Andreas Heerwig

Imine-linked polymer-derived nitrogen-doped microporous carbons with excellent CO2 capture properties.

A series of nitrogen-doped microporous carbons (NCs) was successfully prepared by direct pyrolysis of high-surface-area microporous imine-linked polymer (ILP, 744 m(2)/g) which was formed using commercial starting materials based on the Schiff base condensation under catalyst-free conditions. These NCs have moderate specific surface areas of up to 366 m(2)/g, pore volumes of 0.43 cm(3)/g, narrow micropore size distributions, and a high density of nitrogen functional groups (5.58-8.74%). The resulting NCs are highly suitable for CO2 capture adsorbents because of their microporous textural properties and large amount of Lewis basic sites. At 1 bar, NC-800 prepared by the pyrolysis of ILP at 800 °C showed the highest CO2 uptakes of 1.95 and 2.65 mmol/g at 25 and 0 °C, respectively. The calculated adsorption capacity for CO2 per m(2) (μmol of CO2/m(2)) of NC-800 is 7.41 μmol of CO2/m(2) at 1 bar and 25 °C, the highest ever reported for porous carbon adsorbents. The isosteric heats of CO2 adsorption (Qst) for these NCs are as high as 49 kJ/mol at low CO2 surface coverage, and still ~25 kJ/mol even at high CO2 uptake (2.0 mmol/g), respectively. Furthermore, these NCs also exhibit high stability, excellent adsorption selectivity for CO2 over N2, and easy regeneration and reuse without any evident loss of CO2 adsorption capacity.

Highly porous nitrogen-doped polyimine-based carbons with adjustable microstructures for CO2 capture

A series of highly porous nitrogen doped porous carbons (NPCs) have been successfully prepared using a novel porous polyimine as the precursor. The resulting NPCs have a high specific surface area of up to 3195 m2 g−1, high pore volume and micropore volume (up to 1.58 and 1.38 cm3 g−1, respectively), narrow micropore size distributions, and adjustable nitrogen (1.52–5.05 wt%) depending on the activation temperatures (600–750 °C). The CO2 uptakes of the NPCs prepared at higher temperatures (700–750 °C) are lower than those prepared at milder conditions (600–650 °C). At 1 bar, NPC-650 demonstrates the best CO2 capture performance and could efficiently adsorb CO2 molecules of 3.10 mmol g−1 (136 mg g−1) and 5.26 mmol g−1 (231.3 mg g−1), at 25 and 0 °C, respectively. The NPCs also show good a initial CO2/N2 adsorption selectivity of up to 23.4 and an adsorption ratio of CO2/N2 (6.6) at 1 bar. Meanwhile, these NPCs exhibit a high stability and facile regeneration/recyclability without evident loss of the CO2 capture capacities.

Dye Encapsulation Inside a New Mesoporous Metal–Organic Framework for Multifunctional Solvatochromic‐Response Function

Metal–organic frameworks (MOFs), hybrid materials built up from metal clusters and organic linkers, have shown a huge potential for a wide range of applications. In recent years, MOFs have set new records in terms of specific surface areas and pore volumes and therefore are highly suitable as storage materials for small and large molecules. The development of new materials is crucial for the improvement of storage devices, but MOFs are also ideal candidates for functionalization. One functionalization strategy is the integration of complex organic linker molecules containing secondary functional groups. However, this approach is synthetically demanding and not general, because functional donor atoms may affect the linker connectivity resulting in unexpected network topologies. A second powerful strategy is postsynthetic modification of the framework. In this case, the range of functions is restricted due to the limited stability of MOFs against aggressive chemicals. A modular and more versatile approach may be the encapsulation of functional guest molecules into the MOF material. However, for these systems leaching is critical. A crucial requirement in all cases is also the accessibility of MOF functionalities for guest molecules. In this context, a large pore size is highly beneficial. However, the development of such mesoporous frameworks is challenging, because expanded frameworks are often more fragile leading to a collapse of the framework during removal of included guests molecules. A very effective concept to achieve robust frameworks lies in the creation of hierarchical pore structures by combination of two different linker molecules. The most prominent examples of such copolymerization approach are UMCM-1/ 2/ 3, DUT-6 and DUT-23 or MOF210. In the case of DUT-23, auxiliary linker was used successfully to avoid interpenetration and to enhance the robustness, which resulted in highly porous structures. To date, this concept was restricted only to the combination of triand ditopic linkers. On the other hand, DUT-10(M) (M= Zn, Cu, Co) compounds based on the tetratopic N,N,N’,N’benzidinetetrabenzoate (benztb) ligand and the paddlewheel secondary building unit (SBU) undergo structural change upon solvent removal. By enhancing the connectivity of the framework by using a six-connecting [Zn4O] 6+

Electrical Actuation of a DNA Origami Nanolever on an Electrode

Development of electrically powered DNA origami nanomachines requires effective means to actuate moving origami parts by externally applied electric fields. We demonstrate how origami nanolevers on an electrode can be manipulated (switched) at high frequency by alternating voltages. Orientation switching is long-time stable and can be induced by applying low voltages of 200 mV. The mechanical response time of a 100 nm long origami lever to an applied voltage step is less than 100 μs, allowing dynamic control of the induced motion. Moreover, through voltage assisted capture, origamis can be immobilized from folding solution without purification, even in the presence of excess staple strands. The results establish a way for interfacing and controlling DNA origamis with standard electronics, and enable their use as moving parts in electro-mechanical nanodevices.

Tunable Fluorescence of a Semiconducting Polythiophene Positioned on DNA Origami

A novel approach for the integration of π-conjugated polymers (CPs) into DNA-based nanostructures is presented. Using the controlled Kumada catalyst-transfer polycondensation, well-defined thiophene-based polymers with controllable molecular weight, specific end groups, and water-soluble oligoethylene glycol-based side chains were synthesized. The end groups were used for the easy but highly efficient click chemistry-based attachment of end-functionalized oligodeoxynucleotides (ODNs) with predesigned sequences. As demonstrated by surface plasmon resonance spectroscopy, the prepared block copolymers (BCPs), P3(EO)3T-b-ODN, comprising different ODN lengths and specific or repetitive sequences, undergo specific hybridization with complementary, thiol-functionalized ODNs immobilized on a gold surface. Furthermore, the site-specific attachment of the BCPs to DNA origami structures is studied. We demonstrate that a nanoscale object, that is, a single BCP with a single ODN handle, can be directed and bound to the DNA origami with reasonable yield, site-specificity, and high spatial density. On the basis of these results, we are able to demonstrate for the first time that optical properties of CP molecules densely immobilized on DNA origami can be locally fine-tuned by controlling the attractive π-π-stacking interactions between the CPs. In particular, we show that the fluorescence of the immobilized CP molecules can be significantly enhanced by surfactant-induced breakup of π-π-stacking interactions between the CPs backbones. Such molecular control over the emission intensity of the CPs can be valuable for the construction of sophisticated switchable nanophotonic devices and nanoscale biosensors.

Dielectrophoresis of gold nanoparticles conjugated to DNA origami structures

Summary DNA nanostructures are promising construction materials to bridge the gap between self-assembly of functional molecules and conventional top-down fabrication methods in nanotechnology. Their positioning onto specific locations of a microstructured substrate is an important task towards this aim. Here we study manipulation and positioning of pristine and of gold nanoparticle-conjugated tubular DNA origami structures using ac dielectrophoresis. The dielectrophoretic behavior was investigated employing fluorescence microscopy. For the pristine origami, a significant dielectrophoretic response was found to take place in the megahertz range, whereas, due to the higher polarizability of the metallic nanoparticles, the nanoparticle/DNA hybrid structures required a lower electrical field strength and frequency for a comparable trapping at the edges of the electrode structure. The nanoparticle conjugation additionally resulted in a remarkable alteration of the DNA structure arrangement. The growth of linear, chain-like structures in between electrodes at applied frequencies in the megahertz range was observed. The long-range chain formation is caused by a local, gold nanoparticle-induced field concentration along the DNA nanostructures, which in turn, creates dielectrophoretic forces that enable the observed self-alignment of the hybrid structures.