All SiC Product Specifications

Cree Silicon Carbide Substrates and Epitaxy
Supported diameters:
◊ 76.2 mm
◊ 100.0 mm
◊ 150.0 mm
Product Specifications
4H Silicon Carbide Substrates
N-type, P-type, and Semi-Insulating
N-type and P-type Silicon Carbide Epitaxy
Cree® is the global leader in the manufacture of 4H silicon-carbide (SiC) substrates, SiC and III-Nitride epitaxial
wafers.
The Materials Business Unit produces a wide assortment of conductive and semi-insulating products ranging in
wafer diameters up to 150.0 mm. This material is the foundation for Cree’s vertically-integrated structure and is
manufactured upon a high-volume platform process that provides our customers the highest degree of material
quality, supply assurance, and economies of scale.
Product applications include:
G
MAT-CATALO
.00Q
4H-N SiC Substrates/SiC Epitaxy
•
•
•
•
4H-HPSI SiC Substrates/III-Nitride Epitaxy
•
•
•
Optoelectronics
Power-factor correction
Solar inverters
High-power RF
Graphene
Terahertz
Industrial motor drives
To learn more, visit www.cree.com/materials
Subject to change without notice.
www.cree.com
1
Physical Properties
Polytype
Single-Crystal 4H
Crystal structure
Bandgap
Hexagonal
3.26 eV
Thermal conductivity (n-type; 0.020 ohm-cm)
a~4.2 W/cm • K @ 298 K
c~3.7 W/cm • K @ 298 K
Thermal conductivity (HPSI)
a~4.9 W/cm • K @ 298 K
c~3.9 W/cm • K @ 298 K
Lattice parameters
a=3.073 Å
c=10.053 Å
Mohs hardness
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
2
MAT-CATALOG.00Q
~9
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
76.2 and 100.0 mm SiC Substrate Product Descriptions
Part Number
W
X
X
X
X
Options
X
X
–
X
X
X
X
0
1
2
3
4
5
=
=
=
=
=
=
no epitaxy
1 layer
2 layers
3 layers
4 layers
5 layers
0 = no epitaxy
S = standard SiC epitaxy
T = thick SiC epitaxy
2 = double-side polish, Si-face CMP, epi ready
6 = double-side polish, C-face CMP, epi ready
0 = standard micropipe
B = low basal plane dislocation density (BPD)*
L = low micropipe
V = very-low micropipe
U = ultra-low micropipe
Z = zero micropipe (ZMPTM)
resistivity code
(see appropriate specification sheet)
0 = on-axis
4 = 4.0° off-axis
8 = 8.0° off-axis
E = 76.2 mm (3.0”)
F = 100.0 mm
P = production-grade
R = research-grade
N = N-type
P = P-type
T = high-purity semi-insulating
* Low basal plane dislocation material is available
for 100-mm diameter substrates only
4 = 4H
W = standard product
See page 9 for 150-mm product descriptions
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
3
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
76.2 mm SiC Substrate Product Descriptions
Part Number
Type
Orientation
Micropipe Density
Resistivity Ohm-cm Range
Bin
N-Type Low Micropipe Density
W4NxE4C-L200
N
4˚ Off
≤15 micropipes/cm2
0.015-0.028
C
W4NxE8C-L200
N
8˚ Off
≤15 micropipes/cm
0.015-0.028
C
2
N-Type Very-Low Micropipe Density
W4NxE4C-V200
N
4˚ Off
≤5 micropipes/cm2
0.015-0.028
C
W4NxE8C-V200
N
8˚ Off
2
≤5 micropipes/cm
0.015-0.028
C
N-Type Ultra-Low Micropipe Density
W4NxE4C-U200
N
4˚ Off
≤1 micropipes/cm2
0.015-0.028
C
W4NxE8C-U200
N
8˚ Off
≤1 micropipes/cm
0.015-0.028
C
2
N-Type Zero Micropipe Density (ZMP )
TM
W4NxE4C-Z200
N
4˚ Off
0 micropipes/cm2
0.015-0.028
C
N
On-axis
N/A
0.013-2.000
N/A
P
8˚ Off
N/A
≤2.5
F
N-Type LCW
W4NRE0X-0200
P-Type
W4PRE8F-0200
High-Purity Semi-Insulating
W4TRE0R-0200
HPSI
On-axis
N/A
≥ 1E5
R
W4TRE8R-0200
HPSI
8˚ Off
N/A
≥ 1E5
R
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
4
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
100.0 mm SiC Substrate Product Descriptions
Part Number
Type
Orientation
Micropipe Density Resistivity Ohm-cm Range
Bin
N-Type Low Micropipe Density
W4NxF4C-L200
N
4˚ Off
≤15 micropipes/cm2
0.015-0.028
C
≤5 micropipes/cm2
0.015-0.028
C
N-Type Very-Low Micropipe Density
W4NxF4C-V200
N
4˚ Off
N-Type Ultra-Low Micropipe Density
W4NxF4C-U200
N
4˚ Off
≤1 micropipes/cm2
0.015-0.028
C
W4NxF4C-B200
N
4˚ Off
≤1 micropipes/cm2
0.015-0.028
C, BPD ≤1,000/cm2
N-Type Zero Micropipe Density (ZMPTM)
W4NxF4C-Z200
N
4˚ Off
0 micropipes/cm2
0.015-0.028
C
N
On-axis
N/A
0.013-2.000
N/A
N/A
≥1E5
R
N-Type LCW
W4NRF0X-0200
High-Purity Semi-Insulating
W4TRF0R-0200
HPSI
On-axis
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
5
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
Dimensional Properties, Terminology and Methods
Diameter
The linear dimension across the surface of a wafer.
Measurement is performed manually with ANSI-certified
digital calipers on each individual wafer (see Figure 1).
Thickness, center point
Measured with ANSI-certified non-contact tools at the center
of each individual wafer.
Flat length
Linear dimension of the flat measured with ANSI-certified
digital calipers on a sample of one wafer per ingot (see
Figure 1).
Marking
For silicon-face-polished material, the carbon face of each
individual wafer is laser-marked with OCR-compatible
font, similar to definitions and characteristics in SEMI M12
(see Figure 1). For carbon-face-polished material, the
silicon face of each individual wafer is laser-marked (see
Figure 2). 150.0 mm substrates have no secondary flat,
and the marking convention is identical to that of 76.2
and 100 mm products.
Surface orientation
Denotes the orientation of the surface of a wafer with respect
to a crystallographic plane within the lattice structure. In
wafers cut intentionally “off orientation,” the direction of cut
is parallel to the primary flat, away from the secondary flat.
Measured with x-ray goniometer on a sample of one wafer
per ingot in the center of the wafer.
Orthogonal misorientation
In wafers cut intentionally “off orientation,” the angle
between the projection of the normal vector to the wafers
surface onto a {0001} plane and the projection on that
plane of the nearest <1120> direction.
Primary flat
The primary flat is the {1010} plane with the flat face
parallel to the <1120> direction.
Secondary
Flat
XXXXXX-XX
Wafer
Diameter
Primary Flat
Figure 1. Diameter, primary and
secondary flat locations, and
marking orientation, carbon face up
for silicon face polished wafers
Primary flat orientation
The flat of the longest length on the wafer, oriented such
that the chord is parallel with a specified low-index crystal
plane. Measured on one wafer per ingot using Laue backreflection technique with manual angle measurement.
Secondary flat orientation
A flat of shorter length than the primary orientation flat,
whose position with respect to the primary orientation flat
identifies the face of the wafer.
Secondary
Flat
XXXXXX-XX
Primary Flat
Figure 2. Primary and
secondary flat locations, and
marking orientation, silicon face up
for carbon face polished wafers
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
6
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
76.2 mm SiC Substrate Specifications
Substrate Property
Cree Standard
Diameter
3.000” ± 0.015”
76.2 mm ± 0.38 mm
Thickness
N-type on-axis
0.0145” ± 0.0025”
368.0 μm ± 64.0 μm
Thickness
N-type off-axis; semi-insulating
0.0138” ± 0.001”
350.0 μm ± 25.0 μm
Dopant
n-type: Nitrogen
Primary flat length
0.875” ± 0.125”
22.22 mm ± 3.17 mm
Secondary flat length
0.440” ± 0.060”
11.18 mm ± 1.52 mm
Surface orientation
on-axis
{0001} ± 0.25˚
Surface orientation
off-axis
4.0˚ toward <1120> ± 0.5˚
8.0˚ toward <1120> ± 0.5˚
Surface finish
Both sides polished
Orthogonal misorientation
± 5.0˚
Primary flat orientation
<1120> ± 5.0˚
Secondary flat orientation
90.0˚ CW from Primary ± 5.0˚, silicon face up
TTV
≤15 microns, full substrate
Warp
≤35 microns, full substrate
LTV (average, 1 cm2 site)
≤4 microns, full substrate
Packaging
Multi-wafer box unless otherwise specified
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
7
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
100.0 mm SiC Substrate Specifications
Substrate Property
Cree Standard
Diameter
100.0 mm +0.0/-0.5 mm
Thickness
N-type on-axis
500.0 μm ± 50.0 μm
Thickness
N-type off-axis
350.0 μm ± 25.0 μm
Thickness
Semi-insulating
500.0 μm ± 25.0 μm
Dopant
n-type: nitrogen
Primary flat length
32.5 mm ± 2.0 mm
Secondary flat length
18.0 mm ± 2.0 mm
Surface orientation
On-axis
{0001} ± 0.25˚
Surface orientation
Off-axis
4.0˚ toward <1120> ± 0.5˚
Surface finish
Both sides polished
Orthogonal misorientation
± 5.0˚
Primary flat orientation
<1120> ± 5.0˚
Secondary flat orientation
90.0˚ CW from primary ± 5.0˚, silicon face up
TTV
≤15 microns, full substrate
Warp
≤45 microns, full substrate
LTV (average, 1 cm2 site)
≤4 microns, full substrate
Packaging
Multi-wafer box unless otherwise specified
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
8
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
150.0 mm SiC Substrate Product Descriptions
Part Number
W
X
X
X
X
Options
X
X
–
X
X
-
X
X
X
X
0
1
2
3
4
5
=
=
=
=
=
=
no epitaxy
1 layer
2 layers
3 layers
4 layers
5 layers
0 = no epitaxy
S = standard epitaxy
T = thick epitaxy
2 = double-side polish, Si-face CMP, epi ready
6 = double-side polish, C-face CMP, epi ready
V = very-low micropipe
U = ultra-low micropipe
None = 500-µm thickness
1 = 350-µm thickness
C
resistivity code
(see appropriate specification sheet)
0 = on-axis
4 = 4.0° off-axis
G = 150.0 mm (6.0”)
P = production grade
R = research grade
N = N-type
T = high-purity semi-insulating
4 = 4H
W = standard product
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
9
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
150.0 mm SiC Substrate Product Descriptions
Part Number
Type
Orientation
Micropipe Density
Resistivity Ohm-cm Range
Bin
≤5 micropipes/cm2
0.015-0.028
C
4˚ Off
≤1 micropipes/cm2
0.015-0.028
C
On-axis
N/A
>1E5
R
N-Type Very-Low Micropipe Density
W4NRG4C-CX-V200
N
4˚ Off
N-Type Ultra-Low Micropipe Density
W4NPG4C-CX-U200
N
High-Purity Semi-Insulating
W4TRG0R-CX-0200
HPSI
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
10
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
150.0 mm SiC Substrate Specifications
Substrate Property
Cree Standard
Diameter
5.905” ± 0.984”
150.0 mm ± 0.25 mm
Thickness
N-type on-axis; semi-insulating
n-type: TBD
HPSI: 500 µm ± 25 µm
Thickness
N-type off-axis; semi-insulating
C specification: 500 µm ± 25 µm
C1 specification: 350 µm ± 25 µm
Dopant
n-type: nitrogen
Primary flat length
1.870” ± 0.059”
47.5 mm ± 1.5 mm
Secondary flat length
none
Surface orientation
on-axis
{0001} ±0.25°
Surface orientation
off-axis
4.0˚ toward <11-20> ± 0.5˚
Surface finish
Si-face CMP polish, C-face optical polish
C-face CMP polish, Si-face optical polish
Orthogonal misorientation
± 5.0˚
Primary flat orientation
<11-20> ± 5˚
Secondary flat orientation
N/A
N-type
HPSI
TTV
Production-grade: ≤10 µm
Research-grade: ≤10 µm
Research-grade: <10 μm
Warp
Production-grade: ≤40 µm
Research-grade: ≤60 µm
Research-grade: <60 μm
LTV (average, 1 cm2 site)
Production-grade: ≤2 µm
Research-grade: ≤4 µm
Research-grade: ≤4 μm
Edge chips by diffuse lighting
Production-grade: none permitted
Research-grade: qty. 2 ≥1.0 mm
width and depth
Research-grade: 2 ≤1.0 mm width &
depth
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
11
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
Standard Specifications for Polished SiC Substrates - Surface Finish
76.2, 100.0 and 150.0 mm SiC Substrates
Characteristics
Production-Grade
Research-Grade
Edge chips/indents by diffuse lighting†
none permitted
2 ≤1.0 mm width & depth
Orange peel/pits by diffuse lighting*Δ
≤10% area
≤30% area
Striations by diffuse lighting
3 allowed ≤3 mm each
20 allowed ≤7 mm each
Polytype areas by diffuse lighting*
≤5% area
≤20% area
Area contamination (stains) by highintensity light
none permitted
none permitted
Cracks by high-intensity light
none permitted
none permitted
Hex plates by high-intensity light*
cumulative area ≤10%
cumulative area ≤30%
Scratches by high-intensity light*
5 scratches to 1X wafer diameter
cumulatvie length
8 scratches to 1.5X wafer diameter
cumulatvie length
Masking defects (mounds)*
Quantitative by 200X microscopic
inspection
10 defects in 3 or less of the 9 fields
inspected in a cross pattern
10 defects in 5 or less of the 9 fields
inspected in a cross pattern
Contamination
Quantitative by 200X microscopic
inspection
none in inspected fields
none in inspected fields
Cumulative area defects*
Quantitative by 200X microscopic
inspection
≤10% area
≤30% area
Notes:
* Defect limits apply to entire wafer surface except for edge exclusion area, which is 2 mm for 76.2 mm substrates and
3 mm for 100.0 and 150.0 mm substrates.
◊ Pits must be <2 mm in distance from one another to be considered a reject cause.
† Edge chips must be >0.5 mm on R-grade material to be considered a reject cause.
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
12
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
Terminology and Methods for Polished SiC Substrates – Surface Finish
(Area) Contamination
Any foreign matter on the surface in localized areas which
is revealed under high-intensity (or diffuse) illumination
as discolored, mottled, or cloudy appearance resulting
from smudges, stains or water spots.
Cracks
A fracture or cleavage of the wafer that extends from the
frontside surface of the wafer to the back-side surface
of the wafer. Cracks must exceed 0.010” in length under
high-intensity illumination in order to discriminate fracture lines from allowable crystalline striations. Fracture
lines typically exhibit sharp, thin lines of propagation,
which discriminate them from material striations.
Edge chips
Any edge anomalies (including wafer-saw exit marks)
in excess of 1.0 mm in either radial depth or width. As
viewed under diffuse illumination, edge chips are determined as unintentionally missing material from the edge
of the wafer.
Edge exclusion
The outer annulus of the wafer is designated as wafer
handling area and is excluded from surface finish criteria
(such as scratches, pits, haze, contamination, craters,
dimples, grooves, mounds, orange peel and saw marks).
This annulus is 2 mm for 76.2 mm substrates, and 3 mm
for 100.0 mm substrates.
Hex plate
Hexagonal-shaped platelets on the surface of the wafer
which appear silver in color to the unaided eye, under diffuse illumination.
Masking defects (also referred to as “Mound”)
A distinct raised area above the wafer frontside surface as
viewed with diffuse illumination.
Orange peel
Visually detectable surface roughening when viewed under diffuse illumination.
Pits
Individual distinguishable surface anomalies, which appears as a depression in the wafer surface with a lengthto-width ratio less than 5 to 1, and visible under highintensity illumination.
Foreign polytypes (also referred to as “Inclusions” or
“Crystallites”)
Regions of the wafer crystallography which are polycrystalline or of a different polytype material than the remainder of the wafer, such as 6H mixed in with a 4H type
substrate. Foreign polytype regions frequently exhibit
color changes or distinct boundary lines, and are judged
in terms of area percent under diffuse illumination.
Scratches
A scratch is defined as a singular cut or groove into the
frontside wafer surface with a length-to-width ratio of
greater than 5 to 1, and visible under high-intensity illumination.
Striations
Striations in silicon carbide are defined as linear crystallographic defects extending down from the surface of
the wafer which may or may not pass through the entire
thickness of the wafer, and generally follow crystallographic planes over its length.
Total usable area
A cumulative subtraction of all noted defect areas from
the frontside wafer quality area within the edge exclusion
zone. The remaining percent value indicates the proportion of the frontside surface to be free of all noted defects
(does not include edge exclusion).
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
13
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
Specifications for SiC Epitaxial Wafers - 76.2, 100.0 and 150.0 mm Substrates
Substrate Orientation: Epitaxy is available only for off-axis substrates
Conductivity
n-type
p-type
Dopant
Nitrogen
Aluminum
Net doping density
ND-NA
NA-ND
Silicon face
9E14 – 1E19/cm3
9E14 – 1E19/cm3
Carbon face
1E16 – 1E19/cm3
Not available
Tolerance
±25%
±50%
±10% of selected thickness
±10% of selected thickness
0.2–1.0 microns
±25% of selected thickness
Not available
1.0–10.0 microns
±15% of selected thickness
Not Available
Thickness range – silicon face
0.2–50.0 microns
Thickness range – carbon face
Notes:
• 2 mm edge exclusion for 76.2 mm, 3 mm edge exclusion for 100.0 and 150.0 mm
• N-type epi layers <20 microns are preceeded by n-type, 1E18, 0.5 micron buffer layer
• N-type epi layers ≥20 microns are preceeded by n-type, 1E18, 1.0 micron buffer layer
• No buffer layer for p-type epitaxial layers
• Not all doping densities are available in all thicknesses
• Contact Cree Sales for specifications on multi-layer or unique epitaxy requests
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
14
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
Specifications for SiC Epitaxial Wafers - 76.2, 100.0 and 150.0 mm Substrates
Characteristics
Large-point
defects
Maximum Acceptability Limits
76.2 mm
30
100.0 mm
40
150.0 mm
50
Test Methods
Defect Definitions
(see pg. 14)
Methodology
(see pg. 15)
D1
Scratches
10 lines <2x wafer diameter
D2
Dimpling
<5% affected
D3
M1, M2
4.0˚ off-axis
N/A
8.0˚ off-axis
<10% affected
Step bunching
Backside cleanliness
Edge chips
Diffuse
illumination
D4
95% clean
D5
2 with radius 1.5 mm
D6
ID correct/legible
Yes
M2
D7
Wafer flats
Yes
Epi defects
25/cm2
Microscopic
D8-D12
M3
Net doping
See specification table
Hg probe CV
–
M4
Thickness
See specification table
FTIR
–
M5
Notes:
• 2 mm edge exclusion for 76.2 mm, 3 mm edge exclusion for 100.0 and 150.0 mm
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
15
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
SiC Epitaxial Wafer Definitions, Epitaxy-Defect Descriptions and Methodology
Definitions
D1. Large-point defects
Defects which exhibit a clear shape to the unassisted
eye and are > 50 microns across. These features include
spikes, adherent particles, chips and craters. Large point
defects less than 3 mm apart count as one defect.
D2. Scratches
Grooves or cuts below the surface plane of the wafer having a length-to-width ratio of greater than 5 to
1. Scratches are specified by the number of discrete
scratches times the total length in fractional diameter.
D3. Dimpling
A texture resembling the surface of a golf ball. Specified
in % affected area.
D4. Step bunching
Step bunching is visible as a pattern of parallel lines running perpendicular to the major flat. If present, estimate
the % of specified area affected.
D5. Backside cleanliness
Verified by inspecting for a uniform color to the wafer
backside. Note there is a darker region near the center of
some higher doped wafers. Backside cleanliness specified
as percent area clean.
D6. Edge chips
Areas where material has been unintentionally removed
from the wafer. Do not confuse fractures in epi crown with
edge chips.
D7. ID correct and major wafer flat
Both should be readily discernible.
Epitaxy Defects
The sum of discrete microscopic defects counted in specified area. These include 3C inclusions, comet tails, carrots, particles and silicon droplets.
D8. 3C inclusions
Regions where step-flow was interrupted during epi layer
growth. Typical regions are generally triangular although
more rounded shapes are sometimes seen. Count once
per occurrence. Two inclusions within 200 microns count
as one.
D9. Comet tails
Comet tails have a discrete head and trailing tail. These
features are aligned parallel to the major flat. Usually, all
comet tails tend to be of the same length. Count once per
occurrence. Two comet tails within 200 microns count as
one.
D10. Carrots
Similar to comet tails in appearance except they are
more angular and lack a discrete head. If present, these
features are aligned parallel to the major flat. Usually,
any carrots present tend to be of the same length. Count
once per occurrence. Two carrots within 200 microns
count as one.
D11. Particles
Particles have the appearance of eyes and if present are
usually concentrated at the wafer edges and not within
the specified area. If present, count once per occurrence.
Two particles within 200 microns count as one.
D12. Silicon droplets
Silicon droplets can appear as either small mounds or
depressions in the wafer surface. Normally absent, but if
present are largely concentrated at perimeter of wafer. If
present, estimate the % of specified area affected.
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
16
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com
SiC Epitaxial Wafer Definitions, Epitaxy-Defect Descriptions and Methodology
Methodology
M1. 2 mm edge exclusion for 76.2 mm, 3 mm edge exclusion for 100.0 and 150.0 mm.
M2. Inspection performed under diffuse illumination.
Approx.
1.5 mm
M3. Microscopic inspection performed at 100X, on an
Olympus BH2 UMA Optical Microscope, or comparable.
Inspection pattern detailed in Figure 3.
M4. Net doping is determined as an average value of
multiple points along radius opposite major flat using Hg
probe CV.
2 mm typ.
M5. Thickness is determined as an average value across
the wafer using FTIR, or mass difference.
Figure 3. Epi inspection pattern
Copyright © 1998-2013 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree
and the Cree logo are registered trademarks of Cree, Inc. Other trademarks, product and company names are the property of their
respective owners and do not imply specific product and/or vendor endorsement, sponsorship or association.
17
MAT-CATALOG.00Q
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
Fax: +1.919.313.5451
www.cree.com