Anderson D Smith
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Explore the profile of Anderson D Smith including associated specialties, affiliations and a list of published articles.
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Articles
19
Citations
917
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Recent Articles
1.
Moreno-Garcia D, Fan X, Smith A, Lemme M, Messina V, Martin-Olmos C, et al.
Small
. 2022 May;
18(28):e2201816.
PMID: 35638191
Measuring vibrations is essential to ensuring building structural safety and machine stability. Predictive maintenance is a central internet of things (IoT) application within the new industrial revolution, where sustainability and...
2.
Fan X, Smith A, Forsberg F, Wagner S, Schroder S, Afyouni Akbari S, et al.
Microsyst Nanoeng
. 2021 Sep;
6:17.
PMID: 34567632
Graphene's unparalleled strength, chemical stability, ultimate surface-to-volume ratio and excellent electronic properties make it an ideal candidate as a material for membranes in micro- and nanoelectromechanical systems (MEMS and NEMS)....
3.
Fan X, Forsberg F, Smith A, Schroder S, Wagner S, Ostling M, et al.
Nano Lett
. 2019 Sep;
19(10):6788-6799.
PMID: 31478660
Graphene is an atomically thin material that features unique electrical and mechanical properties, which makes it an extremely promising material for future nanoelectromechanical systems (NEMS). Recently, basic NEMS accelerometer functionality...
4.
Vyas A, Staaf H, Rusu C, Ebefors T, Liljeholm J, Smith A, et al.
Micromachines (Basel)
. 2018 Nov;
9(5).
PMID: 30424185
This paper presents a demonstration of the feasibility of fabricating micro-cantilever harvesters with extended stress distribution and enhanced bandwidth by exploiting an M-shaped two-degrees-of-freedom design. The measured mechanical response of...
5.
Quellmalz A, Smith A, Elgammal K, Fan X, Delin A, Ostling M, et al.
ACS Appl Mater Interfaces
. 2018 Nov;
10(48):41738-41746.
PMID: 30387599
The electrical contact resistance at metal-graphene interfaces can significantly degrade the properties of graphene devices and is currently hindering the full exploitation of graphene's potential. Therefore, the influence of environmental...
6.
Sollami Delekta S, Smith A, Li J, Ostling M
Nanoscale
. 2017 May;
9(21):6998-7005.
PMID: 28534907
Modern energy storage devices for portable and wearable technologies must fulfill a number of requirements, such as small size, flexibility, thinness, reliability, transparency, manufacturing simplicity and performance, in order to...
7.
Wagner S, Dieing T, Centeno A, Zurutuza A, Smith A, Ostling M, et al.
Nano Lett
. 2017 Feb;
17(3):1504-1511.
PMID: 28140595
Graphene has extraordinary mechanical and electronic properties, making it a promising material for membrane-based nanoelectromechanical systems (NEMS). Here, chemical-vapor-deposited graphene is transferred onto target substrates to suspend it over cavities...
8.
Smith A, Niklaus F, Paussa A, Schroder S, Fischer A, Sterner M, et al.
ACS Nano
. 2016 Nov;
10(11):9879-9886.
PMID: 27797484
Graphene membranes act as highly sensitive transducers in nanoelectromechanical devices due to their ultimate thinness. Previously, the piezoresistive effect has been experimentally verified in graphene using uniaxial strain in graphene....
9.
Smith A, Elgammal K, Niklaus F, Delin A, Fischer A, Vaziri S, et al.
Nanoscale
. 2015 Nov;
7(45):19099-109.
PMID: 26523705
We demonstrate humidity sensing using a change of the electrical resistance of single-layer chemical vapor deposited (CVD) graphene that is placed on top of a SiO2 layer on a Si...
10.
Vaziri S, Lupina G, Henkel C, Smith A, Ostling M, Dabrowski J, et al.
Nano Lett
. 2013 Mar;
13(4):1435-9.
PMID: 23488893
We experimentally demonstrate DC functionality of graphene-based hot electron transistors, which we call graphene base transistors (GBT). The fabrication scheme is potentially compatible with silicon technology and can be carried...