Reduction in Polysilicon Oxide Leakage Current by Annealing prior to Oxidation

Shinada, K.; Mori, S.; Mikata, Y.

doi:10.1149/1.2114316

Cited by 27 publications

(14 citation statements)

References 5 publications

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“…Celle-ci évolue jusqu'à près de 70 nm après un traitement de recuit ou d'oxydation à haute température. Notons que cette taille initiale des grains est plus petite que celle d'échantillons de silicium polycristallin dopés par diffusion, à partir d'une source de POCI3 (50 nm environ [13,18]). Par ailleurs, la température de dopage par diffusion est nettement supérieure (900 °C-1 000 °C) à la température du dopage in situ (670 °C), ce qui entraîne la présence de contraintes thermiques.…”

Section: Méthodes Analytiques -Les Caractéristi-unclassified

Evolution de la taille des grains du silicium polycristallin pendant des traitements thermiques ou oxydation

Lemiti¹,

Audisio

Maï

et al. 1989

Rev. Phys. Appl. (Paris)

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Nous avons comparé l'évolution de la morphologie cristallographique de couches épitaxiques de silicium polycristallin (résistivité de 9 x 10 -3 Ω.cm, épaisseur de 450 nm, dépôt L.P.C.V.D. à 670°C par décomposition du silane) soumises pendant 6 à 180 min, à un traitement thermique à température élevée (entre 900 °C et 1 050 °C) sous atmosphère soit inerte (argon), soit oxydante (oxygène sec). L'évolution de la taille des cristallites de la couche polycristalline a été mise en évidence par diffraction des rayons X. Dans les deux cas, on observe un accroissement (plus rapide lors d'une oxydation) de la taille des grains (de moins de 20 nm à plus de 70 nm), correspondant à une cristallisation des zones amorphes, favorisée par la diffusion du dopant (phosphore) aux joints de grains et par l'existence de contraintes mécaniques. La vitesse de formation de l'oxyde est çontrôlée par l'orientation cristallographique aléatoire des grains et la présence des joints de grains (diffusion intergranulaire et ségrégation des dopants). Le claquage destructif de l'oxyde n'est pas direct, on observe souvent une phase de préclaquage avec une auto-guérison. La rigidité diélectrique dépend du dopage et varie de 2 MV/cm à 5 MV/cm quand la température d'oxydation passe de 900 °C à 1000 °C

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Section: Méthodes Analytiques -Les Caractéristi-unclassified

Evolution de la taille des grains du silicium polycristallin pendant des traitements thermiques ou oxydation

Lemiti¹,

Audisio

Maï

et al. 1989

Rev. Phys. Appl. (Paris)

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“…11 The poly-Si deposition and doping processes establish the microstructure, dopant concentrations, and surface topography of these films. [2][3][4][13][14][15][16][17][18] The purpose of this work was to evaluate the surface topography of poly-Si films that are used for double-poly-Si capacitor applications. [2][3][4][13][14][15][16][17][18] The purpose of this work was to evaluate the surface topography of poly-Si films that are used for double-poly-Si capacitor applications.…”

Section: Introductionmentioning

confidence: 99%

Surface topography of phosphorus doped polysilicon

Hegde

Paulson

Tobin

1995

Journal of Vacuum Science &Amp; Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena

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The surface topography of doped polysilicon films was investigated by atomic force microscopy for a wide range of doping and process conditions. These low-pressure chemical vapor deposition silicon films were approximately 350 nm thick. The amorphous films were in situ phosphorus doped during deposition at 550°C, while the crystalline films were deposited at 625°C and subsequently diffusion doped using either PH 3 or POCl 3 gases. Measured resistivities ranged from 700 to 10 000 ⍀ cm corresponding to secondary ion mass spectrometry phosphorus concentrations that ranged from 8.45 to 0.95ϫ10 20 cm Ϫ3 . In situ doped films exhibited the smoothest surface topography with a peak-to-valley surface roughness of 11 nm. The surface roughness values were 50 nm for PH 3 doped poly films, and as high as 135 nm for the POCl 3 doped films. Atomic force microscopy grain size analysis showed uniform distributions for the in situ and PH 3 doped films with grain sizes of 130 and 200 nm, respectively. POCl 3 doped poly-Si showed bimodal grain size distributions, with the secondary grains measuring 500 nm in size and the normal grains averaging 225 nm. These secondary grains increased the surface roughness and their occurrence correlates with chlorine concentration. The number of secondary grains and their size increases with higher phosphorus content. Following the polyoxide growth, the surface roughness increased 3ϫ to 5ϫ with POCl 3 doping, but the surface topography increased only slightly for PH 3 and in situ doped poly-Si. After removing the polyoxide, the surface roughness decreased for the diffusion doped films. In situ doped films retained their smooth surface following the oxidation and removal of the oxide.

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“…It is seen that the effective barrier heights were almost the same for these samples. Since the barrier height value is very sensitive to the interface texture structure [8], this implied that the fluorine-induced improvement of polyoxide characteristics was not caused by the change of the polysilicodpolyoxide interface texture. We would then suspected that the improvement of the polyoxide property is caused by the oxide stress relaxation due to the incorporation of fluorine.…”

Section: Resultsmentioning

confidence: 99%