Home Knowledge Base Semiconductor Laser Annealing

Semiconductor Laser Annealing is the ultra-rapid thermal processing technique that uses high-power laser pulses to heat the wafer surface to 1000-1400°C for milliseconds or microseconds — activating implanted dopants with near-100% efficiency while maintaining ultrasharp dopant profiles because the heating is so brief that dopant diffusion is negligible, critical for sub-5nm nodes where junction depths of 5-10 nm must be formed without any profile broadening.

Why Laser Annealing

Annealing Technology Comparison

TechnologyTemperatureDurationDopant DiffusionActivation
Furnace anneal800-1000°C30-60 min50-200 nm40-60%
Spike RTA1000-1100°C~1 sec5-20 nm70-90%
Flash lamp anneal1100-1300°C1-5 ms1-5 nm90-98%
Laser spike anneal (LSA)1200-1400°C0.1-1 ms<1 nm>99%
Nanosecond laser annealMelt temperature10-100 ns~0 nm~100%

Laser Anneal Process

[CO₂ laser beam (10.6 µm) or diode laser array]
              ↓
[Scanned across wafer surface at ~100-300 mm/s]
              ↓
[Surface heated to 1200-1400°C in <1 ms]
              ↓
[Substrate remains at ~400-500°C (thermal sink)]
              ↓
[Surface cools in ~1 ms as beam moves on]

Key: Only top ~10 µm is heated → underlying structures preserved

Temperature Profile

<svg viewBox="0 0 309 226" xmlns="http://www.w3.org/2000/svg" style="max-width:100%;height:auto" role="img"><rect x="0" y="0" width="309" height="226" rx="12" fill="#0d1117"/><g font-family="ui-monospace,SFMono-Regular,Menlo,Consolas,&quot;Liberation Mono&quot;,monospace" font-size="14"><text xml:space="preserve" x="20" y="31.7"><tspan fill="#c9d1d9">T (°C)</tspan></text><text xml:space="preserve" x="20" y="50.7"><tspan fill="#c9d1d9">1400</tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9">     </tspan><tspan fill="#6e7681">┌─┐</tspan></text><text xml:space="preserve" x="20" y="69.7"><tspan fill="#c9d1d9">    </tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9">    / </tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9"> \</tspan></text><text xml:space="preserve" x="20" y="88.7"><tspan fill="#c9d1d9">1200</tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9">   /  </tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9">  \</tspan></text><text xml:space="preserve" x="20" y="107.7"><tspan fill="#c9d1d9">    </tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9">  /   </tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9">   \</tspan></text><text xml:space="preserve" x="20" y="126.7"><tspan fill="#c9d1d9"> 800</tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9"> /    </tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9">    \</tspan></text><text xml:space="preserve" x="20" y="145.7"><tspan fill="#c9d1d9">    </tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9">/     </tspan><tspan fill="#6e7681">│</tspan><tspan fill="#c9d1d9">     \</tspan><tspan fill="#6e7681">────────</tspan></text><text xml:space="preserve" x="20" y="164.7"><tspan fill="#c9d1d9"> 400</tspan><tspan fill="#6e7681">│──────┘</tspan><tspan fill="#c9d1d9">           substrate</tspan></text><text xml:space="preserve" x="20" y="183.7"><tspan fill="#c9d1d9">    </tspan><tspan fill="#6e7681">└─────────────────────</tspan></text><text xml:space="preserve" x="20" y="202.7"><tspan fill="#c9d1d9">     Time (0   0.5ms  1ms)</tspan></text></g></svg>

Applications

ApplicationBenefit of Laser Anneal
Source/drain activationUltra-shallow junctions (5-8 nm) with high activation
Contact resistance reductionHigher active doping → lower R_contact
Strain engineeringActivate SiGe S/D without relaxing strain
3D stackingLow thermal impact on lower layers
BEOL annealCan anneal top layers without damaging metal interconnects

Nanosecond Laser Anneal (Melt Anneal)

Challenges

ChallengeIssueMitigation
Pattern density effectDifferent structures absorb differentlyAbsorber layers, tuned wavelength
Temperature measurement<1 ms duration → hard to measure TEmissivity models, pyrometry
Wafer stressRapid thermal gradient → potential slipControlled ramp, back-side heating
ThroughputScan entire 300mm waferMulti-beam, wide line beams

Semiconductor laser annealing is the thermal processing breakthrough that decoupled dopant activation from dopant diffusion — by achieving temperatures high enough for complete activation in timeframes too short for diffusion, laser annealing enables the ultra-shallow, heavily-doped junctions that make sub-5nm transistors possible, representing one of the most critical process innovations in advanced CMOS manufacturing.

semiconductor laser anneallaser spike anneallsamillisecond annealultrafast annealing

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