain size. • Literature shows Si 3 N 4 strength increases with increasing β- Si 3 N 4 content and decreasing grain size. • Highest strength obtained with 30 MPa which gave the lowest β- Si 3 N 4 content and lowest grain size. • The highest strength sample that was sintered at 1800°C, 2 minute hold, and 30 MPa had a toughness of 10.57 ± 0.74 MPa m 1/2 . • Our maximum strength and toughness of the H.C. Starck powder are comparable to values in literature. • Using spark plasma sintering and altering the sintering pressure we were able to control the microstructure of sintered Si 3 N 4. • By using SPS we are able to manipulate the grain size and beta concentration of the silicon nitride. The rapid heating and cooling of the SPS allows us to create specific microstructures. • Using this sintering method allows us to investigate the effect of different microstructures of Si 3 N 4 on the flexural strength. • Increasing the sintering pressure resulted in higher initial rates of densification, lower β-Si 3 N 4 concentration of the A ready to press blend of silicon nitride from H.C. Starck is spark plasma sintered (SPS) at varying pressures to determine the effect of pressure on grain size, alpha to beta phase transformation, flexural strength, and toughness. With SPS we are able to tailor the microstructure of the silicon nitride and examine how different microstructures affect mechanical properties. We spark plasma sintered the silicon nitride at 1800°C, with a 2 minute hold, and varying pressures of 5 MPa, 20 MPa, and 30 MPa. XRD was used to determine the phase composition of the sintered parts and the grain size was determined using SEM micrographs. The flexural strength and toughness of the sintered parts were measured. 3.00μm Fracture surface of SPS Si 3 N 4 Beta phase •Long rods •Increas es toughnes s Undergraduate student support is provided by the National Science Foundation-Southwest Materials Research Training Program in High Temperature Materials under an NSF Early Faculty CAREER Award number NSF-DMR 0954110. Acknowledgement also goes to Luke S. Walker and Kimberlin Schnittker for help with sample preparation Intens ity Heating Rate 20°C/min <50°C/min <500°C/min Radiant Radiant Joule Hold Time & Temp for Si 3 N 4 Densification 6-12 Hours; 1900 °C+ < 1 Hour; 1750 °C+ 0-20 Minutes; 1550 - 1800°C Sample Shape Near Net Shape Simple Geometries Simple Geometries Heating Method Pressure-less Sintering Hot pressing SPS Si 3 N 4 Si 3 N 4 Pressure-less Sintering Si 3 N 4 Punch Sample i Punch V Control Pyromet er Sampl e Graphite Die Schematic of SPS 2θ 5 MPa 20 MPa 30 MPa 260 280 300 320 340 360 0 5 10 15 20 25 30 35 SPS Pressure (M Pa)
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Transcript of The Effect of Pressure on the Microstructure and Mechanical Properties of Spark Plasma Sintered...
The Effect of Pressure on the Microstructure and Mechanical Properties of Spark Plasma Sintered Silicon Nitride
Anne Ellis, Leah Herlihy, William Pinc, and Erica CorralMaterials Science and Engineering Department, The University of Arizona, Tucson, AZ
Properties of Silicon Nitride
Spark Plasma Sintering
SPS Conditions Grain Size of Si3N4 PartsAbstract
Densification Behavior
Alpha to Beta Phase Transformation
Mechanical Properties
Discussion and Conclusion
Silicon nitride (Si3N4) is a useful ceramic in research and industry due its high thermal conductivity, high strength within a wide range of temperatures, and high fracture toughness. Si3N4 has two different phases that exhibit different mechanical properties.
α-Phase Crystal Structure
Trigonal
β-Phase Crystal Structure
Hexagonal
• Pressure-less sintering, hot pressing, and spark plasma sintering of Si3N4 can result in fully dense microstructures with room temperature strengths > 1 GPa.• Liquid forming sintering aids are required to achieve full density and beta growth.
The alpha phase has high hardness and the beta phase forms long rods which increases the fracture toughness in the ceramic.
Powder Manufacturer % α-Si3N4 %-Additives Average Particle Size (nm)
Theoretical Density (g/cc)
RTP Grade P H.C. Starck 91%
1% MgO5% Al2O3
5% Y2O3
580 ± 220 3.22
Silicon Nitride Powder Information
Spark plasma sintering is an ideal method for the rapid densification of high temperature ceramics due to the high heating rates and short sintering times required.
Sample Size 20 mm diameterTemperature 1800°C
Sintering Pressures 5 MPa, 20 MPa, 30MPaPreload 5 MPa
Loading Schedule Load applied at start of heating. Load removed at the end of the
hold.
Heating / Cooling Rate Used
100°C/min
Chamber Environment
N2 Gas (~ 1 atm)
• SPS uses a pulsing direct current to rapidly heat powders contained in graphite dies while simultaneously applying load. • The die is heated through joule heating and the powder is heated through heat transfer.
- 10-3 Thermal Technology - 3,000 Amps at up to 10V
- Max load of 10 tons - Heating rate 600°C/min+
Spark plasma sintering (SPS) is used to densify powder blends, which allows us to examine a large number of sintering parameters and control the microstructure of the material.
Displacement of Si3N4 Powders During SPS Densification
• H.C. Starck Si3N4 powder densifies by liquid phase sintering with oxide sintering aids and a higher sintering pressure results in a faster initial rate of densification.
• The onset of densification begins at the same temperature (1200°C) for all three pressures.
• Higher pressures result in higher initial rates of densification; as the glass is softening at these temperatures, higher pressures are able to better flow the glass.
• Samples sintered at higher pressures completely densify sooner.
• All samples reach full density.
5 MPa
20 MPa
30 MPa
Early stages of densification
Liquid phase formation -Onset of densification
Completion of densification
XRD Plot for SPS Si3N4 at various pressures
SPS Pressure Condition
(MPa)% α-Si3N4 % β- Si3N4
5 21 79
20 30 70
30 42 58
XRD patterns show that a lower sintering pressure results in a higher β-Si3N4 concentration in the sintered part.
Alpha and Beta Si3N4 Content After Sintering
• Higher sintering pressures are inhibiting the α to β-Si3N4 phase transformation.
260
280
300
320
340
360
0 5 10 15 20 25 30 35
SPS Pressure (MPa)
Gra
in S
ize
(nm
)
The Effect of Pressure on Grain Size of SPS HC-Starck Si3N4SPS Pressure
Condition (MPa)
AverageGrain Size (nm) % β- Si3N4
5 358 7920 286 7030 270 58• Increases in grain size with lower sintering pressures
correlate with increasing β-Si3N4 content.
• Increase in grain size is likely driven by the formation of elongated, rod-like β-Si3N4 grains.
Grain size is found to increase with lower sintering pressures.
Average Grain Size of Si3N4 After Sintering
1.00 μm 1.00 μm 1.00 μm
1800°C – 2 minute 5 MPa sample
358 nm
SEM images of SPS samples1800°C - 2 minute
20 MPa sample 286 nm
1800°C - 2 minute30 MPa sample
270 nm
Pressure Increases
Grain Size Increases
SPS Pressure Condition
(MPa)% β-Si3N4
Average Grain Size
(nm)Vickers Hardness
(GPa)Average Flexural Strength (MPa)
Average Toughness (MPa
m1/2)
5 79 358 13.79 ± 0.25 720.4 ± 99.8 _
20 70 286 15.02 ± 0.34 542.2 ± 119.2 _
30 58 270 14.31 ± 0.51 869 ± 87.6 10.57 ± 0.74
The hardness and room temperature flexural strength of sintered Si3N4 is dependent on both β-Si3N4 content and average grain size.
• Literature shows Si3N4 strength increases with increasing β-Si3N4 content and decreasing grain size.
• Highest strength obtained with 30 MPa which gave the lowest β-Si3N4 content and lowest grain size.
• The highest strength sample that was sintered at 1800°C, 2 minute hold, and 30 MPa had a toughness of 10.57 ± 0.74 MPa m1/2.
• Our maximum strength and toughness of the H.C. Starck powder are comparable to values in literature.
• Using spark plasma sintering and altering the sintering pressure we were able to control the microstructure of sintered Si3N4.
• By using SPS we are able to manipulate the grain size and beta concentration of the silicon nitride. The rapid heating and cooling of the SPS allows us to create specific microstructures.
• Using this sintering method allows us to investigate the effect of different microstructures of Si3N4 on the flexural strength.
• Increasing the sintering pressure resulted in higher initial rates of densification, lower β-Si3N4 concentration of the sintered part and smaller grain size while increasing the flexural strength.
A ready to press blend of silicon nitride from H.C. Starck is spark plasma sintered (SPS) at varying pressures to determine the effect of pressure on grain size, alpha to beta phase transformation, flexural strength, and toughness. With SPS we are able to tailor the microstructure of the silicon nitride and examine how different microstructures affect mechanical properties. We spark plasma sintered the silicon nitride at 1800°C, with a 2 minute hold, and varying pressures of 5 MPa, 20 MPa, and 30 MPa. XRD was used to determine the phase composition of the sintered parts and the grain size was determined using SEM micrographs. The flexural strength and toughness of the sintered parts were measured.
3.00μm
Fracture surface of SPS Si3N4
Beta phase•Long rods•Increases toughness
Undergraduate student support is provided by the National Science Foundation-Southwest Materials Research Training Program in High Temperature Materials under an NSF Early Faculty CAREER Award number NSF-DMR 0954110. Acknowledgement also goes to Luke S. Walker and Kimberlin Schnittker for help with sample preparation and calculations.
Inte
nsity
Heating Rate20°C/min <50°C/min <500°C/min
Radiant Radiant Joule
Hold Time & Temp for Si3N4 Densification6-12 Hours; 1900 °C+ < 1 Hour; 1750 °C+ 0-20 Minutes; 1550 - 1800°C
Sample ShapeNear Net Shape Simple Geometries Simple Geometries
Heating MethodPressure-less Sintering Hot pressing SPS
Si3N4 Si3N4
Pressure-less Sintering
Si3N4
Punch
Sample
i
Punch
V
Control Pyrometer
Sample
Gra
phite
Die
Schematic of SPS
2θ
5 MPa 20
MPa 30
MPa
