Band alignment of high-к/SiO2/Si stacks incorporating Zr and Al oxides prepared by atomic layer deposition

2010 International Students and Young Scientists Workshop "Photonics and Microsystems" Pub Date : 2010-06-25 DOI:10.1109/STYSW.2010.5714175

Lukasz Starzyk, M. Tallarida, D. Schmeißer

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Abstract

Band alignment of high-к/SiO2/Si stacks incorporating Zr and Al oxides for advanced MOS technology is explored. Because of requirements concerning continued scaling of MOSFET transistors, gate oxides were grown in situ on Si(001) substrate by means of atomic layer deposition (ALD) process using respectively TDMAZr and TMA as metal precursors and ultra pure H2O as oxygen source. The thicknesses of high-к films were around 1–2 nm. We applied synchrotron radiation based X-ray photoelectron spectroscopy (SR XPS) at the undulator beam line U49/2-PGM2 (BESSY, Berlin) to characterize our samples, which allows step by step in situ investigations. In this way thanks to our (in situ)2 approach we are able to improve functional properties of our thin films by controlling sample preparation process. Si 2p, O 1s, Zr 3d, Al 2p core levels and valence band (VB) spectra were recorded and analyzed. As a result, we determined chemical composition, growth rate and electronic band structure. We found the formation of interface dipole as well as the existence of space charge regime as deduced from continuous shift of the VB maximum with increasing layer thickness.

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原子层沉积制备含Zr和Al氧化物的高氧/SiO2/Si堆叠的能带排列

探讨了采用Zr和Al氧化物的高氧/SiO2/Si堆叠用于先进MOS技术的波段对准。由于MOSFET晶体管的持续尺度要求，分别以TDMAZr和TMA为金属前驱体，以超纯H2O为氧源，采用原子层沉积(ALD)工艺在Si(001)衬底上原位生长栅极氧化物。高渗膜的厚度约为1 ~ 2 nm。我们应用同步辐射的x射线光电子能谱(SR XPS)在波动束线U49/2-PGM2 (BESSY，柏林)来表征我们的样品，这允许一步一步的原位研究。通过这种方式，由于我们的(原位)2方法，我们能够通过控制样品制备过程来改善薄膜的功能特性。记录并分析了Si 2p、o1s、Zr 3d、Al 2p的核能级和价带(VB)谱。因此，我们确定了化学成分、生长速率和电子能带结构。我们发现界面偶极子的形成和空间电荷的存在，由VB最大值随层厚的增加而连续移动推导出来。

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2010 International Students and Young Scientists Workshop "Photonics and Microsystems"

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