Subnanometer Characterization of Nanoelectronic Devices

Eyben, Pierre; Mody, Jay; Nazir, Aftab; Schulze, Andreas; Clarysse, Trudo; Hantschel, Thomas; Vandervorst, Wilfried

doi:10.1201/b15523-46

Cited by 8 publications

(7 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…On the other hand, C-AFM as well as SSRM have reported ≈1 nm electrical resolution as indication of a higher confinement of the electrical processes within the tip-sample contact area. A notorious case illustrating the difference between physical and electrical contact area relates to SSRM, where the confined pressure transformation resulting from the high force applied to the tip, leads to an electrical contact area 5-10 x smaller than the geometrical one [32]. Figure 3.9a shows the case of SSRM where a thin 0.5 nm oxide is detectable.…”

Section: Electrical Lateral Resolutionmentioning

confidence: 98%

Nanoscaled Electrical Characterization

Celano

2016

Metrology and Physical Mechanisms in New Generation Ionic Devices

View full text Add to dashboard Cite

Section: Electrical Lateral Resolutionmentioning

confidence: 98%

Nanoscaled Electrical Characterization

Celano

2016

Metrology and Physical Mechanisms in New Generation Ionic Devices

View full text Add to dashboard Cite

“…This structure is composed of seven epitaxially grown Si layers with an increasing boron concentration forming a dopant staircase (figure 2(a)). A thin (0.5 nm) Si0 2 layer sandwiched in between highly boron-doped Si and poly-Si layers is deposited on top in order to evaluate the spatial resolution of the technique [6] (figure 2(c)). A silicide layer (covered by a protective oxide layer deposited at low temperature) is formed on top of the poly-Si layer in order to determine the sensitivity decrease and dynamic range limit of the technique in lowly resistive materials (figure 2(b)).…”

Section: Concentration Sensitivity and Spatial Resolutionmentioning

confidence: 99%

“…In order to be relevant, methods used for this purpose should provide sub-nanometer resolution and high sensitivity over many orders of magnitude and be quantitative. For 20 years, various metrology solutions have been proposed in order to tackle this problem, such as electron holography [1], scanning capacitance microscopy [2], scanning tunneling microscopy [3], and scanning spreading-resistance microscopy (SSRM) [4][5][6]. Among these, SSRM is the only method combining high spatial resolution, sensitivity, and the possibility to perform quantification.…”

Section: Introductionmentioning

confidence: 99%

“…Various studies have demonstrated that one can provide 2D carrier concentration maps with a spatial resolution down to 0.6 nm and a dopant gradient resolution of 1-2 nm dec −1 , using the SSRM technique in a controlled environment (less than 0.1 ppm of H 2 O and O 2 ) with full diamond tips [6] with a sensitivity ranging over five orders of magnitude and with good quantification accuracy. The possibility to extend the technique towards 3D carrier profiling has also been demonstrated [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Fast Fourier transform scanning spreading resistance microscopy: a novel technique to overcome the limitations of classical conductive AFM techniques

Eyben¹,

Bisiaux²,

Schulze³

et al. 2015

Nanotechnology

View full text Add to dashboard Cite

A new atomic force microscopy (AFM)-based technique named fast Fourier transform scanning spreading-resistance microscopy (FFT-SSRM) has been developed. FFT-SSRM offers the ability to isolate the local spreading resistance (Sr) from the parasitic series resistance (probe, bulk, and back contact). The parasitic series resistance limits the use of classical SSRM in confined volumes and on very highly doped materials, two increasingly important situations in nanoelectronic components. This is realized via a force modulation at controlled frequency (affecting the SR component) and the extraction of the resistance amplitude at the modulation frequency, performing an FFT-based lock-in deconvolution. A systematic evaluation of the FFT-SSRM performances (i.e., resolution, dynamic range, sensitivity, and repeatability) is presented. The impact of various parameters (i.e., modulation frequency and amplitude or cutoff frequency of the current amplifier) on the performances of FFT-SSRM has been evaluated. We demonstrate the possibility to overcome sensitivity losses due to tip saturation in highly doped material and the utility of the technique in two different structures, presenting isolated and confined volumes.

show abstract

“…SSRM is based on atomic force microscopy (AFM) and is the leading method for quantitative 2D‐carrier profiling, featuring ∼1 nm spatial resolution, a response function covering a wide dynamic range of carrier concentration and the capability for site‐specific analysis . SSRM has been demonstrated as a unique concept for the electrical characterization of semiconductor devices with successful applications toward silicon‐based metal‐oxide semiconductor field‐effect transistors (MOSFETs) , FinFETs , nanowire‐based transistors , and Ge‐based p‐MOSFET devices .…”

Section: Introductionmentioning

confidence: 99%

Scanning spreading resistance microscopy for electrical characterization of diamond interfacial layers

Hantschel

Tsigkourakos

et al. 2015

Physica Status Solidi (a)

View full text Add to dashboard Cite

This paper presents a methodology to directly investigate on the nanometer scale electrical properties of the nucleation layer of grown diamond films, which are important when the film is used as an electrode with the current flow across the nucleation layer. The diamond films are grown on Si substrates. In this methodology, the Si substrate is locally removed by wet etching and electrical measurements are then carried out by scanning spreading resistance microscopy (SSRM). SSRM is based on atomic force microscopy (AFM) and measures the local spreading resistance underneath a conducting tip which is scanned in contact mode across the sample surface. Our work shows how SSRM can be applied on the diamond interfacial layer and what insights can be gained from these measurements. We show how undoped and boron-doped seeds are incorporated at the interface and how the seed solution concentration impacts the interfacial seed density and the resulting interfacial electrical resistance. This paper discusses in more detail the sample preparation and measurement procedures.

show abstract

Subnanometer Characterization of Nanoelectronic Devices

Cited by 8 publications

References 16 publications

Nanoscaled Electrical Characterization

Nanoscaled Electrical Characterization

Fast Fourier transform scanning spreading resistance microscopy: a novel technique to overcome the limitations of classical conductive AFM techniques

Scanning spreading resistance microscopy for electrical characterization of diamond interfacial layers

Contact Info

Product

Resources

About