Modeling of Nanoparticular Magnetoresistive Systems and the Impact on Molecular Recognition
Teich L, Kappe D, Rempel T, Meyer J, Schröder C, Hütten A (2015)
Sensors 15(4): 9251-9264.
Zeitschriftenaufsatz
| Veröffentlicht | Englisch
Download
Es wurden keine Dateien hochgeladen. Nur Publikationsnachweis!
Autor*in
Einrichtung
Abstract / Bemerkung
The formation of magnetic bead or nanoparticle superstructures due to magnetic dipole dipole interactions can be used as configurable matter in order to realize low-cost magnetoresistive sensors with very high GMR-effect amplitudes. Experimentally, this can be realized by immersing magnetic beads or nanoparticles in conductive liquid gels and rearranging them by applying suitable external magnetic fields. After gelatinization of the gel matrix the bead or nanoparticle positions are fixed and the resulting system can be used as a magnetoresistive sensor. In order to optimize such sensor structures we have developed a simulation tool chain that allows us not only to study the structuring process in the liquid state but also to rigorously calculate the magnetoresistive characteristic curves for arbitrary nanoparticle arrangements. As an application, we discuss the role of magnetoresistive sensors in finding answers to molecular recognition.
Erscheinungsjahr
2015
Zeitschriftentitel
Sensors
Band
15
Ausgabe
4
Seite(n)
9251-9264
Urheberrecht / Lizenzen
ISSN
1424-8220
eISSN
1424-8220
Page URI
https://pub.uni-bielefeld.de/record/2758487
Zitieren
Teich L, Kappe D, Rempel T, Meyer J, Schröder C, Hütten A. Modeling of Nanoparticular Magnetoresistive Systems and the Impact on Molecular Recognition. Sensors. 2015;15(4):9251-9264.
Teich, L., Kappe, D., Rempel, T., Meyer, J., Schröder, C., & Hütten, A. (2015). Modeling of Nanoparticular Magnetoresistive Systems and the Impact on Molecular Recognition. Sensors, 15(4), 9251-9264. doi:10.3390/s150409251
Teich, Lisa, Kappe, Daniel, Rempel, Thomas, Meyer, Judith, Schröder, Christian, and Hütten, Andreas. 2015. “Modeling of Nanoparticular Magnetoresistive Systems and the Impact on Molecular Recognition”. Sensors 15 (4): 9251-9264.
Teich, L., Kappe, D., Rempel, T., Meyer, J., Schröder, C., and Hütten, A. (2015). Modeling of Nanoparticular Magnetoresistive Systems and the Impact on Molecular Recognition. Sensors 15, 9251-9264.
Teich, L., et al., 2015. Modeling of Nanoparticular Magnetoresistive Systems and the Impact on Molecular Recognition. Sensors, 15(4), p 9251-9264.
L. Teich, et al., “Modeling of Nanoparticular Magnetoresistive Systems and the Impact on Molecular Recognition”, Sensors, vol. 15, 2015, pp. 9251-9264.
Teich, L., Kappe, D., Rempel, T., Meyer, J., Schröder, C., Hütten, A.: Modeling of Nanoparticular Magnetoresistive Systems and the Impact on Molecular Recognition. Sensors. 15, 9251-9264 (2015).
Teich, Lisa, Kappe, Daniel, Rempel, Thomas, Meyer, Judith, Schröder, Christian, and Hütten, Andreas. “Modeling of Nanoparticular Magnetoresistive Systems and the Impact on Molecular Recognition”. Sensors 15.4 (2015): 9251-9264.
Daten bereitgestellt von European Bioinformatics Institute (EBI)
3 Zitationen in Europe PMC
Daten bereitgestellt von Europe PubMed Central.
3D Magnetic Field Reconstruction Methodology Based on a Scanning Magnetoresistive Probe.
Richheimer F, Costa M, Leitao DC, Gaspar J, Cardoso S, Freitas PP., Sensors (Basel) 18(7), 2018
PMID: 29954089
Richheimer F, Costa M, Leitao DC, Gaspar J, Cardoso S, Freitas PP., Sensors (Basel) 18(7), 2018
PMID: 29954089
Giant Magnetoresistance: Basic Concepts, Microstructure, Magnetic Interactions and Applications.
Ennen I, Kappe D, Rempel T, Glenske C, Hütten A., Sensors (Basel) 16(6), 2016
PMID: 27322277
Ennen I, Kappe D, Rempel T, Glenske C, Hütten A., Sensors (Basel) 16(6), 2016
PMID: 27322277
Hybrid Molecular and Spin Dynamics Simulations for Ensembles of Magnetic Nanoparticles for Magnetoresistive Systems.
Teich L, Schröder C., Sensors (Basel) 15(11), 2015
PMID: 26580623
Teich L, Schröder C., Sensors (Basel) 15(11), 2015
PMID: 26580623
20 References
Daten bereitgestellt von Europe PubMed Central.
Enhanced magnetoresistance in layered magnetic structures with antiferromagnetic interlayer exchange.
Binasch G, Grunberg P, Saurenbach F, Zinn W., Phys. Rev., B Condens. Matter 39(7), 1989
PMID: 9948867
Binasch G, Grunberg P, Saurenbach F, Zinn W., Phys. Rev., B Condens. Matter 39(7), 1989
PMID: 9948867
Giant magnetoresistance of (001)Fe/(001)Cr magnetic superlattices.
Baibich MN, Broto JM, Fert A, Nguyen Van Dau F , Petroff F, Etienne P, Creuzet G, Friederich A, Chazelas J., Phys. Rev. Lett. 61(21), 1988
PMID: 10039127
Baibich MN, Broto JM, Fert A, Nguyen Van Dau F , Petroff F, Etienne P, Creuzet G, Friederich A, Chazelas J., Phys. Rev. Lett. 61(21), 1988
PMID: 10039127
Giant magnetoresistance in nonmultilayer magnetic systems.
Xiao JQ, Jiang JS, Chien CL., Phys. Rev. Lett. 68(25), 1992
PMID: 10045787
Xiao JQ, Jiang JS, Chien CL., Phys. Rev. Lett. 68(25), 1992
PMID: 10045787
Giant magnetoresistance in heterogeneous Cu-Co alloys.
Berkowitz AE, Mitchell JR, Carey MJ, Young AP, Zhang S, Spada FE, Parker FT, Hutten A, Thomas G., Phys. Rev. Lett. 68(25), 1992
PMID: 10045786
Berkowitz AE, Mitchell JR, Carey MJ, Young AP, Zhang S, Spada FE, Parker FT, Hutten A, Thomas G., Phys. Rev. Lett. 68(25), 1992
PMID: 10045786
Giant magnetoresistance effects in gel-like matrices
Meyer J., Rempel T., Schäfers M., Wittbracht F., Müller C., Patel A.V., Hütten A.., 2013
Meyer J., Rempel T., Schäfers M., Wittbracht F., Müller C., Patel A.V., Hütten A.., 2013
Efficient Calculation of Low Energy Configurations of Nanoparticle Ensembles for Magnetoresistive Sensor Devices by Means of Stochastic Spin Dynamics and Monte Carlo Methods
Teich L., Meyer J., Müller C., Patel A., Hütten A., Schröder C.., 2015
Teich L., Meyer J., Müller C., Patel A., Hütten A., Schröder C.., 2015
Simulating Computationally Complex Magnetic Molecules
Engelhardt L., Schröder C.., 2011
Engelhardt L., Schröder C.., 2011
General purpose molecular dynamics simulations fully implemented on graphics processing units
Anderson J.A., Lorenz C.D., Travesset A.., 2008
Anderson J.A., Lorenz C.D., Travesset A.., 2008
Role of repulsive forces in determining the equilibrium structure of simple liquids
Weeks J.D., Chandler D., Andersen H.C.., 1971
Weeks J.D., Chandler D., Andersen H.C.., 1971
Zur Quantentheorie der Molekeln
Born M., Oppenheimer R.., 1927
Born M., Oppenheimer R.., 1927
Review and outlook: from single nanoparticles to self-assembled monolayers and granular GMR sensors.
Weddemann A, Ennen I, Regtmeier A, Albon C, Wolff A, Eckstadt K, Mill N, Peter MK, Mattay J, Plattner C, Sewald N, Hutten A., Beilstein J Nanotechnol 1(), 2010
PMID: 21977397
Weddemann A, Ennen I, Regtmeier A, Albon C, Wolff A, Eckstadt K, Mill N, Peter MK, Mattay J, Plattner C, Sewald N, Hutten A., Beilstein J Nanotechnol 1(), 2010
PMID: 21977397
Phenomenological theory of the giant magnetoresistance of superparamagnetic particles
Wiser N.., 1996
Wiser N.., 1996
Origin of Giant Magnetoresistance: Bulk or Interface Scattering
Zahn P., Binder J., Mertig I., Zeller R., Dederichs P.H.., 1998
Zahn P., Binder J., Mertig I., Zeller R., Dederichs P.H.., 1998
Spin glasses: Experimental facts, theoretical concepts, and open questions
Binder K., Young A.P.., 1986
Binder K., Young A.P.., 1986
Disorder strength and field-driven ground state domain formation in artificial spin ice: experiment, simulation, and theory.
Budrikis Z, Morgan JP, Akerman J, Stein A, Politi P, Langridge S, Marrows CH, Stamps RL., Phys. Rev. Lett. 109(3), 2012
PMID: 22861890
Budrikis Z, Morgan JP, Akerman J, Stein A, Politi P, Langridge S, Marrows CH, Stamps RL., Phys. Rev. Lett. 109(3), 2012
PMID: 22861890
COMSOL Multiphysics Modeling Software
AUTHOR UNKNOWN, 0
AUTHOR UNKNOWN, 0
Minor groove recognition is important for the transcription factor PhoB: a surface plasmon resonance study.
Ritzefeld M, Wollschlager K, Niemann G, Anselmetti D, Sewald N., Mol Biosyst 7(11), 2011
PMID: 21912786
Ritzefeld M, Wollschlager K, Niemann G, Anselmetti D, Sewald N., Mol Biosyst 7(11), 2011
PMID: 21912786
DNA-Bindung und Modifizierung der DNA-Bindenden Dom?ne des bakteriellen Transkriptionsfaktors PhoB aus E. coli
Niemann G.., 2014
Niemann G.., 2014
Reactive boundary conditions for stochastic simulations of reaction-diffusion processes.
Erban R, Chapman SJ., Phys Biol 4(1), 2007
PMID: 17406082
Erban R, Chapman SJ., Phys Biol 4(1), 2007
PMID: 17406082
Positioning system for particles in microfluidic structures
Weddemann A., Wittbracht F., Auge A., Hütten A.., 2009
Weddemann A., Wittbracht F., Auge A., Hütten A.., 2009
Export
Markieren/ Markierung löschen
Markierte Publikationen
Web of Science
Dieser Datensatz im Web of Science®Quellen
PMID: 25903554
PubMed | Europe PMC
Suchen in