Work function engineering using lanthanum oxide interfacial layers

Alshareef, Husam N.; Quevedo‐Lopez, Manuel; Wen, Huang-Chun; Harris, R.; Kirsch, P. D.; Majhi, P.; Lee, B. H.; Jammy, R.; Lichtenwalner, Daniel J.; Jur, Jesse S.; Kingon, Angus I.

doi:10.1063/1.2396918

Cited by 123 publications

(70 citation statements)

References 6 publications

(1 reference statement)

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“…Overall, our results summarized in table VI are in a qualitative agreement with the recent experiments [6][7][8][9][10][11][12][13][14][15][16][17], and we need to identify the microscopic mechanism of the doping effect.…”

Section: Band Alignment and Charge Transfersupporting

confidence: 78%

“…In particular, group III metals have been suggested to modify the interfacial dipole. For example, La has been used for the n-type silicon field effect transistors (FETs) [6,[8][9][10][11] and Al for the p-type FETs [7,[12][13][14][15][16][17]. The doping can be achieved, for instance, via the ion diffusion from a thin metal oxide capping layer deposited on top of the HfO 2 -based dielectric.…”

Section: Introductionmentioning

confidence: 99%

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Band alignment at the SiO2/HfO2interface: Group IIIA versus group IIIB metal dopants

Luo

Bersuker²,

Demkov

2011

Phys. Rev. B

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Abstract:Using density functional theory we examine the effect of Al and La incorporation on the electronic properties of the interface in the SiO 2 /HfO 2 high-k gate stacks recently introduced into the advanced modern field effect transistors. We show that La and Al doping have opposite effects on the band alignment at the SiO 2 /HfO 2 interface: while the Al ions, which substitute preferentially for Si in the SiO 2 layer, promote higher effective work function (EWF) values, the substitution of La for Hf decreases EWF. The analysis of the electronic structure of the doped interface suggests a simple relation between the electronegativity of the doping metal, screening properties of the interfacial layer and the band offset, which allows predicting qualitatively the effect of the high-k gate stack doping with a variety of metals on its EWF.

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Section: Band Alignment and Charge Transfersupporting

confidence: 78%

Section: Introductionmentioning

confidence: 99%

Band alignment at the SiO2/HfO2interface: Group IIIA versus group IIIB metal dopants

Luo

Bersuker²,

Demkov

2011

Phys. Rev. B

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“…Recent experiments into the possibility of shifting the threshold voltage to more desirable values incorporating rare earth elements (e.g., lanthanum) in the gate stack have shown encouraging results. [5][6][7][8] This can be accomplished, for example, by mixing the element in the bulk dielectric, such as in the case of HfLaO x materials, [5][6][7] or by adding a cap layer on top of the HfSiO x dielectric. [8] In addition, reports have been published describing scandate materials where a rare earth element is combined with scandium instead of hafnium.…”

Section: Introductionmentioning

confidence: 99%

“…[5][6][7][8] This can be accomplished, for example, by mixing the element in the bulk dielectric, such as in the case of HfLaO x materials, [5][6][7] or by adding a cap layer on top of the HfSiO x dielectric. [8] In addition, reports have been published describing scandate materials where a rare earth element is combined with scandium instead of hafnium. [9][10][11][12][13][14] Besides the benefits for threshold voltage control originating from the incorporation of the rare earth element in the gate stack, these materials are reported to have a high dielectric constant (j ∼ 20), [10,15] and a band gap comparable to HfO 2 [9,16] in combination with a high thermal stability, which makes them a very interesting class of materials.…”

Section: Introductionmentioning

confidence: 99%

Growth of Dysprosium‐, Scandium‐, and Hafnium‐based Third Generation High‐κ Dielectrics by Atomic Vapor Deposition

Adelmann

Lehnen

Elshocht

et al. 2007

Chemical Vapor Deposition

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“…34 illustrates the effect of a band offset change between the high-k and interfacial oxide induced by incorporating metal ions into the interfacial layer. A metallic element can be incorporated in the IL by diffusion during thermal processing, specifically www.intechopen.com In nFETs, La is found to be the most effective dopant based on its overall effect on V t , EOT scaling, mobility, and reliability [50,53,54]. An Al 2 O 3 cap has been widely used for pFETs, but it increased the EOT [52] (since it has a relatively lower dielectric constant value) as well as raises reliability concerns due to Al diffusing into the interfacial oxide layer [52].…”

Section: Dielectric Capping For Work Function Tuningmentioning

confidence: 99%

The Progress and Challenges of Applying High-k/Metal-Gated Devices to Advanced CMOS Technologies

Tseng¹

2010

Solid State Circuits Technologies

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Introduction Motivation for implementing high dielectric constant gate dielectric for advanced CMOS scalingSemiconductor devices need to have good performance, with a low cost and low power dissipation. For decades, research and development of semiconductor processing technology and device integration have focused on enhancing performance and reducing costs using SiO 2 as the gate dielectric and doped polysilicon as the gate electrode. The most effective way to enhance performance and reduce costs is to scale the device gate length and gate oxide. Scaling the gate length results in fabricating more devices per wafer (i.e., increase the device density) and thus reduce the cost per chip, while scaling the gate oxide enhances the drive current and reduces the short channel effects due to gate length scaling. However, as the gate oxide becomes thinner, the power to operate transistors increases because of greater gate oxide leakage current. To resolve this high gate oxide leakage problem, the mechanism of the carriers tunneling through the gate dielectric must be better understood. In an ideal metal-insulator-semiconductor (MIS) device, the current conduction in the insulator should be zero. In a real MIS device, however, current can flow through the insulating film by various conduction mechanisms. The two primary conduction mechanisms for electron tunneling through high quality gate dielectric are discussed below. Direct tunnelingIn a metal-insulator-semiconductor (MIS) stack, when the oxide voltage (V ox ) is smaller than the metal-insulator barrier height, the electron tunnels directly from the metal electrode into other semiconductor electrode through the insulator. This is known as the direct tunneling process. The equation for direct tunneling current density (current normalized by device area) is proportional to

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Work function engineering using lanthanum oxide interfacial layers

Cited by 123 publications

References 6 publications

Band alignment at the SiO2/HfO2interface: Group IIIA versus group IIIB metal dopants

Band alignment at the SiO2/HfO2interface: Group IIIA versus group IIIB metal dopants

Growth of Dysprosium‐, Scandium‐, and Hafnium‐based Third Generation High‐κ Dielectrics by Atomic Vapor Deposition

The Progress and Challenges of Applying High-k/Metal-Gated Devices to Advanced CMOS Technologies

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