Photoelectron emission microscopy of ultrathin oxide covered devices

Ballarotto, V. W.; Breban, M.; Siegrist, K.; Phaneuf, R. J.; Williams, Ellen D.

doi:10.1116/1.1525007

Cited by 36 publications

(31 citation statements)

References 21 publications

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“…Ga implantation into an n-type substrate would initially compensate and then transform the implanted region into p-type. p-type regions appear brighter in PEEM images [8,9]. Here a sharp stripe pattern is observed for implantation at RT (Fig.…”

Section: Resultsmentioning

confidence: 72%

“…The Ga concentration profile extends to the surface as the peak of the concentration profile is at a depth smaller than 3DR p . In any case, PEEM images can also be obtained from buried layers [9].…”

Section: Resultsmentioning

confidence: 99%

“…In the PEEM image p-doped Si regions appear brighter compared to n-doped regions [8]. Buried p-doped regions fabricated by broad beam implantation of boron (190 keV) into n-type silicon substrates also have shown brighter contrast in PEEM images from the B-implanted regions [9].…”

Section: Introductionmentioning

confidence: 97%

See 2 more Smart Citations

Lateral straggling and its influence on lateral diffusion in implantation with a focused ion beam

Batabyal

Mahato

Roy

et al. 2011

Nuclear Instruments and Methods in Physics Research Section B:

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Section: Resultsmentioning

confidence: 72%

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Lateral straggling and its influence on lateral diffusion in implantation with a focused ion beam

Batabyal

Mahato

Roy

et al. 2011

Nuclear Instruments and Methods in Physics Research Section B:

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“…Development of such a PES-through-membrane approach is inspired by the successful photoelectron spectroscopy and microscopy of buried interfaces for a wide range of excitation energies spanning ultraviolet (UV) [23], soft X-rays [24] to hard X-rays [25,26]. The membrane can be considered as an overlayer with a thickness comparable to the IMFP, so that the signal from the immersed sample is directly related to the classical signal attenuation by overlayer films in surface science [27].…”

Section: Appes Conceptsmentioning

confidence: 99%

Recent Approaches for Bridging the Pressure Gap in Photoelectron Microspectroscopy

et al. 2016

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Ambient-pressure photoelectron spectroscopy (APPES) and microscopy are at the frontier of modern chemical analysis at liquid-gas, solid-liquid and solid-gas interfaces, bridging science and engineering of functional materials. Complementing the current state-of-the art of the instruments, we survey in this short review several alternative APPES approaches, developed recently in the scanning photoelectron microscope (SPEM) at the Elettra laboratory. In particular, we report on experimental setups for dynamic near-ambient pressure environment, using pulsed-gas injection in the vicinity of samples or reaction cells with very small apertures, allowing for experiments without introducing additional differential pumping stages. The major part of the review is dedicated to the construction and performance of novel environmental cells using ultrathin electron-transparent but molecularly impermeable membranes to isolate the gas or liquid ambient from the electron detector operating in ultra-high vacuum (UHV). We demonstrate that two dimensional materials, such as graphene and derivatives, are mechanically robust to withstand atmospheric - UHV pressure differences and are sufficiently transparent for the photoelectrons emitted from samples immersed in the liquid or gaseous media. There are many unique opportunities for APPES using X-rays over a wide energy range. We show representative results that illustrate the potential of these ‘ambient-pressure’ approaches. Combined with the ca 100 nm lateral resolution of SPEM, they can overcome the pressure gap challenges and address the evolution of chemical composition and electronic structure at surface and interfaces under realistic operation conditions with unprecedented lateral and spectral resolution.

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“…1 eV) photoelectrons imaged in PEEM is 1-2 nm, resulting in excellent surface sensitivity. [35,36] PEEM intensities are sensitive to changes in the work function during phase transformations, as well as to changes in chemical composition, crystal orientation, and surface dipole. [37][38][39][40] In recent work, we described in situ PEEM observations of the phase transformation in bulk CuZnAl SMA.…”

Section: Introductionmentioning

confidence: 99%

Study of Martensitic Phase Transformation in a NiTiCu Thin‐Film Shape‐Memory Alloy Using Photoelectron Emission Microscopy

Cai

Langford

et al. 2006

Adv Funct Materials

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Thermally induced martensitic phase transformation in a polycrystalline NiTiCu thin‐film shape‐memory alloy is probed using photoelectron emission microscopy (PEEM). In situ PEEM images reveal distinct changes in microstructure and photoemission intensity at the phase‐transition temperatures. In particular, images of the low‐temperature, martensite phase are brighter than that of the high‐temperature, austenite phase, because of the lower work function of the martensite. UV photoelectron spectroscopy shows that the effective work‐function changes by about 0.16 eV during thermal cycling. In situ PEEM images also show that the network of trenches observed on the room‐temperature film disappears suddenly during heating and reappears suddenly during subsequent cooling. These trenches are also characterized using atomic force microscopy at selected temperatures. The implications of these observations with respect to the spatial distribution of phases during thermal cycling in this thin‐film shape‐memory alloy are discussed.

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Photoelectron emission microscopy of ultrathin oxide covered devices

Cited by 36 publications

References 21 publications

Lateral straggling and its influence on lateral diffusion in implantation with a focused ion beam

Lateral straggling and its influence on lateral diffusion in implantation with a focused ion beam

Recent Approaches for Bridging the Pressure Gap in Photoelectron Microspectroscopy

Study of Martensitic Phase Transformation in a NiTiCu Thin‐Film Shape‐Memory Alloy Using Photoelectron Emission Microscopy

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