Stefan Palzer
Stefan Palzer
Universidad Autónoma de Madrid
Bestätigte E-Mail-Adresse bei
Zitiert von
Zitiert von
A trapped single ion inside a Bose–Einstein condensate
C Zipkes, S Palzer, C Sias, M Köhl
Nature 464 (7287), 388-391, 2010
Quantum transport through a Tonks-Girardeau gas
S Palzer, C Zipkes, C Sias, M Köhl
Physical review letters 103 (15), 150601, 2009
Cold heteronuclear atom-ion collisions
C Zipkes, S Palzer, L Ratschbacher, C Sias, M Köhl
Physical review letters 105 (13), 133201, 2010
Gas response of reactively sputtered ZnO films on Si-based micro-array
Y Min, HL Tuller, S Palzer, J Wöllenstein, H Böttner
Sensors and Actuators B: Chemical 93 (1-3), 435-441, 2003
Photoacoustic-based gas sensing: A review
S Palzer
Sensors 20 (9), 2745, 2020
Photo-induced room-temperature gas sensing with a-IGZO based thin-film transistors fabricated on flexible plastic foil
S Knobelspies, B Bierer, A Daus, A Takabayashi, GA Salvatore, ...
Sensors 18 (2), 358, 2018
Apparatus to characterize gas sensor response under real-world conditions in the lab
J Kneer, A Eberhardt, P Walden, A Ortiz Pérez, J Wöllenstein, S Palzer
Review of Scientific Instruments 85 (5), 2014
A wireless gas sensor network to monitor indoor environmental quality in schools
A Ortiz Perez, B Bierer, L Scholz, J Wöllenstein, S Palzer
Sensors 18 (12), 4345, 2018
New method to selectively determine hydrogen sulfide concentrations using CuO layers
J Kneer, S Knobelspies, B Bierer, J Wöllenstein, S Palzer
Sensors and Actuators B: Chemical 222, 625-631, 2016
Entanglement dynamics under decoherence: from qubits to qudits
ARR Carvalho, F Mintert, S Palzer, A Buchleitner
The European Physical Journal D 41, 425-432, 2007
Miniature low-cost carbon dioxide sensor for mobile devices
L Scholz, AO Perez, B Bierer, P Eaksen, J Wöllenstein, S Palzer
IEEE Sensors Journal 17 (9), 2889-2895, 2017
Design of a LED-based sensor for monitoring the lower explosion limit of methane
V Wittstock, L Scholz, B Bierer, AO Perez, J Wöllenstein, S Palzer
Sensors and Actuators B: Chemical 247, 930-939, 2017
Micromachined hotplate platform for the investigation of ink-jet printed, functionalized metal oxide nanoparticles
P Walden, J Kneer, S Knobelspies, W Kronast, U Mescheder, S Palzer
Journal of Microelectromechanical Systems 24 (5), 1384-1390, 2015
MID-IR led-based, photoacoustic CO2 sensor
L Scholz, AO Perez, S Knobelspies, J Wöllenstein, S Palzer
Procedia engineering 120, 1233-1236, 2015
Investigation of reactions between trace gases and functional CuO nanospheres and octahedrons using NEXAFS-TXM imaging
K Henzler, A Heilemann, J Kneer, P Guttmann, H Jia, E Bartsch, Y Lu, ...
Scientific reports 5 (1), 17729, 2015
Scalable gas sensors fabrication to integrate metal oxide nanoparticles with well-defined shape and size
H Gao, H Jia, B Bierer, J Wöllenstein, Y Lu, S Palzer
Sensors and Actuators B: Chemical 249, 639-646, 2017
Monitoring the wobbe index of natural gas using fiber-enhanced Raman spectroscopy
V Sandfort, BM Trabold, A Abdolvand, C Bolwien, PSJ Russell, ...
Sensors 17 (12), 2714, 2017
Low-cost gas sensing system for the reliable and precise measurement of methane, carbon dioxide and hydrogen sulfide in natural gas and biomethane
S Knobelspies, B Bierer, AO Perez, J Wöllenstein, J Kneer, S Palzer
Sensors and Actuators B: Chemical 236, 885-892, 2016
Manipulating the gas–surface interaction between copper (II) oxide and mono-nitrogen oxides using temperature
J Kneer, J Wöllenstein, S Palzer
Sensors and Actuators B: Chemical 229, 57-62, 2016
Specific, trace gas induced phase transition in copper (II) oxide for highly selective gas sensing
J Kneer, J Wöllenstein, S Palzer
Applied Physics Letters 105 (7), 2014
Das System kann den Vorgang jetzt nicht ausführen. Versuchen Sie es später erneut.
Artikel 1–20