Current Understanding and Modeling of B Diffusion and Activation Anomalies in Preamorphized Ultra-Shallow Junctions

Colombeau, B.; Smith, Andrew J.; Cowern, N.E.B.; Pawlak, Bartek; Cristiano, Fuccio; Duffy, Ray; Claverie, A.; Ortiz, C.J.; Pichler, P.; Lampin, E.; Zechner, Christoph

doi:10.1557/proc-810-c3.6

Cited by 43 publications

(41 citation statements)

References 23 publications

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“…3, we have chosen to compare the number of interstitials reaching the surface with the measured deactivation, using vertical scales differing by a factor of 2, corresponding to the usually observed deactivation of about two B atoms by one interstitial. 16,17 The agreement is good for all data points except the first ͑remaining crystal thickness of 37 nm͒ for which the EOR band slightly overlapped the B implant distribution. The slightly low value for this point could be a result of direct deactivation by implanted interstitials prior to annealing.…”

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confidence: 67%

“…As this EOR band evolves, it releases self-interstitials, causing transient enhanced diffusion ͑TED͒ and boron-interstitial cluster ͑BIC͒ formation which manifests itself as electrical deactivation. 4 In SOI, a proportion of the emitted self-interstitials may migrate to nearby sinks such as the silicon/buried oxide ͑BOX͒ interface, thus reducing the amount of B deactivation that occurs. 5 This letter quantifies the role of the BOX and shows the dramatic advantages-in terms of reduced diffusion and deactivation-that can be achieved by exploiting the positioning of the EOR defect band within the silicon top layer in SOI.…”

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confidence: 99%

“…At low PAI energies, the characteristic deactivation and reactivation of B are observed, arising from the formation and subsequent dissolution of BICs. 4 However, as the PAI energy is increased, bringing the EOR defect band toward the BOX interface, the amount of deactivation decreases very dramatically.…”

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Boron deactivation in preamorphized silicon on insulator: Efficiency of the buried oxide as an interstitial sink

Hamilton

Kirkby

Cowern

et al. 2007

Applied Physics Letters

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Preamorphization of ultrashallow implanted boron in silicon on insulator is optimized to produce an abrupt boxlike doping profile with negligible electrical deactivation and significantly reduced transient enhanced diffusion. The effect is achieved by positioning the as-implanted amorphous/ crystalline interface close to the buried oxide interface to minimize interstitials while leaving a single-crystal seed to support solid-phase epitaxy. Results support the idea that the interface between the Si overlayer and the buried oxide is an efficient interstitial sink. © 2007 American Institute of Physics. ͓DOI: 10.1063/1.2778749͔Highly activated ultrashallow boxlike doping profiles are an important requirement for advanced planar complementary metal oxide semiconductor ͑MOS͒ applications. 1 A promising fabrication approach for p-channel MOS transistors is the use of Ge preamorphizing implants ͑PAIs͒ prior to ultralow energy B implantation. This reduces channeling and increases electrical activation due to solid-phase epitaxial regrowth ͑SPER͒. 2 For future technology nodes, bulk Si wafers may be replaced by silicon on insulator ͑SOI͒. 3 Unfortunately, in both bulk Si and SOI, the PAI implantation step causes an interstitial-rich "end-of-range" ͑EOR͒ defect band to form on further annealing. As this EOR band evolves, it releases self-interstitials, causing transient enhanced diffusion ͑TED͒ and boron-interstitial cluster ͑BIC͒ formation which manifests itself as electrical deactivation. 4 In SOI, a proportion of the emitted self-interstitials may migrate to nearby sinks such as the silicon/buried oxide ͑BOX͒ interface, thus reducing the amount of B deactivation that occurs. 5 This letter quantifies the role of the BOX and shows the dramatic advantages-in terms of reduced diffusion and deactivation-that can be achieved by exploiting the positioning of the EOR defect band within the silicon top layer in SOI. We will show that two distinct physical processes are involved: the removal of interstitials at the BOX interface following diffusion within the Si overlayer and the cutting off of the "as-implanted" excess interstitial profile within the BOX.Experiments were performed on n-type ͗100͘ Czochralski Si wafers with a resistivity of ϳ10-25 ⍀ cm, and on SOITEC© SOI wafers with a nominal 145 nm BOX and a 55 nm p-type Si overlayer. The wafers were implanted with Ge + at 8, 20, 24, 28, 32, or 36 keV to a dose of 1 ϫ 10 15 cm −2 , amorphizing to depths of ϳ20, 40, 45, 50, 55, and 60 nm, respectively, as determined by Rutherford backscattering spectrometry ͑RBS͒ and cross-sectional transmission electron microscopy ͑XTEM͒. Boron was subsequently implanted at 500 eV to a dose of 2 ϫ 10 15 cm −2 at 0°tilt and 0°twist. RBS used a 1.5 MeV He beam at 45°to the sample. 6 After implantation, samples received isochronal rapid thermal annealings in N 2 ambient, using a Process Products Corporation 18-lamp system ͑with lamps above and below the sample͒ operating with a set time of 60 s at temperatures in the range of 700-1000°C, considere...

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Boron deactivation in preamorphized silicon on insulator: Efficiency of the buried oxide as an interstitial sink

Hamilton

Kirkby

Cowern

et al. 2007

Applied Physics Letters

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“…During higher temperature annealing these defects undergo a series of transitions from self-interstitial clusters to ͕113͖ defects to dislocation loops depending on the initial PAI and subsequent conditions. 3 These defects dissolve during annealing and the silicon self-interstitials so released migrate to nearby sinks such as the silicon surface. 3 Transient enhanced diffusion and B electrical deactivation result from the interstitials that diffuse towards the silicon surface during annealing.…”

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“…3 These defects dissolve during annealing and the silicon self-interstitials so released migrate to nearby sinks such as the silicon surface. 3 Transient enhanced diffusion and B electrical deactivation result from the interstitials that diffuse towards the silicon surface during annealing. 3,4 In the absence of sinks within the silicon, all of the released interstitials diffuse towards the surface.…”

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Diffusion and activation of ultrashallow B implants in silicon on insulator: End-of-range defect dissolution and the buried Si∕SiO2 interface

Hamilton

Cowern

Sharp

et al. 2006

Applied Physics Letters

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The fabrication of preamorphized p-type ultrashallow junctions in silicon-on-insulator ͑SOI͒ has been investigated. Electrical and structural measurements after annealing show that boron deactivation and transient enhanced diffusion are reduced in SOI compared to bulk wafers. The reduction is strongest when the end-of-range defects of the preamorphizing implant are located deep within the silicon overlayer of the SOI silicon substrate. Results reveal a very substantial increase in the dissolution rate of the end-of-range defect band. A key player in this effect is the buried Si/ SiO 2 interface, which acts as an efficient sink for interstitials competing with the silicon surface. © 2006 American Institute of Physics. ͓DOI: 10.1063/1.2240257͔ Formation of highly activated, ultrashallow, and abrupt profiles is a key requirement for the next generation of complementary metal oxide semiconductor ͑CMOS͒ devices, particularly for source-drain extensions.1 For p-type ͑boron͒ dopant implants, a promising method of increasing junction abruptness is to use Ge preamorphizing implants ͑PAI͒ prior to ultralow energy B implantation. Advantages of this method are a reduction in B channeling and an increase in B electrical activation due to the solid-phase-epitaxial ͑SPE͒ regrowth process. 2 SPE regrowth of the amorphized silicon does not remove interstitial defects located at depths greater than the initial amorphous/crystalline ͑a / c͒ interface. Excess interstitial atoms in this region agglomerate into "end-of-range" ͑EOR͒ defects situated just below the former a / c interface. During higher temperature annealing these defects undergo a series of transitions from self-interstitial clusters to ͕113͖ defects to dislocation loops depending on the initial PAI and subsequent conditions.3 These defects dissolve during annealing and the silicon self-interstitials so released migrate to nearby sinks such as the silicon surface.3 Transient enhanced diffusion and B electrical deactivation result from the interstitials that diffuse towards the silicon surface during annealing. 3,4 In the absence of sinks within the silicon, all of the released interstitials diffuse towards the surface. Thus they either end up reacting with B atoms in the implant or migrating unscathed through the B-doped layer to the silicon surface-the former being the more probable event in the case of highdose B implants.One possible method to reduce the number of interstitials that migrate to the B implanted region is to provide an efficient alternative sink for the interstitials. In this letter we investigate whether the buried oxide interface of the silicon top layer in silicon on insulator ͑SOI͒ may function in this way. This question is of considerable importance as SOI emerges as a candidate technology for future CMOS applications. 5Experiments were performed on n-type ͗100͘ Czochralski silicon wafers with a resistivity of ϳ10-25 ⍀ cm and on SOI wafers with a 145-nm-thick buried oxide and a 55-nm-thick p-type Si overlayer. Silicon and Soitec© SOI wafers were i...

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Continuum simulation of solid phase epitaxial regrowth of amorphized silicon including most advanced physical interactions

Delalleau

Pakfar

Bazizi

et al. 2010

Physica Status Solidi (a)

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Solid‐phase‐epitaxial regrowth (SPER) of Si amorphized by ion implantation is considered as a potential solution for the fabrication of highly‐activated ultra‐shallow junctions for future technology nodes of Si CMOS devices. In the frame of 32 and 22 nm technologies node development, SPER occurs after amorphizing implantations used in source/drain regions. To get an accurate simulation of dopant activation and junction depth position, a suitable continuum SPER model, implemented into a commercial simulator, is now mandatory. This TCAD model must consider the different physical effects associated with SPER: silicon regrowth rate, dopants redistribution snow plough effect, and interaction with silicon point defects. In this work, using a previously established model, we have implemented an improved physically based model for SPER and, several formulations have been developed to enable a robust/accurate modeling of the recrystallization velocity. It takes into account the direct interaction between amorphous/crystalline interface kinetics and point defects, and a regrowth rate dependent on temperature. Simulation results of dopant concentration profiles are in good agreement with experimental data and can provide important insight for optimizing the bulk silicon process as well in one dimension as two dimensions.

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Current Understanding and Modeling of B Diffusion and Activation Anomalies in Preamorphized Ultra-Shallow Junctions

Cited by 43 publications

References 23 publications

Boron deactivation in preamorphized silicon on insulator: Efficiency of the buried oxide as an interstitial sink

Boron deactivation in preamorphized silicon on insulator: Efficiency of the buried oxide as an interstitial sink

Diffusion and activation of ultrashallow B implants in silicon on insulator: End-of-range defect dissolution and the buried Si∕SiO2 interface

Continuum simulation of solid phase epitaxial regrowth of amorphized silicon including most advanced physical interactions

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