Metallic Materials Deposition: Metal‐Organic PrecursorsUpdate based on the original article by Charles H. Winter, Wenjun Zheng and Hani M. El‐Kaderi,<i>Encyclopedia of Inorganic Chemistry</i>Second Edition, © 2005, John Wiley &amp; Sons, Ltd.

Winter, Charles H.; Knisley, Thomas J.; Kalutarage, Lakmal C.; Zavada, Mark A.; Klesko, Joseph P.; Perera, T. Hiran

doi:10.1002/9781119951438.eibc0128.pub2

Cited by 3 publications

(3 citation statements)

References 362 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To overcome these drawbacks, organometallic precursors have drawn considerable interest for metal-organic CVD (MOCVD). Typically, these complexes include nitrogen-bound moieties such as amido, imido, hydrazido, amidinate or guanidinate ligands, 13,14 and have been used in single-source or NH 3 /H 2 co-reacting conditions to deposit WN x . Unfortunately, many of these precursors still require relatively high deposition temperature (>350…”

mentioning

confidence: 99%

Low Temperature Deposition of WN_xC_yDiffusion Barriers Using WN(NEt₂)₃as a Single-Source Precursor

O’Donohue

McClain

Koley

et al. 2014

ECS J. Solid State Sci. Technol.

View full text Add to dashboard Cite

Deposition of high quality WN x C y barrier films at very low temperature using aerosol-assisted chemical vapor deposition (AACVD) is reported. The single-source tungsten nitrido complex, WN(NEt 2 ) 3 , was designed to reduce the temperature required for WN x C y film deposition in an effort to minimize thermal stresses on neighboring layers in device structures. Using either pyridine or heptane as a solvent, WN x C y films were successfully deposited at temperatures from 100 to 650 • C. Film growth in pyridine and heptane at low temperature (100-350 • C and 125-550 • C, respectively) showed weak temperature dependence consistent with mass-transfer limited growth. At higher temperature the growth rate decreased rapidly with apparent activation energy of 0.375 ± 0.057 eV. The effects of solvent choice on film properties including composition, crystallinity, density, and surface roughness are discussed. Films deposited at low temperature (<350 • C) were highly smooth, amorphous and with a stoichiometry approaching W 2 NC; characteristics desirable for diffusion barrier applications. In Cu diffusion barrier tests, Cu (∼ 100 nm)/WN x C y (∼ 5.5 nm)/Si stacks subjected to a 500 Thin interlayer materials are increasingly being used in electronic devices to modify interfacial characteristics, including the film work function, chemical, thermal and charge transport rates, surface tension, and adhesion. Due to their low resistivity, appropriate work function, and thermal stability, refractory metal nitrides have been proposed for a number of applications, ranging from wafer level hermetic sealing 1 to field effect transistor (FET) gate electrodes. 2 In particular, the tungsten-based materials WN x and WN x C y have been considered as an alternative for both diffusion barriers 3,4 and gate electrodes 5 due to their low resistivity, appropriate and tunable work function (4.39-5.01 eV 6 ), thermal and mechanical stability, good barrier performance, and processing simplicity. 7,8 Depositions of WN x and WN x C y typically use ammonia and WCl 6 , WF 6 or W(CO) 6 as co-reactants. 4,[9][10][11][12] Despite being volatile, simple, and cost-effective, these chemistries generally require high deposition temperature, can introduce impurities, and can yield corrosive byproducts. To overcome these drawbacks, organometallic precursors have drawn considerable interest for metal-organic CVD (MOCVD). Typically, these complexes include nitrogen-bound moieties such as amido, imido, hydrazido, amidinate or guanidinate ligands, 13,14 and have been used in single-source or NH 3 /H 2 co-reacting conditions to deposit WN x . Unfortunately, many of these precursors still require relatively high deposition temperature (>350• C) 15-22 that can compromise contact level structures 2,23 and neighboring dielectrics. 24In addition, the development of ultra-low temperature CVD WN x C y has potential application to flexible and organic devices. Therefore, there is interest in developing organometallic precursors for ultra-low deposition temperature. We h...

show abstract

mentioning

confidence: 99%

Low Temperature Deposition of WN_xC_yDiffusion Barriers Using WN(NEt₂)₃as a Single-Source Precursor

O’Donohue

McClain

Koley

et al. 2014

ECS J. Solid State Sci. Technol.

View full text Add to dashboard Cite

show abstract

“…We published a review article on metalorganic film growth precursors that were reported between 2005 and 2012. 4 This article appeared in "Encyclopedia of Inorganic and Bioinorganic Chemistry" in December 2012.…”

Section: Summary Of the Most Important Resultsmentioning

confidence: 99%

New Chemical Precursors for the Growth of Ferroelectric and Mid-Valent Metal Oxide Films

Winter¹

2014

Self Cite

View full text Add to dashboard Cite

This proposal seeks to prepare improved chemical vapor deposition (CVD) and atomic layer deposition (ALD) precursors to materials that contain Sr, Ba, and Ti and ALD precursors for the mid-valent oxides MO (M = Mo, W), M2O3 (M = Nb, Ta, Mo, W), and MO2 (M = Nb, Ta, Mo, W). These new precursors will be evaluated in film growth trials of MTiO3 (M = Sr, Ba) and mid-valent metal oxide films. Specific objectives include the synthesis and characterization of Sr, Ba, and Ti precursors containing bis(pyrazolyl)methane-derived ligands and Nb(

show abstract

“…The use of oxygen as a gas-reagent for the production of metallic iridium has proven itself well in the case of liquid cyclopentadienyl complexes. When using the [Ir(cod)Cp Me ] precursor, pure coatings (<1 at.% C and O) are formed already at 270 • C [29,66]; however, the growth rate is low. The application of the special system of "liquid delivery" of the precursor using a tetrahydrofuran (THF) solution allows attainment of exceptionally high growth rates (up to 70 nm/min at 350 • C) [67].…”

Section: Application Of Iridium Precursors In Mocvd Processesmentioning

confidence: 99%

Volatile Iridium and Platinum MOCVD Precursors: Chemistry, Thermal Properties, Materials and Prospects for Their Application in Medicine

et al. 2021

View full text Add to dashboard Cite

Interest in iridium and platinum has been steadily encouraged due to such unique properties as exceptional chemical inertia and corrosion resistance, high biological compatibility, and mechanical strength, which are the basis for their application in medical practice. Metal-organic chemical vapor deposition (MOCVD) is a promising method to fabricate Ir and Pt nanomaterials, multilayers, and heterostructures. Its advantages include precise control of the material composition and microstructure in deposition processes at relatively low temperatures onto non-planar substrates. The development of MOCVD processes is inextricably linked with the development of the chemistry of volatile precursors, viz., specially designed coordination and organometallic compounds. This review describes the synthesis methods of various iridium and platinum precursors, their thermal properties, and examples of the use of MOCVD, including formation of films for medical application and bimetallics. Although metal acetylacetonates are currently the most widely used precursors, the recently developed heteroligand Ir(I) and Pt(IV) complexes appear to be more promising in both synthetic and thermochemical aspects. Their main advantage is their ability to control thermal properties by modifying several types of ligands, making them tunable to deposit films onto different types of materials and to select a combination of compatible compounds for obtaining the bimetallic materials.

show abstract

Metallic Materials Deposition: Metal‐Organic PrecursorsUpdate based on the original article by Charles H. Winter, Wenjun Zheng and Hani M. El‐Kaderi,Encyclopedia of Inorganic ChemistrySecond Edition, © 2005, John Wiley & Sons, Ltd.

Cited by 3 publications

References 362 publications

Low Temperature Deposition of WN_xC_yDiffusion Barriers Using WN(NEt₂)₃as a Single-Source Precursor

Low Temperature Deposition of WN_xC_yDiffusion Barriers Using WN(NEt₂)₃as a Single-Source Precursor

New Chemical Precursors for the Growth of Ferroelectric and Mid-Valent Metal Oxide Films

Volatile Iridium and Platinum MOCVD Precursors: Chemistry, Thermal Properties, Materials and Prospects for Their Application in Medicine

Contact Info

Product

Resources

About

Metallic Materials Deposition: Metal‐Organic PrecursorsUpdate based on the original article by Charles H. Winter, Wenjun Zheng and Hani M. El‐Kaderi,Encyclopedia of Inorganic ChemistrySecond Edition, © 2005, John Wiley & Sons, Ltd.

Cited by 3 publications

References 362 publications

Low Temperature Deposition of WNxCyDiffusion Barriers Using WN(NEt2)3as a Single-Source Precursor

Low Temperature Deposition of WNxCyDiffusion Barriers Using WN(NEt2)3as a Single-Source Precursor

New Chemical Precursors for the Growth of Ferroelectric and Mid-Valent Metal Oxide Films

Volatile Iridium and Platinum MOCVD Precursors: Chemistry, Thermal Properties, Materials and Prospects for Their Application in Medicine

Contact Info

Product

Resources

About

Low Temperature Deposition of WN_xC_yDiffusion Barriers Using WN(NEt₂)₃as a Single-Source Precursor

Low Temperature Deposition of WN_xC_yDiffusion Barriers Using WN(NEt₂)₃as a Single-Source Precursor