Effect of fluorine implantation dose on boron thermal diffusion in silicon

Mubarek, H.A.W. El; Bonar, J. M.; Dilliway, G.; Ashburn, P.; Karunaratne, M. S. A.; Willoughby, A. F. W.; Wang, Y.; Hemment, P.L.F.; Price, R.W.; Zhang, J.; Ward, Peter

doi:10.1063/1.1790063

Cited by 30 publications

(23 citation statements)

References 25 publications

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“…15 Recent work on fluorine implantation into preamorphized silicon has also suggested that V-F clusters are responsible for the suppression of boron transient enhanced diffusion. 9 However, contradictory results have also been reported, 16 which indicate that for fluorine implants into crystalline SiGe, suppression of boron TED is also obtained even when the shallow SIMS peak due to V-F clusters is not present. These results suggest that mechanisms other than V-F clusters can contribute to the suppression of boron diffusion in Si and SiGe.…”

Section: Introductionmentioning

confidence: 81%

Reduced boron diffusion under interstitial injection in fluorine implanted silicon

Kham

Maťko

Chenevier

et al. 2007

Journal of Applied Physics

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Point defect injection studies are performed to investigate how fluorine implantation influences the diffusion of boron marker layers in both the vacancy-rich and interstitial-rich regions of the fluorine damage profile. A 185 keV, 2.3ϫ 10 15 cm −2 F + implant is made into silicon samples containing multiple boron marker layers and rapid thermal annealing is performed at 1000°C for times of 15-120 s. The boron and fluorine profiles are characterized by secondary ion mass spectroscopy and the defect structures by transmission electron microscopy ͑TEM͒. Fluorine implanted samples surprisingly show less boron diffusion under interstitial injection than those under inert anneal. This effect is particularly noticeable for boron marker layers located in the interstitial-rich region of the fluorine damage profile and for short anneal times ͑15 s͒. TEM images show a band of dislocation loops around the range of the fluorine implant and the density of dislocation loops is lower under interstitial injection than under inert anneal. It is proposed that interstitial injection accelerates the evolution of interstitial defects into dislocation loops, thereby giving transient enhanced boron diffusion over a shorter period of time. The effect of the fluorine implant on boron diffusion is found to be the opposite for boron marker layers in the interstitial-rich and vacancy-rich regions of the fluorine damage profile. For marker layers in the interstitial-rich region of the fluorine damage profile, the boron diffusion coefficient decreases with anneal time, as is typically seen for transient enhanced diffusion. The boron diffusion under interstitial injection is enhanced by the fluorine implant at short anneal times but suppressed at longer anneal times. It is proposed that this behavior is due to trapping of interstitials at the dislocation loops introduced by the fluorine implant. For boron marker layers in the vacancy-rich region of the fluorine damage profile, suppression of boron diffusion is seen for short anneals and then increased diffusion after a critical time, which is longer for inert anneal than interstitial injection. This behavior is explained by the annealing of vacancy-fluorine clusters, which anneal quicker under interstitial injection because the injected interstitials annihilate vacancies in the clusters.

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Section: Introductionmentioning

confidence: 81%

Reduced boron diffusion under interstitial injection in fluorine implanted silicon

Kham

Maťko

Chenevier

et al. 2007

Journal of Applied Physics

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“…Enhanced Diffusion (and thermal diffusion) of B in Si can be suppressed by F implantation, which may form larger defects that soak up interstitials [6] . However the detailed electrical activity of F clusters (with anything) is yet to be established.…”

Section: Application To Device Developmentmentioning

confidence: 99%

“…A further solution may lie in the introduction of another ion which promotes vacancy formation or retention, thus reducing the interstitial population, and hence reducing all diffusion. A possible candidate species currently under investigation is F [6], but other elements such as C may also have the same effect. 9], but this has more recently been shown not to be the case [10].…”

Section: Introductionmentioning

confidence: 99%

Deep electronic states in ion-implanted Si

et al. 2006

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In this paper we present an overview of the deep states present after ion-implantation by various species into n-type silicon, measured by Deep Level Transient Spectroscopy (DLTS) and high resolution Laplace DLTS (LDLTS). Both point and small extended defects are found, prior to any anneal, which can therefore be the precursors to more detrimental defects such as end of range loops. We show that the ion mass is linked to the concentrations of defects that are observed, and the presence of small interstitial clusters directly after ion implantation is established by comparing their behaviour with that of electrically active stacking faults. Finally, future applications of the LDLTS technique to ion-implanted regions in Si-based devices are outlined.2

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“…10 Over the past few years there has been considerable interest in the effect of fluorine on boron diffusion in silicon to suppress boron diffusion. [11][12][13][14][15][16][17][18][19] Research on the effects of fluorine from a BF 2 + implant reveals that shallower junctions could be obtained when BF 2 + was implanted instead of boron. [11][12][13] Also, it has been reported that fluorine was implanted separately into the boron to characterize the effect of the fluorine on boron diffusion.…”

mentioning

confidence: 99%

“…This work shows that the fluorine implant reduced boron TED and increased boron activity. [14][15][16][17][18][19] In conjunction with these studies, the deactivation of dopants also should be considered because the postannealing process is accompanied with the deactivation of dopants during device fabrication. In the case of boron, Takamura et al 20 have already shown that the deactivation of boron in laser-annealed silicon is stable.…”

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confidence: 99%

Ultrashallow p[sup +]∕n Junction Prepared by Low Energy BF[sub 3] Plasma Doping and KrF Excimer Laser Annealing

Lee

Baek

Heo

et al. 2006

Electrochem. Solid-State Lett.

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We have investigated the activation and deactivation of the 1 kV BF 3 plasma doping ͑PLAD͒ with excimer laser annealing ͑ELA͒. Half of the dopants were activated by ELA, and the deactivation was dramatically increased after the postannealing. We have confirmed that 1 kV BF 3 PLAD did not form an amorphous layer at the substrate using X-ray transmission electron microscopy ͑X-TEM͒ and that boron and fluorine segregated after annealing using secondary ion mass spectroscopy profiles and plane-view TEM. Based on the results, we proved that fluorine can suppress boron diffusion, although it retards the activation and increases the deactivation of BF 3 PLAD with ELA.As the dimensions of devices become smaller, the size and junction depths of devices must be made shallower to prevent the short channel effect. According to The International Technology Roadmap for Semiconductors, ͑ITRS͒ the junction depth of the lightly doped drain ͑LDD͒ region may be as shallow as roughly 20-30 nm in a 0.1 m metal oxide semiconductor field effect transistor ͑MOSFET͒ device. 1 Compared with the n + /p junction, it is difficult to form an untrashallow p + /n junction due to boron channeling and transientenhanced diffusion ͑TED͒ which is related to extra interstitials generated during the implantation. 2,3 Therefore, many studies have been conducted to discover alternative methods for shallower p + /n junctions. 4-6 Plasma doping ͑PLAD͒, which is a method to create a shallow junction, has been studied as a replacement for conventional ion implantation. 7 However, at a low doping energy of 1 kV or less, TED during activation annealing is inevitable. 8,9 Therefore, to reduce the enhanced diffusion and to obtain a highly activated dopant profile, excimer laser annealing ͑ELA͒ has also been studied. 10 Over the past few years there has been considerable interest in the effect of fluorine on boron diffusion in silicon to suppress boron diffusion. [11][12][13][14][15][16][17][18][19] Research on the effects of fluorine from a BF 2 + implant reveals that shallower junctions could be obtained when BF 2 + was implanted instead of boron. 11-13 Also, it has been reported that fluorine was implanted separately into the boron to characterize the effect of the fluorine on boron diffusion. This work shows that the fluorine implant reduced boron TED and increased boron activity. [14][15][16][17][18][19] In conjunction with these studies, the deactivation of dopants also should be considered because the postannealing process is accompanied with the deactivation of dopants during device fabrication. In the case of boron, Takamura et al. 20 have already shown that the deactivation of boron in laser-annealed silicon is stable.To be conclusive further studies are needed to investigate how the low energy BF 3 PLAD with ELA is effective for forming an ultrashallow junction. In this paper, we report the electrical properties of the low-energy BF 3 PLAD activated by ELA and the behavior of boron and fluorine after the annealing along with time-offlight ͑TOF͒ second...

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Effect of fluorine implantation dose on boron thermal diffusion in silicon

Cited by 30 publications

References 25 publications

Reduced boron diffusion under interstitial injection in fluorine implanted silicon

Reduced boron diffusion under interstitial injection in fluorine implanted silicon

Deep electronic states in ion-implanted Si

Ultrashallow p[sup +]∕n Junction Prepared by Low Energy BF[sub 3] Plasma Doping and KrF Excimer Laser Annealing

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