`Temperature Chemical Vapor Deposition from Titanium
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`Tetraiodide
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`ham, Dirk Manger, Gregory Peterson,
`Cheryl Faltermeier, Cindy Goldberg, Michael Jones, Allan Up
`Janice Lau, and Alain E. Ka
`oyeros
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`New York State Center for Advanced Thin Film Technology and Department of Physics, The University at Albany,
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`State University of New York, Albany, New York 12222, USA
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`Barry Arkles
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`Gelest, Incorporated, Tullytown, Pennsylvania 19007, USA
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`Aiit Paranipe“
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`Texas Instruments, Incorporated, Dallas, Texas 75265, USA
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`ABSTRACT
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`. Results are presented from a systematic study of the composition, texture, and electrical properties of titanium nitride
`(TiN) films and their performance as diffusion barrier in multilevel interconnect schemes of ultralarge scale integration
`(ULSI) computer chip device structures. The films were grown by low temperature (<450°C) inorganic chemical vapor
`deposrtion using titanium tetraiodide as source precursor and ammonia and hydrogen as co-reactants. The TiN films were
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`nitrogen-rich, with iodine concentrations below 2 atom percent, displayed resistivities in the range 100 to 150 p!) cm
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`depending on thickness, and exhibited excellent step coverage with better than 90% conformality in both nominal 0.45 am,
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`3:1 aspect ratio and 0.25 am, 4:1 aspect ratio contact structures. A comparison of the properties of chemical vapor
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`deposited (CVD) TiN with equivalent physical vapor deposited (PVD) TiN showed that reactivity with Al—0.5 a/o Cu alloys
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`was equivalent in both cases. In particular, a 10% increase in the Al—Cu/TiN stack sheet resistance was observed for both
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`types of TiN after a 450°C, 30 min sinter. Similarly, the characteristics of CVD tungsten and reflow plug fills were iden—
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`tical on both types of TiN films. However, barrier performance for CVD TiN in aluminum and tungsten plug technologies
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`was superior to that of PVD TiN, as evidenced by lower contact diode leakage for CVD TiN in comparison with PVD TiN
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`films of equal thickness. This improved barrier performance could be attributed to a combination of factors, which
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`include the nitrogen—rich composition, higher density, and enhanced conformality of the CVD TiN phase in comparison
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`with the PVD TiN. In view of the superior step coverage and diffusion barrier characteristics, the low temperature inor—
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`ganic CVD route to TiN seems to provide an adequate replacement for conventional PVD TiN in emerging ULSI metal—
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`lization interconnect schemes.
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`plicity, controllability, and ability to coat large area sub-
`Introduction
`strates with excellent uniformity at industrially viable
`Titanium nitride (TiN) is a commonly used material in
`growth rates, CVD could potentially meet performance
`current integrated circuit (IC) technologies.1 Its applica-
`demands well into the 0.18 am device technology and
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`tions range from diffusion barrier and glue layer at the
`beyond.
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`contact/via level to diffusion barrier and antireflection
`Early attempts at preparing CVD TiN used mostly tita-
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`coating in the interconnect stack.2 Such applications are
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`nium tetrachloride (TiCl4) and ammonia (NH3) to yield stoi-
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`made possible by the desirable properties of TiN, includ—
`chiometric TiN films having good step coverage.7 The
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`ing its refractory nature at elevated temperature, excellent
`impurities produced by this process, mainly chlorine, were
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`mechanical, chemical, and thermal inertness, and good
`within 1 atomic percent (a/o). Unfortunately, the process-
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`resistance to corrosion. These properties allow TiN to
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`ing temperatures required to produce these films were in
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`withstand the repeated thermal cycles use in multilevel
`excess of 650°C, and were thus prohibitive for use above
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`metallization of IC devices, and make its continued use in
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`the contact level. Efforts to reduce deposition tempera—
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`emerging subquarter micron device technologies highly
`tures included plasma—assisted CVD (PACVD) of TiCl4 in a
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`desirable. However, the suitability of TiN for such appli-
`mixture of nitrogen and hydrogen, electron cyclotron res—
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`cations is only possible if it is deposited with good confor-
`onance (ECR) plasma CVD of TiCl4 in a nitrogen atmos—
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`mality in subquarter micron features, leading to void-free
`phere,8 and atmospheric pressure CVD (APCVD) using
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`plug formation, reduced junction leakage, and low con—
`TiCl4 and isopropylamine or tert-butylamine as the co—
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`tact/via resistance. This requirement is further complicat—
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`reactant.9 These efforts led to an appreciable reduction in
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`ed by a strong push to reduce barrier thickness, as device size
`process temperatures to within the acceptable range of
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`about 350 to 500°C. However, various reliability issues
`shrinks, to provide the cross section of aluminum or copper
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`conductor required for optimum device performance.
`ranging from poor step coverage (30 to 70%) in some cases,
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`Conventional physical vapor deposition (PVD) routes to
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`to high resistivities (> 200 a!) cm) and chlorine contami—
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`TiN, with their inherent line of sight type deposition,
`nation above several atomic percent, in other cases, pre-
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`appear to have reached their maximum useful lifetime,
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`vented their incorporation in the IC process flow.
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`even with the addition of special features such as collima-
`There are several recent reports on metallorganic CVD
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`t0rs.3 Modified PVD processes,
`including high density
`(MOCVD) of TiN from dialkylamino derivatives of titani~
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`plasma sputtering, appear to provide acceptable near term
`um of the type Ti(NR2)4, where R is a methyl or ethyl
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`solutions, at least for the 0.25 pm device generation.“'6
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`group.10 Additional MOCVD studies involved the use of
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`Chemical vapor deposition (CVD), on the other hand,
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`single—source
`titanium precursors
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`of
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`offers a low temperature alternative which is inherently
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`[TiC12(NHR2)(NH2R)H] and [TiCl4(NR3)2], and cyclopenta—
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`capable of conformal metal growth. By combining sim—
`dienyl—based titanium compounds of the type biscyclopen-
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`tadienyl titanium diazide, szTi(N3)2 (where Cp = C5H5).11
`3 Present address: CVC Products, Inc., Rochester, New York
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`These activities led to the development of robust and ver—
`14603, USA.
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`J. Electrochem. 800., Vol. 144, No. 3, March 1997 © The Electrochemical Society, Inc.
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`Tianma Exhibit 1014
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`1 002
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`Page 1 of 7
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`Page 1 of 7
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`Tianma Exhibit 1014
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`J. Electrochem. 800., Vol. 144, No.3, March 1997 © The Electrochemical Society, Inc.
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`1003
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`satile MOCVD TiN processes,12 with MOCVD from
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`Ti(NEt2),,, for example, yielding resistivity below 300 pt!)
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`cm, carbon contamination under 3 a/o, and step coverage
`as high as 70% in 0.35 pun device structures.
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`The strategy espoused herein has focused, instead, on
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`low temperature inorganic CVD of TiN from titanium
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`tetraiodide (TiI4). Til, was selected because the dissocia—
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`tion energy of the Ti—I is relatively low, with a correspond—
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`ing heat of formation at 298 K of —92 kcal/mol. This
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`value is well below the heat of formation for TiCl4, name—
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`ly, — 192 kcal/mol. Accordingly, and in view of the similar
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`chemical characteristics of the two halide chemistries, TiI4
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`is expected to yield TiN films in an ammonia atmosphere
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`with properties and performance similar to those from
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`TiCl4 but at significantly lower temperature.
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`Additionally, the activation energy for iodine diffusion
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`is expected to be significantly higher than chlorine, given
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`that I is a much heavier element than C1. This expectation
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`is based on work on the interaction of fluorine and chlo—
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`rine with (111) 81,13 and which showed that the barrier for
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`chlorine penetration into the Si surface is much larger
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`than that for fluorine. This behavior was a consequence of
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`the larger size, and hence ionicity and resulting coulomb
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`interaction, of the chlorine atom in comparison with fluo-
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`rine. This property has important implications for the
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`effects of residual halide incorporation in the deposited
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`TiN, with 1 a/o iodine requiring appreciably higher ther—
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`mal energy to diffuse out of TiN lattice than its chlorine
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`counterpart. This observation is also supported by the
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`findings presented herein, including diode leakage meas—
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`urements, and which indicate that 2 a/o iodine did not
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`affect TiN performance as diffusion barrier/adhesion pro—
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`mater.
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`The paper is the second in a series of reports on the iden-
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`tification and optimization of a low temperature inorgan-
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`ic CVD process for TiN from Ti14.” The first report has
`focused on the development of a low—temperature, in situ,
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`sequential CVD process for the deposition of ultrathin
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`Ti/TiN bilayers for applications in device ULSI technolo—
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`gies. In this article, results are presented from a systemat—
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`ic study of the microstructural, microchemical, and elec-
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`trical characteristics of TiN films, as well as their
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`performance in 0.45 pm, 3:1 aspect ratio contact/plug
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`device structures. The findings from this study are com-
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`pared and contrasted with those from PVD TiN grown by
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`conventional PVD techniques.
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`Experimental
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`The CVD reactor used for inorganic CVD of TiN from
`TiI, was a custom-made, 8 in. wafer, cold wall system, and
`was described in detail elsewhere.13 Briefly, it consisted of
`a parallel plate plasma configuration with the wafer locat-
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`ed on the bottom electrode, which was resistively heated
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`using an externally positioned boron nitride—coated
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`graphite heater. The top active electrode was formed in the
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`shape of a circular mesh to allow unrestricted flow of the
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`reactants through a cone-shaped shower head located
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`above the mesh. Pumping was achieved through eight
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`ports which were symmetrically distributed below the
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`heater chuck to permit uniform gas flow distribution. A
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`standard pressure based sublimator was used to store the
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`solid TiI,1 precursor, which was delivered to the reaction
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`zone with the assistance of a hydrogen carrier gas.
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`Ammonia reactant flow was delivered through a sideline
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`directly to the reaction zone. A soft hydrogen plasma pre-
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`deposition clean was performed on all samples prior to
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`deposition. However, no plasma was used during actual
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`deposition. Several types of wafers were processed, as
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`shown in Table I, using the process conditions summarized
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`in Table II.
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`Methods of Analysis
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`The TiN film microchemical, microstructural, and elec-
`trical properties were thoroughly analyzed at the New
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`York State Center for Advanced Thin Film Technology by
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`Table I. Type and number of wafers used in the study.
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` Wafer type Number of wafers Thickness CVD TiN
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`1000 A PETEOS/Si
`900 i 50.A
`30 i 2 A
`Si
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`230 : 5 A,
`Si
`0.45 pm contact
`620 : 129A
`0.45 jun contact
`230 i 5 A°
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`0.45 pm contact
`300 i 10 A
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`0.45 pm contact
`400 : 10°A
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`0.45 pm contact/nI
`30 i 2 A
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`salicide junction
`0
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`0.45 pm contact/n"
`230 i 5 A
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`salicide junction
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`0.45 p.m contact/nI
`400 t 10 A
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`salicide junction
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`2
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`2
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`2
`1
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`3
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`3
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`Table II. Summary of processing parameters.
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`Process parameter
`Value
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`Source precursor
`Wafer temperature
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`Source temperature
`Reactor pressure
`Ammonia reactant flow
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`Hydrogen carrier gas flow
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`In situ predeposition
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`Hydrogen Plasma clean
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`'I‘iI4
`430°C
`140°C
`0.3 torr
`600 sccm
`30 sccm
`13.56 Mhz@
`0.08 W/cm2
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`x—ray photoelectron spectroscopy (XPS), Rutherford
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`backseattering (RBS), x-ray diffraction (XRD), four~point
`resistivity probe, and cross—sectional scanning electron
`microscopy (CS—SEM). In these studies, the results were
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`standardized using a pure TiN standard deposited by col—
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`limated sputtering at SEMATECH. Additional composi—
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`tional and structural characterization was also carried out
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`independently at SEMATECH.
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`Film composition was determined using XPS and RBS.
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`XPS was carried out on a Perkin—Elmer PHI 5500 Multi-
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`Technique System. A magnesium x-ray source at 15 kV
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`and 300 W was used. High resolution XPS scans employed
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`a 23.50 eV pass energy to resolve shifts from particular
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`photoelectron peaks.
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`In addition to performing compositional characteriza-
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`tion, RBS was also employed, in conjunction with CS—
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`SEM,
`for thickness and growth rate measurements.
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`Rutherford backseattering (RBS) spectra were taken using
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`a 2 MeV He+ beam, and calibrated with bulk samples of
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`gold and carbon, while CS—SEM investigations employed
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`a Zeiss DSM 940 microscope using a 20 keV primary elec—
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`tron beam. Four—point probe resistivity measurements
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`used a Signatone four-point probe. Deposition rates were
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`defined as T/t, where T is film thickness and t is run time.
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`Run time was measured starting form the instant when the
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`precursor was actually being delivered to the reactor.
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`X—ray diffraction was done on a Scintag XDS 2000 x—ray
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`diffractometer. X-rays were generated with a Cu K“ x-ray
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`source at typical tube operating power of 1.8 kW, which
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`corresponds to 40 mA and 45 kV. XRD spectra were col—
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`lected both in normal incidence and 5° grazing angle
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`geometries. The resulting TiN XRD patterns were com—
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`pared with the sputtered TiN standard provided by
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`SEMATECH and a TiN reference pattern from the stan—
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`dard JCPDS powder diffraction file (PDF).
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`A complete evaluation of the physical properties and
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`barrier characteristics of the TiN films was carried out at
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`the Semiconductor Process and Device Center of Texas
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`Instruments. The microchemical and electrical measure—
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`ments performed above at the Albany Center were repeat-
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`ed as an independent checking mechanism of TiN film
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`properties. The parameters measured and corresponding
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`methods of analysis are summarized in Table III and dis-
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`cussed in more detail in the following sections. In these
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`studies, the results were standardized using a pure TiN
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`standard deposited by collimated sputtering at Texas
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`Instruments.
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`Page 2 of 7
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`1 004
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`J. Electrochem. 800., Vol. 144, No.3, March 1997 © The Electrochemical Society, Inc.
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`100
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`Table IV. Summary of results.
`Table III. Methods of analysis.
`
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`Method
`Parameter
`Parameter
`Value
`
`
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`
`
`Four-pointprobe (900 A TiN on
`Deposition rate (A/min)
`200
`Sheet resistance
`1000 A PETEOS/Si)
`5 to 8
`Nonuniformity (%, lo)
`
`
`Step coverage (%)
`Profilometry (900 A TiN on 1000 A
`90
`PETEOS/Si) RB:
`Resistivity (11.0. cm)
`100 to 150
`TiN on 1000 A
`Weightgain (900
`Stoichiometry (TizN)
`1:1.06
`
`
`
`
`
`
`
`PETEOS/Si)
`<2 a/o iodine
`Impurities
`
`
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`
`
`RBS and XPS (900 A TiN on 1000 A
`<1 a/o oxygen
`
`
`
`
`
`
`
`
`PETEOS/Si)
`1.1 times that of PVD TiN
`Density
`
`
`
`
`
`CS—SEM (230, 400 900 A TiN on
`Golden
`Color
`
`
`
`
`
`
`
`
`0.45 and 0.25 urn contact)
`Zero
`Stability (ABS/2 h, %)
`
`
`230,400,600 AllTiN on
`Similar to PVD TiN
`CVD W plug fill
`
`
`
`
`
`
`
`
`
`
`Similar to PVD TiN
`0.45 pm contact
`A1 reflow plug fill
`
`
`
`
`Similar to PVD TiN
`Used 30 to 230 A CVD TiN on Si:
`Reactivity with Al—Cu
`
`
`
`
`
`
`Barrier property
`Superior to PVD TiN
`(2') Deposited 600 A A1—0 5 3/0 Cu
`
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`then spintered at 450 to 550°C for
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`30 to 60 min. (ii) Measured pre-
`
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`and post Al—Cu sheet resistance.
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`RBS analysis of TiN on Si also supported the XPS
`(iii) After sintering, metal was
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`stripped and o tical microscopy
`results, and indicated the presence of about 2 a/o iodine
`
`
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`
`
`used to quantify pit density1n Si.
`incorporation, as displayed in Fig. 4.
`
`
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`
`
`(iv) Samples on Si, plasma TEOS,
`
`
`
`
`The composition of the CVD produced TiN films was
`
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`PVD TiN were similarly processed
`
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`nitrogen-rich in comparison with the SEMATECH colli-
`and used for comparison.
`
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`mated PVD 'IiN. Levels of iodine in the films are not
`CS—SEM (230, 400, 900 A TiN on
`
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`0.45 pm contact
`
`
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`30to400ATiNon0.45 pun
`
`
`
`
`contact/n salicide junction
`
`
`
`30 to 400 A TiN on 0.45 pm
`
`
`
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`
`contact/n+ salicide junction
`
`
`
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`
`
`
`
`
`Thickness
`
`Density
`
`Composition
`
`Step coverage
`Barrier attack
`Barrier properties
`
`
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`
`
`W plug fill
`Contact resistance
`
`Diode leakage
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`
`
`(%)
`AtomicConcentration
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`8 6
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`0
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`
`Sputter Time (mins.)
`
`indicates a stoichiometric TiN phase
`Fig. 1. XPS depth protili
`
`
`
`
`
`with iodine concentration be ow 2 a/o. Noooxygen or other conta-
`XPS.
`ts
`minants were found within the detection limi
`
`
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`
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`
`
`
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`.. Q
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`454
`
`450
`
`
`
` NonnaltzedIntensity(arbitraryunits) 470
`
`
`
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`
`
`
`
`
`466
`
`458
`462
`Binding Energy (eV)
`
`Fig. 2. XPS high resolution spectrum of TiI2pm indicates a core
`
`
`
`
`
`peak at 455.1 eV corresponding to a pure TiN phase.
`
`
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`
`10
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`W O
`
`:
`
`
`
`a8
`
`402
`
`398
`Binding Energy (eV)
`
`394
`
`390
`
`A N
`
`:
`
`Q
`
`
`
`NormalizedIntensity(arbitraryunits)
`
`
`
`
`
`.3 The XPS N Is binding energy at 397.3 eV indicates a pure
`TiNiphase.
`
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`
`The 900 A CVD TiN films on plasma tetraethylorthosil-
`icate (PETEOS) were analyzed for sheet resistance, sheet
`thickness, density and composi—
`resistance uniformity,
`tion/stoichiometry. Sheet resistance was measured using a
`
`
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`four-point probe, thickness was calculated using a pro-
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`filometer, density was determined from weight gain
`
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`
`measurements, and composition/stoichiometry was
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`determined from RBS analysis. For the RBS analysis, a
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`PVD (conventional sputtering) TiN film was used as
`
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`
`control for comparison.
`
`
`
`The 30 to 230 A CVD TiN films on Si were used for bar-
`
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`
`
`rier studies. A 6000 A A1— 0.5 a/o Cu film was sputter
`
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`deposited on the CVD TiN and the stack was subjected to
`
`
`sintering at 450 to 550°C for 30 to 60 min. Sheet resistance
`
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`measurements prior to and after sintering were used to
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`quantify the reaction between Al—Cu and CVD TiN. After
`
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`sintering was complete, the metal was stripped and the
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`density of pits in the silicon was measured on an optical
`
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`
`
`microscope to quantify the quality of the CVD TiN barri-
`
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`
`
`er. 6000 A A1—0. 5 a/o Cu films deposited directly on Si,
`
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`
`plasma TEOS, and PVD TiN were also subjected to simi-
`
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`
`
`
`lar sinter cycles for comparison. The patterned contact
`
`
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`
`
`wafers were used for step coverage measurements and to
`
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`
`
`evaluate nucleation, barrier attack, and plug—fill during
`
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`CVD tungsten deposition. Finally, the contacts on the n"
`
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`salicided junctions were used to measure contact resist—
`
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`
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`ance and contact—induced diode leakage.
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`Results
`
`
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`
`
`
`The TiN films thus produced were metallic, mirror—like,
`
`
`
`
`and gold colored. Their physical properties are summa—
`rized in Table IV and discussed in more detail below. In
`particular, deposition nonuniformity is slightly high, but is
`
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`
`an equipment not a process issue, given that a custom-
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`made, nonoptimum, reactor was used in the study.
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`Film composition—The composition of the films was
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`
`
`examined by XPS and RBS. XPS depth profiling, as
`
`
`
`
`
`
`
`shown in Fig. 1, indicated a nitrogen-rich TiN,“ phase
`with iodine concentration below 2 a/o. No oxygen or other
`
`
`
`
`
`
`contaminants were found within the detection limits of XPS
`
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`
`
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`(~1a/o). Additionally, XPS high resolution spectra of ele-
`
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`
`
`
`mental core levels yielded a Ti 2p3,2 core peak at 455.1 eV,
`
`
`
`
`
`
`
`
`as displayed in Fig. 2, corresponding to a pure TiN phase.
`
`
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`
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`
`
`Figure 3 shows the N Is binding energy at 397.3 eV, also
`
`
`
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`
`
`
`indicating a pure TiN phase.
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`Page 3 of 7
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`Page 3 of 7
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`J. Electrochem. 800., Vol. 144, No.3, March 1997 © The Electrochemical Society, Inc.
`
`1 005
`
`30
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`toQ
`
`
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`NormalizedYield
`
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`10
`
`O
`
`100
`
`200
`
`300
`Channel
`
`500
`
`600
`
`Fig. 4. R35 analysis of TiN on Si sup
`rts the XPS results, and
`indicates the incorporation of about 2 f0Iodine.
`
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`expected to pose any reliability problems, such as Si
`
`wormhole formation and metal corrosion. This assessment
`is attributed to the higher activation energy for iodine dif-
`fusion as compared with chlorine, given that I is much
`
`
`
`
`
`
`
`
`heavier than Cl. Accordingly,
`it is expected that 1 a/o
`
`
`
`
`
`
`iodine might require appreciably higher thermal energy to
`
`
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`
`
`
`
`
`
`diffuse out of the TiN lattice than its chlorine counterpart,
`
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`
`
`
`
`
`thus posing less of a reliability problem. This assumption
`
`
`
`
`
`
`
`
`
`is supported by the findings presented herein and which
`
`
`
`
`
`
`
`demonstrate that TiN barrier integrity and device perfor-
`
`
`
`
`
`
`
`
`
`mance are not compromised by 2 a/o residual iodine levels.
`
`
`
`
`
`
`
`It is also in agreement with similar work reported by
`
`
`
`
`
`
`
`
`Yokoyama et al. on the mobility of chlorine in CVD TiN
`
`
`
`
`
`
`
`produced from the reaction of 'I‘iCl4 and NH3.15
`
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`Film texture—Figure 5 shows a typical XRD spectrum
`
`
`
`
`
`
`
`
`
`
`of a CVD TiN film. The spectrum exhibited reflections cor—
`
`
`
`
`
`
`responding to 20 = 42.340 (111) and 61.98 (220), with the
`(111) orientation exhibiting the highest diffraction inten-
`
`
`
`
`
`
`sity. Interestingly, the XRD spectrum displayed in Fig. 6
`
`
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`
`
`
`
`
`from SEMATECH’S sputter—deposited TiN film showed a
`
`
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`
`
`different XRD texture, with the (200) orientation showing
`
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`the strongest diffraction peak. Interestingly, Yokoyama et al.
`
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`
`also cfiibserved textural variations between CVD and PVD
`TiN.1
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`
`The textural variations observed might have significant
`
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`
`
`
`
`implications for the barrier characteristics and associated
`
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`
`
`
`
`differences in the peformance of CVD and PVD grown
`films. Additionally, it has been shown that the texture of
`
`
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`
`
`the TiN film can significantly affect that of the overlaying
`
`
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`
`
`aluminum film. Primarily, predominantly (200) textures
`
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`
`
`TiN leads to the formation of similarly textured alu-
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`Intensity(ArbitraryUnits)
`
`30
`
`‘ 0
`
`0
`
`60
`
`70
`
`Angle 29
`
`(degrees)
`
`Fig. 5. Typical XRD spectrum of a CVD TiN film. The diffraction
`k locations and intensifies are in good agreement with those
`fmfn a standard TiN powder sample, indicating that the TiN filmIs
`
`
`polycrystalline.
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`Page 4 of 7
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`Units)
`Intensitu(Arbitraru
`
`
`3o
`
`40
`
`60
`50
`Angle 29 (degrees)
`
`70
`
`Fig. 6. XRD spectrum of a sputter-deposited TiN film.
`
`
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`
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`
`
`
`
`minum, while (111) oriented TiN produces an identical
`aluminum orientation. This effect is important since pre-
`dominantly (111) oriented aluminum exhibits enhanced
`electromigration resistance and increased mean time to
`
`
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`
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`
`
`failure (MTTF) under electromigration stress conditions in
`
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`
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`comparison with its (200) counterpart.17 Additional stud—
`
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`
`
`ies are underway to study these effects and will be report—
`
`
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`
`
`ed in a subsequent publication.
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`Aggressive structure fill and resistivity—Figure 7 dis—
`
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`
`
`
`
`
`
`plays typical CS-SEM micrographs of TiN step coverage
`
`
`
`in aggressive device trench structures, with nominal fea—
`ture size of 0.45 pm, 3:1 aspect ratio. As can be seen, step
`
`
`
`
`
`coverage is excellent, with 90% conformality observed in
`
`
`
`
`
`
`
`the structures examined. Interestingly, highly conformal
`
`
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`
`
`TiN coverage was achieved across a wide process window,
`
`
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`
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`
`
`as demonstrated in Fig. 8 which shows 90% TiN step cov—
`
`
`
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`erage in 0.25 pm, 4:1 aspect ratio structures. These sam—
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`ples were processed at a substrate temperature of 425°C,
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`source temperature of 140°C, reactor pressure of 0.5 Torr,
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`and hydrogen carrier gas and ammonia reactant flows of,
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`respectively, 30 and 400 sccm. The values observed are sig—
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`nificantly higher than those that can be obtained using
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`collimated PVD TiN. Film resistivity ranged from 100 I10
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`cm for 1000 A films up to 150 an em for 100 A films.
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`Barrier properties—The density of the film is high, 1.1
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`times that of the collimated PVD TiN as tested by Texas
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`Instruments, and the films have a strong golden color.
`Films are stable in air and showed no evidence of oxida—
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`tion, even after prolonged exposure to air. Plug filling with
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`CVD tungsten and Al reflow are similar for vias lined with
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`CVD TiN or PVD TiN. Reactivity with Al—0.5% Cu during
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`a 450°C, 30 min forming gas sinter was similar to the reac-
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`tivity of PVD TiN. The sheet resistance increase upon sin—
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`tering is marginally lower for CVD TiN compared to PVD
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`TiN, as observed in Fig. 9. The various splits indicate that
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`the sheet resistance increase is due to interaction between
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`the Al—Cu and TiN rather than between Al—Cu and Si.
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`After a 550°C, 60 min sinter, splits 1, 2, and 4 show pitting
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`of the Si surface indicative of barrier failure. However the
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`density of pits is maximum for the case of no barrier, and
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`is minimum for the CVD TiN barrier.
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`Superiority of the CVD TiN barrier can also be gauged
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`from the contact—induced diode leakage for a diode with
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`250,000 contacts (Fig 10). The diode leakage characteris—
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`tics for a 230 A CVD TiN film are equivalent to those for a
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`500 A PVD TiN film. Increasing the CVD TiN thickness to
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`400 A decreases the leakage further. There is no apprecia—
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`ble difference1n diode leakage for block diodes with few
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`contacts except for the case of 30 A CVD TiN which
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`appears to be too thin, or possibly not even continuous, to
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`yield a reliable measurement (Fig. 11). Additionally, the
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`wider dispersion'in the diode leakage current for the 400 A
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`TiN film is attributed to a larger than typical thickness
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`Page 4 of 7
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`1006
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`J. Electrochem. 800., Vol. 144, No.3, March 1997 © The Electrochemical Society, Inc.
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`— 5
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`08 no
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`Fig. 7. Typical CS-SEM micrograph of TiN step coverage in 0.45 pm, 3:1 aspect ratio contacts.
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`variation across the specific wafer used in those measure-
`ments. Accordingly, the worst leakage value corresponded to
`a spot on the wafer where the TiN was thinner than 400 A.
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`Discussion and Conclusions
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`The results discussed above demonstrate that the low
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`temperature inorganic CVD route is a viable approach for
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`the deposition of TiN for applications as barrier layer and
`adhesion promoter in emerging subquarter micron device
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`technologies. The TiN films thus produced were gold col-
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`ored, stoichiometric, and exhibited metallic conductivity,
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`with resistivities in the range of 100 to 150 p!) cm, depend—
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`ing on film thickness. Microchemical analyses showed that
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`the films were free from oxygen or carbon contamination,
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`within the detection limits of XPS, with iodine concentra-
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`tions below 2 3/0. Such levels of iodine concentrations are
`not expected to cause reliability problems in device oper-
`ation. This expectation is based on the assumption that
`iodine is significantly heavier than chlorine and will thus
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`require higher activation energy for diffusion out of the
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`TiN matrix. The diode leakage data presented herein
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`seems to also support this assessment.
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`A systematic evaluation was also carried out of the bar—
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`rier characteristics of CVD TiN using PVD TiN as base line
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`material. The data showed that reactivity with Al—0.5 a/o
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`Cu alloys was equivalent in both cases, with the CVD TiN
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`film exhibiting a marginally better performance as com—
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`pared to its PVD counterpart. Similarly, the characteris—
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`tics of CVD tungsten and reflow plug fills were identical