The proposal follows the SNF advice of a single project per applicant in division II. It is divided in five subprojects, each being the subject of a PhD thesis. In spite of the different research targets, they have enough overlap enabling the fruitful exchange of knowledge and mutual developments required to build up a joint group identity. All five projects focus on current challenges in nanotechnology, molecular devices, and supramolecular materials, which are addressed by novel strategies and innovative molecular designs of functional structures. The five subprojects are briefly described in the following: (I) «Geländer»-molecules and helical architectures: «Geländer»-molecules consist of two periodically interlinked oligomers which compensate their length mismatch by wrapping the longer one helically around the shorter one, resembling the shape of the banister (Geländer in German) of a spiral staircase. The here promoted new designs profit from right-angled connections resulting in a simplified symmetry of the building blocks which should make longer oligomers synthetically accessible. A second strategy based on o-tetraphenylene building blocks is geared towards helical «plait»-type oligomers. (II) mechanosensitive model compounds for molecular junctions are based on cyclophane-type architectures enabling to tune the extent of the coupling between their subunits mechanically. With small [2.2]paracyclonaphthane derivatives the effect of torque motion shall be explored, while a polycyclic porphyrin hexamer will be assembled with two stacked states with large difference in their expansion. Based on a «upended» porphyrin type structure, even the coupling of the single electrons of two parallel radical planes might be investigated. (III) B-field sensitive macrocyclic model compounds are loop-shaped macrocycles consisting of a conjugated periphery decorated with terminal anchor groups enabling their integration in single molecule junction experiments. The intention is to detect the contribution of the Lorentz force to the molecules transport current. With a compact and twisted OPE type macrocycle, the axial chirality of the immobilized structure might become specifiable in the transport experiment. (IV) synthesis of an armchair carbon nanotube (CNT) is an interesting synthetic strategy for the controlled wet chemical assembly of an armchair CNT. A belt fragment of a CNT shall be obtained from a macrocycle by a reaction sequence, which can subsequently be repeatedly applied to control the length of the CNT. (V) approaches towards molecular textiles are based on the development of a cross-type junction acting a covalent template arranging the precursors at the water/air interface. Upon interlinking within the LB-film and cleavage of the template, textile-type interwoven molecular films should be obtained. The potential of the cross-type junction for superstructures will be investigated as well.