How will physics be involved in silicon microelectronics

Kamarinos, G.; Felix, P.

doi:10.1088/0022-3727/29/3/001

Cited by 22 publications

(7 citation statements)

References 127 publications

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“…This is especially true for variance and defect interactions that become magnified when investigating the electrical output characteristics as device geometry shrinks. 7 Today, we are truly in a global market where many of our day-to-day applications and interactions require interfaca͒ Author to whom correspondence should be addressed; electronic mail: schroder@asu.edu ing with integrated circuits and the millions of transistors contained in these building blocks. To the average consumer, the dynamics of these ICs are transparent while the expectation for increasing functionality with unquestioned accuracy and quality drive the industry to new heights.…”

Section: Motivationmentioning

confidence: 99%

Negative bias temperature instability: Road to cross in deep submicron silicon semiconductor manufacturing

Schroder

Babcock

2003

Journal of Applied Physics

940

396

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Articles you may be interested inInterface traps responsible for negative bias temperature instability in a nitrided submicron metal-oxidesemiconductor field effect transistor Appl. Phys. Lett. 98, 103513 (2011); 10.1063/1.3559223 Bias temperature instability in metal-oxide-semiconductor field-effect transistors with atomic-layer-deposited Sinitride/ Si O 2 stack gate dielectrics J. Appl. Phys. 103, 084512 (2008); 10.1063/1.2907768Using the Hall effect to measure interface trap densities in silicon carbide and silicon metal-oxide-semiconductor devices Appl.A study on the capacitance-voltage characteristics of metal-Ta 2 O 5 -silicon capacitors for very large scale integration metal-oxide-semiconductor gate oxide applications Identification of isolation-edge related random telegraph signals in submicron silicon metal-oxide-semiconductor field-effect transistors

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Section: Motivationmentioning

confidence: 99%

Negative bias temperature instability: Road to cross in deep submicron silicon semiconductor manufacturing

Schroder

Babcock

2003

Journal of Applied Physics

940

396

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“…For example, ultrashallow doping with depth less than scores in nm is required for sub-0.1-m metal-oxide-semiconductor field-effect transistors ͑MOSFET's͒. 1 In making such shallow junctions with a high concentration of impurities, the depth of the defects from the surface should be much shallower to suppress transient enhanced diffusion ͑TED͒, 2 which is caused by the excess point defects in the region of implant damage. The above requirement extends the ion implantation technique towards lower energies of keV order.…”

Section: Introductionmentioning

confidence: 99%

Mechanisms of cluster implantation in silicon: A molecular-dynamics study

1998

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Employing molecular dynamics, we have simulated collisions of various sizes of 5.7-keV silicon clusters with a silicon surface. At this energy, the simulation provides an atomistic description of the evolution of the multiple scattering process of atoms in the cluster as well as the substrate where atoms interact with each other by covalent forces. The change from the collision cascade that is characteristic in the single-ion case to the simultaneous collision process that leads to the collective motion of particles, such as macroscopic vibration of the surface and shock waves, is found by increasing the number of the atoms in the cluster. With an increase in cluster size, the impurity profile and the damaged region for the cluster ion implantation is also found to be shallower. In contrast to single-ion implantation, cluster implantation may not induce defects in deep regions, making it suitable for device design. The channeling effect is found to be mainly suppressed by the lowfrequency macroscopic vibrations of the surface rather than by the amorphization of the surface caused by the impact.

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“…In the heart of an electronic system, the processing unit is the main element, comprising semiconductor devices belonging to one or several integrated circuits (IC's). Research work in physics [1] is needed for technological advance towards IC's with increased speed, complexity and density of integration (ultra large scale integration, ULSI).…”

Section: Introductionmentioning

confidence: 99%

High Resolution X-Ray Diffraction to Characterize Semiconductor Materials

Hayashi

2000

Physicae

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X-ray diffraction gives information on the composition and lattice strain of III-V and II-VI ternary and quaternary heteroepitaxial semiconductor layers used in the fabrication of optoeletronic devices. In this article we give a brief introduction to the materials used in technology of III-V optoeletronics, and how X-ray diffraction can provide vital information to researchers involved in the growth and development of these semiconductors materials.

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How will physics be involved in silicon microelectronics

Cited by 22 publications

References 127 publications

Negative bias temperature instability: Road to cross in deep submicron silicon semiconductor manufacturing

Negative bias temperature instability: Road to cross in deep submicron silicon semiconductor manufacturing

Mechanisms of cluster implantation in silicon: A molecular-dynamics study

High Resolution X-Ray Diffraction to Characterize Semiconductor Materials

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