STRUCTURE AND EVOLUTION OF THE DISPLACEMENT FIELD IN HYDROGEN-IMPLANTED SILICON

被引：37

作者：

CEROFOLINI, GF

MEDA, L

VOLPONES, C

OTTAVIANI, G

DEFAYETTE, J

DIERCKX, R

DONELLI, D

ORLANDINI, M

ANDERLE, M

CANTERI, R

CLAEYS, C

VANHELLEMONT, J

机构：

[1] UNIV MODENA, DEPARTIMENTO FIS, I-41100 MODENA, ITALY

[2] EEC JOINT RES CTR, I-21020 ISPRA, ITALY

[3] IST RIC SCI & TECNOL, DIV SCI MAT, I-38050 TRENT, ITALY

[4] INTERUNIV MICROELECTR CTR, B-3030 LOUVAIN, BELGIUM

来源：

PHYSICAL REVIEW B | 1990年 / 41卷 / 18期

关键词：

D O I：

10.1103/PhysRevB.41.12607

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

Hydrogen implantation into silicon at room temperature and at 77 K has been studied by secondary-ion mass spectrometry (SIMS), elastic recoil diffusion analysis (ERDA), Rutherford backscattering spectroscopy (RBS), multiple-crystal x-ray diffraction (XRD), conventional and high-resolution transmission electron microscopy (TEM and HREM), and binary-collision simulation (marlowe). The implantation energy was 15.5 keV, low enough not to form dense collisional cascades; the fluence range was 1014 to 2×1016 cm-2. Annealing experiments were carried out by heating the implanted samples for 2 h in the temperature interval 400800°C. While the hydrogen profile is well described by marlowe simulation, the resulting crystal deformation, measured by RBS, XRD, TEM, and HREM, cannot be interpreted in terms of damage imparted to the silicon target, but is mainly related to the displacement field around hydrogen. An accurate analysis is, however, able to separate the contributions due to self-interstitials from that due to hydrogen. The threshold energy for Frenkel-pair production is determined and is found to be 435 eV, remarkably higher than the commonly accepted value of 15 eV. © 1990 The American Physical Society.

引用

页码：12607 / 12618

页数：12

共 26 条

[11]

CEROFOLINI GF, 1986, SEMICONDUCTOR SILICO, P706

[12] DISTRIBUTION OF IRRADIATION DAMAGE IN SILICON BOMBARDED WITH HYDROGEN [J].

CHU, WK ;

KASTL, RH ;

LEVER, RF ;

MADER, S ;

MASTERS, BJ .

PHYSICAL REVIEW B, 1977, 16 (09) :3851-3859

[13]

DAVIES JA, 1975, PHYS REV LETT, V34, P1141

[14]

DESSEAUXTHIBAUL.I, 1983, I PHYS C SER, V67, P71

[15] DEFECT FORMATION IN H-IMPLANTATION OF CRYSTALLINE SI [J].

KEINONEN, J ;

HAUTALA, M ;

RAUHALA, E ;

KARTTUNEN, V ;

KURONEN, A ;

RAISANEN, J ;

LAHTINEN, J ;

VEHANEN, A ;

PUNKKA, E ;

HAUTOJARVI, P .

PHYSICAL REVIEW B, 1988, 37 (14) :8269-8277

[16] HYDROGEN DEPTH PROFILING USING SIMS - PROBLEMS AND THEIR SOLUTIONS [J].

MAGEE, CW ;

BOTNICK, EM .

JOURNAL OF VACUUM SCIENCE & TECHNOLOGY, 1981, 19 (01) :47-52

[17] HYDROGEN IMPLANTATION INTO (100) SILICON - A STUDY OF THE RELEASED DAMAGE [J].

MEDA, L ;

CEROFOLINI, GF ;

DIERCKX, R ;

MERCURIO, G ;

SERVIDORI, M ;

CEMBALI, F ;

ANDERLE, M ;

CANTERI, R ;

OTTAVIANI, G ;

CLAEYS, C ;

VANHELLEMONT, J .

NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION B-BEAM INTERACTIONS WITH MATERIALS AND ATOMS, 1989, 39 (1-4) :381-385

[18] CHANNELING INVESTIGATION OF PROTON AND DEUTERON DAMAGE IN GERMANIUM [J].

MITCHELL, JB ;

FOTI, G ;

HOWE, LM ;

DAVIES, JA .

RADIATION EFFECTS AND DEFECTS IN SOLIDS, 1975, 26 (03) :193-199

[19]

MITCHELL JB, 1975, ION IMPLANTATION SEM, P493

[20] HYDROGEN IN CRYSTALLINE SEMICONDUCTORS [J].

PEARTON, SJ ;

CORBETT, JW ;

SHI, TS .

APPLIED PHYSICS A-MATERIALS SCIENCE & PROCESSING, 1987, 43 (03) :153-195

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