Integration of sharp silicon nitride tips into high-speed SU8 cantilevers in a batch fabrication process

Employing polymer cantilevers has shown to outperform using their silicon or silicon nitride analogues concerning the imaging speed of atomic force microscopy (AFM) in tapping mode (intermittent contact mode with amplitude modulation) by up to one order of magnitude. However, tips of the cantilever made out of a polymer material do not meet the requirements for tip sharpness and durability. Combining the high imaging bandwidth of polymer cantilevers with making sharp and wear-resistant tips is essential for a future adoption of polymer cantilevers in routine AFM use. In this work, we have developed a batch fabrication process to integrate silicon nitride tips with an average tip radius of 9 ± 2 nm into high-speed SU8 cantilevers. Key aspects of the process are the mechanical anchoring of a moulded silicon nitride tip and a two-step release process. The fabrication recipe can be adjusted to any photo-processable polymer cantilever.

Stimuli-responsive nanostructured surfaces

Ana Maria Popa

The coupling of stimuli-responsive macromolecules to nanostructured surfaces opens the perspective for the fabrication and integration of "smart" micro- and nano-electro-mechanical systems (MEMS&NEMS) in which the smallest motile unit is the polymeric chain. The goal of this work was to develop thermoresponsive, durable nanoporous surfaces as a first step toward the fabrication of functional nanocontainers and nanovalves. The proposed strategy involves in a first step the design and implementation of a clean-room compatible, reproducible and up-scalable method for defining organized nanoporous arrays in MEMS compatible surfaces, such as silicon, silicon oxide and silicon nitride. The main objective of the second step was the covalent immobilization of responsive macromolecules on the obtained structures, as to provide the later with a "smart" behavior. The nanostructuring step was realized by block-copolymer assisted lithography. This newly developed technique enables the definition of nanoscale features on semiconductor substrates over large surface areas and in a cost effective manner. A novel method for patterning thin metal films by a lift-off approach, using spin coated block-copolymer micelles monolayers as a template, was investigated. The obtained nanoporous mask was used as resist for the structuring of hard substrates in plasma-assisted processes and structures with aspect ratios as high as 1:10 were be obtained. By using different block-copolymer micelles and spin-coating conditions, the proposed approach enables the variation of the nanopores' diameter from 40 to 80 nm and a surface coverage between 11.7% and 25.5 % in an independent manner. This technique was successfully integrated in a standard microfabrication process for the batch production of thin nanoporous silicon nitride membranes. The 100 nm thick membranes span over thousands of square micrometers and present porosities higher than 109 pores/cm2. They are thus competitive in terms of porosity with the commercially available polymeric membranes. In addition they are two orders of magnitude thinner than polymeric membranes, this making them extremely interesting for applications where permeation rate or response time is important. The rapid flow of water soluble small molecular species through the nanopores was demonstrated in a qualitative manner in this work. Another series of investigations targeted the functionalization of the available nanoporous surfaces with responsive molecules. Poly(N-isopropyl acrylamide) (PNIPAAM) was chosen as a model system. Its coupling to silicon surfaces by a "grafting-to" approach from melt, using an epoxy-functionalized silane as anchoring layer was studied. The analysis of the yielded grafting density showed results superior to those obtained by classic grafting-to approaches. The relation between the polymer's weight and its responsiveness was investigated in liquid media by atomic force microscopy and by dynamic force spectroscopy. Polymers with more than 500 monomers in the back bone were shown to exhibit enhanced responsiveness. Additionally, two bioengineered polymers from the class of elastin-like polymers (ELPs) were investigated as possible candidates for the fabrication of stimuli responsive nanovalves. The molecules were synthesized in collaboration with the Bioforge group (Universidad de Valladolid, Spain) and details of the bioproduction process are presented. A method for the covalent photoattachment of macromolecules using a benzophenone-functionalized silane, was tested in this work. First the capacity of the benzophenone silane to graft synthetic thermo-responsive polymers such as PNIPAAM was demonstrated. The temperature-induced morphology change of the photografted PNIPAAM was not affected by this anchoring strategy and was monitored by tapping AFM in liquid media. The investigations were then extended to the photo-immobilization of ELPs on nanoporous silicon surfaces and the XPS measurements revealed the success of this step. However no conformation modification of the proteins could be evidenced by tapping-mode AFM in liquid media under different ionic strengths.

EPFL2009

A new versatile hybrid MEMS technology for high sensitivity, fluid proof sensing applications.

Matthias Neuenschwander

The field of micro electromechanical systems (MEMS) evolved from the microelectronic industry and the technologies developed to fabricate integrated circuits. As a result, MEMS are commonly fabricated on silicon wafers. The development of MEMS has been driven by three main merits: miniaturisation, microelectronics integration, and parallel fabrication with high precision. Many operational properties scale well with smaller sizes. In addition, integrated electronic circuitry allows embedding MEMS with computing or networking capabilities, while parallel manufacturing enables the fabrication of many identical devices on a single wafer, reducing the unit cost. The main MEMS application is transducers which transform signals from one form of energy to another, and can be used for perception (sensors) or to produce actions (actuators). Silicon and other microelectronic materials like metals have enabled very high-performance MEMS transducers because these materials can be used for a range of very effective actuating and sensing principles.More recently, polymers have started to be used in MEMS because of their unique electrical, physical and chemical properties which include biocompatibility, viscoelasticity and mechanical shock tolerance. They are also much softer than silicon or metals, and they can be processed using many techniques that allow unique low-cost, batch-style fabrication and packaging. However, polymers have relatively low glass-transition and melting temperatures. As a result, the advantages of polymers cannot easily be combined with high-performance actuating and sensing elements as these are based on silicon technology and require high-temperature fabrication steps. Here, a hybrid-MEMS fabrication process is used to address this issue. The developed devices are based on a trilayer structure, where a thick polymer core is sandwiched between two hard thin films, while electronic layers are embedded within in a fluid-compatible way.The objective of this thesis is to turn hybrid-MEMS into a benchmark MEMS technology. This involves many different aspects. First, sensing and actuation elements are integrated into trilayer devices, and their performance is analysed. Then, some more unique possibilities offered by hybrid-MEMS are exploited. A way to fabricate electronics on multiple layers is developed, which allows different electronic features to be integrated in parallel. In addition, three-dimensional bulk features fabricated at several levels are demonstrated. This is possible because the hybrid-MEMS process is based on the bonding of multiple wafers.All these new fabrication features are demonstrated in atomic force microscopy (AFM) applications. Self-actuated trilayer AFM cantilevers with sharp silicon tips are used to boost imaging speeds in the off-resonance tapping (ORT) mode, thanks to an order of magnitude faster surface probing rates. Furthermore, fully integrated ORT imaging is demonstrated with self-actuated piezoresistive cantilevers. Next, trilayer cantilevers with shielded conductive tips are introduced for electrical AFM modes. Finally, ongoing research projects are touched upon, including approaches to fabricate hybrid-MEMS with single crystal silicon piezoresistors for improved sensitivity, and an analysis of reproducibility of fabricated trilayer cantilevers.

EPFL2022

Stimuli-responsive nanostructured surfaces

Ana Maria Popa

EPFL2009

A new versatile hybrid MEMS technology for high sensitivity, fluid proof sensing applications.

Matthias Neuenschwander

EPFL2022