2011
[1] Talin controls nanoscale spatial regulation of integrin recruitment and adhesive force
Coyer, S. R., Singh, A., Dumbauld, D. W., Craig, S. W., Calderwood, D. A., Delamarche, E. and Garcia, A. J.
Nature Cell Biology 2011, submitted.
[2] Controlled release of reagents in capillary-driven microfluidics using reagent integrators
Hitzbleck, M., Gervais, M. and Delamarche, E.
Lab Chip 2011, published on-line.
[3] Capillary-driven multiparametric microfluidic chips for one-step immunoassays
Gervais, L., Hitzbleck, M. and Delamarche, E.
Biosens. Bioelectron. 2011, published on-line.
[4] Microfluidic chips for point-of-care immunodiagnostics
Gervais, L., de Rooij, N. and Delamarche, E.
Adv. Mater. 2011, 23, H151-H176.
[5] Precise placement of gold nanorods by capillary assembly
Kuemin, C., Stutz, R., Spencer, N.D. and Wolf, H.
Langmuir 2011, 27, 6305-6310
[6] A vertical microfluidic probe
Kaigala, G. V., Lovchik, R. D. and Delamarche, E.
Langmuir 2011, 27, 5686–5693.
[7] Protein tethering into multiscale geometries by covalent subtractive printing
Coyer, S. R., Delamarche, E. and Garcia, A. J.
Adv. Mater. 2011, 23, 1550–1553.
2010
[1] Precision patterning with luminescent nanocrystal functionalized beads
Fanizza, E., Malaquin, L., Kraus, T., Wolf, H., Striccoli, M., Micali, N., Agostiano, A. and Curri, M.L.
Langmuir 2010, 26,14294-14300.
[2] Selective assembly of sub-micrometer polymer particles
Kuemin, C., Huckstadt, K. C., Lörtscher, E., Rey, A., Decker, A., Spencer, N.D. and Wolf, H.
Adv. Mater. 2010, 22, 2804-2808.
[3] Direct write 3-dimensional nanopatterning using probes
Duerig, U., Pires, D., Knoll, A., Drechsler, U., Despont, M., Wolf, H., Hedrick, J. and DeSilva, E.
Alternative Lithographic Technologies II, edited by D.J.C. Herr, Proc. SPIE, Vol. 7637 (SPIE, April 2010) 76371E.
[4] Nanoscale three-dimensional patterning of molecular resists by scanning probes
Pires, D., Hedrick, J. L., De Silva, A., Frommer, J., Gotsmann, B., Wolf, H., Despont, M., Duerig, U., and Knoll, A.W.
Science 2010, 328, 732-735.
[5] Templated self-assembly of particles
Kraus, T. and Wolf, H.
Springer Handbook of Nanotechnology, B. Bhushan (Ed), (Springer-Verlag, Berlin, Heidelberg, 2010) 3rd Ed., Part A Nanostructures, Micro-/Nanofabrication and Materials, Ch.6, pp. 187-210.
[6] Overflow microfluidic networks
Lovchik, R. D., Bianco, F., Tonna, N., Ruiz, A., Matteoli, M. and Delamarche, E.
Proceedings μTAS 2010, Groningen, 989–991.
[7] Extended dynamic range capillary-driven microfluidics
Gervais, L and Delamarche, E.
Proceedings μTAS 2010, Groningen, 809–811.
[8] Vertical microfluidic probe heads
Lovchik, R.D., U. Drechsler and Delamarche, E.
Proceedings μTAS 2010, Groningen, 1793–1795.
[9] Two complementary methods to characterize long range proximity effects due to develop loading
Sundberg, L. K., Wallraff, G. M., Fritz, A. M., Davis, B., Zweber, A. E., Lovchik, R. D., Delamarche, E., Senna, T., Komizo, T. and Hinsberg, W. D.
Proceedings SPIE 2010, 7823, 78230G.
[10] A method to characterize pattern density effects: Chemical flare and develop loading
Sundberg, L. K., Wallraff, G. M., Fritz, A. M., Zweber, A. E., Benes, Z., Lovchik, R. D., Delamarche, E. and Hinsberg, W. D.
in “Advances in Resist Materials and Processing Technology XXVII”, edited by R. D. Allen, Proceedings SPIE March 2010, vol. 7639, 76392S.
[11] Overflow microfluidic networks for open and closed cell cultures on chip
Lovchik, R. D., Bianco, F., Tonna, N., Ruiz, A., Matteoli, M. and Delamarche, E.
Anal. Chem. 2010, 82, 3936–3942.
[12] A microfluidic device for depositing and addressing two cell populations with intercellular population communication capability
Lovchik, R. D., Tonna, N., Bianco, F., Matteoli, M. and Delamarche, E.
Biomed. Microdev. 2010, 12, 275–282.
[13] Large-scale arrays of aligned single viruses
Solis, D. J., Coyer, S. R., Garcia, A. J. and Delamarche, E.
Adv. Mater. 2010, 22, 111–114.
2009
[1] One-step immunoassays on capillary-driven microfluidic chips
Gervais, L. and Delamarche, E.
Proceedings μTAS 2009, Jeju, 421–423.
[2] Multiparametric microfluidic chips for studying cellular pathways
Lovchik, R. D., Bianco, F., Matteoli, M. and Delamarche, E.
Proceedings μTAS 2009, Jeju, 591–593.
[3] Multilayered microfluidic probe heads
Lovchik, R. D., Drechsler, U. and Delamarche, E.
J. Micromech.Microeng. 2009, 12, 115006.
[4] Toward one-step point-of-care immunodiagnostics using capillary-driven microfluidics and PDMS substrates
Gervais, L. and Delamarche, E.
Lab Chip 2009, 9, 3313–3452.
[5] Controlled deposition of cells in sealed microfluidics using flow velocity boundaries
Lovchik, R. D., Bianco, F., Matteoli, M. and Delamarche, E.
Lab Chip, 2009, 9, 1395–1402.
[6] Autonomous capillary system for one-step immunoassays
Zimmermann, M., Hunziker, P. and Delamarche, E.
Biomed. Microdevices, 2009, 11, 1–8.
2008
[1] Matrix effects on the surface plasmon resonance of dry supported gold nanocrystals
Kuemin, C., Kraus, T., Wolf, H., Spencer, N.D.
Optics Letters, 2008, 33, 806-808.
[2] One-step immunoassay on capillary driven microfluidics
Gervais, L., Zimmermann, M., Hunziker, P. and Delamarche, E.
Proceedings μTAS 2008, San Diego, 1949–1951.
[3] Microfluidic selection of library elements
Solis, J. S., Lovchik, R. and Delamarche, E.
Proceedings μTAS 2008, San Diego, 224–226.
[4] High-performances immunoassays based on through-stencil patterned antibodies and capillary systems
Ziegler, J., Zimmermann, M., Hunziker, P. and Delamarche, E.
Anal. Chem., 2008, 80, 1763–1769.
[5] Valves for autonomous capillary systems
Zimmermann, M., Hunziker, P. and Delamarche, E.
Microfluid. Nanofluid., 2008, 5, 395–402.
[6] Cellular microarrays for capillary-driven microfluidics
Lovchik, R., von Arx, C., Viviani, A. and Delamarche, E.
Anal. Bioanal. Chem., 2008, 390, 801–808.
2007
[1] Controlled particle placement through convective and capillary
assembly
Malaquin, L., Kraus, T., Schmid, H., Delamarche, E. and Wolf, H.
Langmuir, 2007, 23, 11513-11521.
[2] Fully autonomous microfluidic capillary systems for fast and sensitive
surface immunoassays
Ziegler, J., Zimmermann, M., Hunziker, P. and Delamarche,
E.
Proceedings μTAS 2007, Paris, 101-103.
[3] Valves for autonomous microfluidic capillary systems
Zimmermann, M., Hunziker, P. and Delamarche, E.
Proceedings μTAS 2007, Paris, 1492-1494.
[4] High resolution multi-protein
nanopatterns
Coyer, S.R., Garcia, A.J. and Delamarche, E.
European Cells & Materials 2007, 14, 56.
[5] Facile preparation of complex protein architectures with sub-100-nm
resolution on surfaces
Coyer, S.R., Garcia, A.J. and Delamarche, E.
Angew. Chem., 2007, 46, 6837-6840.
[6] Microcontact processing for microtechnology and biology
Delamarche, E.
Chimia, 2007, 61, 126-132.
[7] Nanoparticle printing with single-particle resolution
Kraus, T., Malaquin, L., Schmid, H., Riess, W., Spencer, N. D.
and Wolf, H.
Nature Nanotechnology, 2007, 2, 570-576.
[8] An in situ study of the adsorption behavior of functionalized
particles on self-assembled monolayers via different chemical interactions
Ling, X. Y., Malaquin, L., Reinhoudt, D. N., Wolf, H., and Huskens,
J.
Langmuir, 2007, 23, 9990-9999
[9] Screening of cell membrane proteins using a micromosaic immunoassay
format
Wolf, M., Zimmermann, M., Hunziker, P. and Delamarche, E.
Biomed. Microdevices, 2007, 9, 135-141.
[10] Capillary pumps for autonomous capillary systems
Zimmermann, M., Schmid, H., Hunziker, P. and Delamarche, E.
Lab Chip 2007, 7, 119-125.
2006
[1] High-speed microcontact printing
Helmuth, J. A., Schmid, H., Stutz, R., Stemmer, A., Wolf, H.
J. Am. Chem. Soc. 2006, 128, 9296-9297.
[2] Advanced flow control of liquids in microfabricated capillary pumps
Zimmermann, M., Hunziker, P. and Delamarche, E.
Proceedings of the µTAS 2006, Tokyo, Japan, 612-614.
2005
[1] Printing chemical gradients
Kraus, T., Stutz, R., Balmer, T.E., Schmid, H., Malaquin, L., Spencer,
N.D., Wolf, H.
Langmuir 2005, 21, 7796-7804.
[2] Closing the gap between self-assembly and microsystems using self-assembly,
transfer, and integration (SATI) of nanoparticles
Kraus, T., Malaquin, L., Delamarche, E., Schmid, H., Spencer, N.
D. and Wolf, H.
Adv. Mater. 2005, 17, 2438-2442.
[3] Diffusion of alkanethiols in PDMS and its implications on microcontact
printing
Balmer, T., Schmid, H., Stutz, R., Delamarche, E., Michel, B., Spencer,
N. and Wolf, H.
Langmuir, 2005, 21, 622-632.
[4] Continuous flow in microfluidics using controlled evaporation
Zimmermann, M., Bentley, S., Schmid, H., Hunziker, P. and Delamarche,
E.
Lab Chip, 2005, 5, 1355-1359.
[5] Microcontact printing of proteins inside microstructures
Foley, J., Schmid, H., Stutz, R. and Delamarche, E.
Langmuir, 2005, 21, 11296-11303.
[6] Assembly and printing of micro and nano objects
Kraus, T., Malaquin, L., Delamarche, E., Schmid, H., Spencer, N.
D. and Wolf, H.
Proceedings of the µTAS 2005, Boston, MA, 539-541.
[7] Locally controlling the environment of a microfluidic chip and
programming its flow rates
Zimmermann, M., Bentley, S., Juncker, D., Schmid, H., Hunziker,
P. and Delamarche, E.
Proceedings of the µTAS 2005, Boston, MA, 578-580.
[8] Capillary effects used for liquid confinement and automatic flow
control in microfluidic probes
Juncker, D., Schmid, H. and Delamarche, E.
Proceedings of the µTAS 2005, Boston, MA, 596-598.
[9] Microfluidic probe with hydrodynamic flow confinement
Juncker, D., Schmid, H. and Delamarche, E.
Proceedings of the µTAS 2005, Boston, MA, 1048-1050.
[10] Engineering microfluidic chips with integrated binding sites for
ultraminiaturized immunoassays
Foley, J., Schmid, H., Stutz, R. and Delamarche, E.
Proceedings of the µTAS 2005, Boston, MA, 250-252.
[11] Microfluidics for processing surfaces and miniaturizing biological
assays
Delamarche, E., Juncker, D. and Schmid, H.
Adv. Mater., invited review, 2005, 17, 2911-2933.
[12] Multipurpose scanning microfluidic probe
Juncker, D., Schmid, H. and Delamarche, E.
Nature Materials, 2005, 4, 622-628.
[13] Modeling and optimization of high-sensitivity, low-volume microfluidic-based
surface immunoassays
Zimmermann, M., Delamarche, E., Wolf, M. and Hunziker, P.
Biomed. Microdev., 2005, 7, 99-110.
2004
[1] High-sensitivity miniaturized immunoassays for tumor necrosis factor
a using microfluidic systems
Cesaro-Tadic, S., Dernick, G., Juncker, D., Buurman, G., Kropshofer, H., Michel, B., Fattinger, C., Delamarche, E.
Lab Chip, 2004, 4, 563-569.
[2] Microcontact printing of proteins
Delamarche, E.
In Nanobiotechnology, C. Mirkin and N. Niemeyer (eds), 2004, Wiley-VCH
GmbH.
[3] Simultaneous detection of C-reactive protein and other cardiac
markers in human plasma using micromosaic immunoassays and self-regulating
microfluidic networks
Wolf, M., Juncker, D., Michel, B., Hunziker, P., Delamarche, E.
Biosens. Bioelectron. B, 2004, 19, 1193-1202.
2003
[1] Self-assembled microarrays of attoliter molecular vessels
Stamou, D., Duschl, C., Delamarche, E. and Vogel, H.
Angew. Chem. Int. Ed. 2003, 42, 5580-5583.
[2] Fabricating arrays of single proteins on glass using microcontact
printing
Renault, J. P., Bernard, A., Bietsch, A., Michel, B., Bosshard,
H. R., Kreiter, M., Hecht, B., Wild, U. and Delamarche, E.
J. Phys. Chem. B 2003, 107, 703-711.
[3] Selective wet-etching of microcontact-printed Cu substrates with
control over the etch profile
Geissler, M., Schmid, H., Michel, B., and Delamarche, E.
Microelec. Microeng. 2003, 67-68, 326-332.
[4] Microcontact printing using poly(dimethylsiloxane) stamps hydrophilized
using poly(ethylene oxide)-silanes
Delamarche, E., Donzel, C., Kamounah, F. S., Wolf, H., Geissler,
M., Stutz, R., Schmidt-Winkel, P., Michel, B., Mathieu, H. J. and
Schaumburg, K.
Langmuir 2003, 19, 8749-8758.
[5] Fabrication of metal nanowires using microcontact printing
Geissler, M., Wolf, H., Stutz, R., Delamarche, E., Grummt, U.-W.,
Michel, B. and Bietsch, A. Langmuir 2003, 19, 6301-6311.
[6] Direct patterning of NiB on glass substrates using microcontact
printing and electroless deposition
Geissler, M., Kind, H., Schmidt-Winkel, P., Michel, B. and Delamarche,
E.
Langmuir 2003, 19, 6283-6296.
[7] Electroless deposition of Cu on glass and patterning with microcontact
printing
Delamarche, E., Vichiconti, J., Hall, S., Geissler, M., Graham,
W., Michel, B. and Nunes, R.
Langmuir 2003, 19, 6567-6569.
[8] Patterning NiB electroless deposited on glass using an electroplated
Cu mask, microcontact printing, and wet etching
Delamarche, E., Geissler, M., Magnuson, R., Schmid, H. and Michel,
B.
Langmuir 2003, 19, 5892-5897.
[9] Electroless deposition of NiB on 15 inch glass substrates for the
fabrication of transistor gates for liquid crystal displays
Delamarche, E., Geissler, M., Vichiconti, J., Graham, W. S., Andry,
P. A., Flake, J. C., Fryer, P. M., Nunes, R. W., Michel, B., O'Sullivan,
E. J., Schmid, H., Wolf, H. and Wisnieff, R. L.
Langmuir 2003, 19, 5923-5935.
[10] Preparation of metallic films on elastomeric stamps and their application
for contact processing and contact printing
Schmid, H., Wolf, H., Allenspach, R., Riehl, H., Karg, S., Michel,
B. and Delamarche, E.
Adv. Func. Mater. 2003, 13, 145-153.
2002
[1] Autonomous microfluidic capillary system
Juncker, D., Schmid, J., Drechsler, U., Wolf, H., Wolf, M., Michel,
B., de Rooij, N. and Delamarche, E.
Anal. Chem. 2002, 74, 6139-6144.
[2] Fabricating microarrays of functional proteins using affinity contact
printing
Renault, J. P., Bernard, A., Juncker, D., Michel, B., Bosshard,
H. R. and Delamarche, E.
Angew. Chem. Int. Ed. 2002, 41, 2320-2323.
[3] Microfluidic capillary systems for the autonomous transport of
bio/chemicals
Juncker, D., Schmid, H., Drechsler, U., Wolf, H., Michel, B., de
Rooij, N. and Delamarche, E.
Proceedings of the µTAS 2002, 952-954.
[4] Positive microcontact printing
Delamarche, E., Geissler, M., Wolf, H. and Michel, B.
J. Am. Chem. Soc. 2002, 124, 3834-3835.
[5] Defect-tolerant and directional wet etch systems for using monolayers
as resists
Geissler, M., Schmid, H., Bietsch, A., Michel, B. and Delamarche,
E.
Langmuir 2002, 18, 2374-2377.
[6] Self-assembled monolayers of alkanethiols on palladium and their
use in microcontact printing
Carvalho, A., Geissler, M., Schmid, H., Michel, B. and Delamarche,
E.
Langmuir 2002, 18, 2406-2412.
2001
[1] Printing meets lithography: Soft approaches to high-resolution
patterning
Michel, B., Bernard, A., Bietsch, A., Delamarche, E., Geissler,
M., Juncker, D., Kind, H., Renault, J. P., Rothuizen, H., Schmid,
H., Schmidt-Winkel, P., Stutz, R. and Wolf, H.
IBM J. Res. Develop. 2001, 45, 697-719.
[2] Affinity-contact printing of functional cell adhesion molecules
for neuronal cell patterning
Bernard, A., Fitzli, D., Sonderegger, P., Delamarche, E., Michel,
B., Bosshard, H. R. and Biebuyck, H. A.
Nature Biotechnology 2001, 19, 866-869.
[3] Soft and rigid 2-level microfluidic networks for patterning surfaces
Juncker, D., Schmid, H., Bernard, A., Caelen, I., Michel, B., de
Rooij, N. and Delamarche, E.
J. Micromech. Microeng. 2001, 11, 532-541.
[4] Microfluidic networks for patterning biomolecules and performing
bioassays
Juncker, D., Bernard, A., Caelen, I., Schmid, H., Papra, A., Michel,
B., de Rooij, N. and Delamarche, E.
Proceedings of the µTAS 2001, 429-431.
[5] Microfluidic networks of polydimethylsiloxane, Si and Au coated
with polyethylene glycol for patterning proteins onto surfaces
Papra, A., Bernard, A., Juncker, D., Larsen, N. B., Michel, B. and
Delamarche, E.
Langmuir 2001, 17, 4090-4095.
[6] Micromosaic immunoassays
Bernard, A., Michel, B. and Delamarche, E.,
Anal. Chem. 2001, 73, 8-12.
[7] Hydrophilic poly(dimethylsloxane) stamps for microcontact printing.
Donzel, C., Geissler, M., Bernard, A., Wolf, H., Michel, B., Hilborn,
J. and Delamarche, E.
Adv. Mater. 2001, 13, 1164-1167.
[8] Contrast mechanisms in high-resolution contact lithography: A comparative
study
Paulus, M., Schmid, H., Michel, B., Martin, O. J. F.
Microel. Eng. 2001, 57-58, 109-116.
2000
[1] Formation of gradients of proteins on surfaces with microfluidic
networks
Caelen, I., Bernard, A., Juncker, D., Michel, B., Heinzelmann, H.
and Delamarche, E.
Langmuir 2000, 16, 9125-9130.
[2] Microcontact printing of proteins
Bernard, A., Renault, J. P., Michel, B., Bosshard, H. R. and Delamarche,
E.
Adv. Mater. 2000, 12, 1067-1070.
[3] Microcontact printing chemical patterns with flat stamps
Geissler, M., Bernard, A, Bietsch, A., Schmid, H., Michel, B. and
Delamarche, E.
J. Am. Chem. Soc. 2000, 122, 6303-6304.
[4] Stress at the solid-liquid interface of self-assembled monolayers
on gold by a nanomechanical sensor
Fritz, J., Baller, M. K., Lang, H. P., Meyer, E., Güntherodt,
H.-J., Delamarche, E., Gerber, Ch. and Gimzewski, J. K.
Langmuir 2000, 16, 9694-9696.
[5] Patterned electroless deposition of copper by microcontact printing
palladium(II) complexes on titanium-covered surfaces
Kind, H., Geissler, M., Schmid, H., Michel, B., Kern, K. and Delamarche,
E.
Langmuir 2000, 16, 6367-6373.`
[6] Conformal contact and stability of stamps used for soft lithography
Bietsch, A. and Michel, B.
J. Appl. Phys. 2000, 88, 4310-4318.
[7] Siloxane Polymers for High-Resolution, High-Accuracy Soft Lithography
Schmid, H. and Michel, B.
Macromolecules, 2000, 33, 3042-3049.
1999
[1] Kelvin probe force microscopy on surfaces:
Investigation of the surface potential of self-assembled monolayers
on gold
Lü, J., Delamarche, E., Eng, L., Bennewitz, R., Meyer, E., and
Güntherodt, H.-J.
Langmuir 1999, 15, 8184-8188.
[2] Surface potential studies of self-assembling monolayers using Kelvin
probe force microscopy
Lü, J., Eng, L., Bennewitz, R., Meyer, E., Güntherodt,
H.-J., Delamarche, E. and Scandella, L.
Surf. Interface Anal. 1999, 368-373.
[3] Contact inking PDMS stamps for microcontact printing alkanethiols
on gold
Libioulle, L., Bietsch, A., Schmid, H., Michel, B. and Delamarche,
E.
Langmuir 1999, 15, 300-304.
1998
[1] Printing patterns of proteins
Bernard, A., Delamarche, E., Schmid, H., Michel, B., Bosshard, H.
R. and Biebuyck, H. A.
Langmuir 1998, 14, 2225-2229.
[2] Microfluidic networks for chemical patterning of substrates: Design
and applications to bioassays
Delamarche, E., Bernard, A., Schmid, H., Bietsch, A., Michel, B.
and Biebuyck, H. A.
J. Am. Chem. Soc. 1998, 120, 500-508.
[3] Transport mechanisms of alkanethiols during microcontact printing
on gold
Delamarche, E., Schmid, H., Bietsch, A., Larsen, N. B., Rothuizen,
H., Michel, B. and Biebuyck, H. A. J. Phys. Chem. B 1998, 102, 3324-3334.
[4] Surface stress in the self-assembly of alkanethiols on gold probed
by a force microscopy technique
Berger, R., Delamarche, E., Lang, H. P., Gerber, Ch., Gimzewski,
J. K., Meyer, E. and Güntherodt, H.-J.
Appl. Phys. A 1998, 66, S55-S59.
[5] Light-coupling masks for lensless, sub-wavelength optical lithography
Schmid, H., Biebuck, H., Michel, B., Martin, O. J. F.
Appl. Phys. Lett. 1998, 72, 2379-2381.
1997
[1] Patterned delivery of immunoglobulins to
surfaces using microfluidic networks
Delamarche, E., Bernard, A., Schmid, H., Michel, B., Biebuyck, H.
Science, 1997, 276, 779-781.
[2] Integration of silicon micromechanical arrays with molecular monolayers
for miniaturized sensor systems
Berger, R., Lang, H.P., Delamarche, E., Gerber, Ch., Gimzewski,
J.K., Andreoli, C., Brugger, J., Despont, M., and Vettiger, P.
Sensors and their Applications VIII, Institute of Physics Publishing
1997, p71-76.
[3] Making gold nanostructures using positive lithography with electron
brams and self-assembled monolayers
Delamarche, E., Hoole, A. C. F., Michel, B., Wilkes, S., Despont,
M., Welland, M. E. and Biebuyck, H. A.
J. Phys. Chem. 1997, 101, 9263-9269.
[4] Stability of molded microstructures in polydimethylsiloxane
Delamarche, E., Biebuyck, H. A., Schmid, H. and Michel, B.
Adv. Mater. 1997, 9, 741-746.
[5] Surface stress in the self-assembly of alkanethiols on gold
Berger, R., Delamarche, E., Lang, H. P., Gerber, Ch., Gimzewski,
J. K., Meyer, E. and Güntherodt, H.-J.
Science 1997, 276, 2021-2024.
[6] Lithography beyond light: Microcontact printing with monolayer
resists
Biebuyck, H. A., Larsen, N. B., Delamarche, E. and Michel, B.
IBM J. Res. Develop. 1997, 41, 159-170.
[7] Order in microcontact printed self-assembled monolayers
Larsen, N. B., Biebuyck, H. A., Delamarche, E. and Michel, B.
J. Am. Chem. Soc. 1997, 119, 3017-3026.
1996
[1] Immobilization of antibodies on a photoactive
self-assembled monolayer on gold
Delamarche, E., Sundarababu, G., Biebuyck, H., Michel, B., Gerber,
Ch., Sigrist, H., Wolf, H., Ringsdorf, H., Xanthopoulos, N., Mathieu, H.J.
Langmuir, 1996, 12, 1997-2006.
[2] Golden interfaces: The surface of self-assembled monolayers
Delamarche, E., Michel, B., Biebuyck, H. A. and Gerber, Ch.
Adv. Mater. 1996, 8, 719-729.
[3] Structure and stability of self-assembled monolayers
Delamarche, E. and Michel, B.
Thin Solid Films 1996, 273, 54-60.
1995
[1] Recognition of individual tail groups in self-assembled monolayers
Takami, T., Delamarche, E., Michel, B., Gerber, Ch., Wolf, H. and
Ringsdorf, H.
Langmuir 1995, 11, 3876-3881.
[2] End-group dominated molecular order in self-assembled monolayers
Wolf, H., Ringsdorf, H., Delamarche, E., Takami, T., Kang, H., Michel,
B., Gerber, Ch., Jaschke, M., Butt, H.-J. and Bamberg, E.
J. Phys. Chem. 1995, 99, 7102-7107.
[3] STM analysis of cytochrome c immobilized on SAMs on gold
Delamarche, E., Biebuyck, H. A., Michel, B., Sundarababu, G., Sigrist,
H., Wolf, H. and Ringsdorf, H. Procedures in SPM, p7.3.4.1-5, Colton
et al. eds, Wiley 1995.
1994
[1] Thermal stability of self-assembled monolayers
Delamarche, E., Michel, B., Kang, H. and Gerber, Ch.
Langmuir 1994, 10, 4103-4108.
[2] The structure of hydrophilic self-assembled monolayers: A combined
scanning tunneling microscopy and computer simulation study
Sprik, M., Delamarche, E., Michel, B., Röthlisberger, U., Klein,
M. L., Wolf, H. and Ringsdorf, H. Langmuir 1994, 10, 4116-4130.
[3] Real-space observation of nanoscale molecular domains in self-assembled
monolayers
Delamarche, E., Michel, B., Gerber, Ch., Anselmetti, D., Güntherodt,
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