We
report the selection of DNA-encoded small molecule libraries
against protein targets within the cytosol and on the surface of live
cells. The approach relies on generation of a covalent linkage of
the DNA to protein targets by affinity labeling. This cross-linking
event enables subsequent copurification by a tag on the recombinant
protein. To access targets within cells, a cyclic cell-penetrating
peptide is appended to DNA-encoded libraries for delivery across the
cell membrane. As this approach assesses binding of DELs to targets
in live cells, it provides a strategy for selection of DELs against
challenging targets that cannot be expressed and purified as active.
Radiative sky cooling reduces the temperature of a system by promoting heat exchange with the sky; its key advantage is that no input energy is required. We will review the origins of radiative sky cooling from ancient times to the modern day, and illustrate how the fundamental physics of radiative cooling calls for a combination of properties that may not occur in bulk materials. A detailed comparison with recent modeling and experiments on nanophotonic structures will then illustrate the advantages of this recently emerging approach. Potential applications of these radiative cooling materials to a variety of temperature-sensitive optoelectronic devices, such as photovoltaics, thermophotovoltaics, rectennas, and infrared detectors, will then be discussed. This review will conclude by forecasting the prospects for the field as a whole in both terrestrial and space-based systems.
The thermal and mechanical properties of b-Yb 2 Si 2 O 7 were investigated using a combination of first-principles calculations and experimental investigations. Theoretically, anisotropic chemical bonding and elastic properties, weak interatomic (010) and (001) planes in the crystal structure, damage tolerance, and low thermal conductivity are predicted. Experimentally, preferred orientation, superior mechanical properties, and damage tolerant behavior for hot-pressed bulk b-Yb 2 Si 2 O 7 are approved. Slipping along the weakly bonded {010}, {001}, or {100} planes, grain delamination, buckling, and kinking of nanolaminated grains are identified as main mechanisms for damage tolerance. The anisotropic linear thermal expansion coefficients (CTEs) are: a a = (3.57 AE 0.18) 3 10 À6 K À1
The crystallization behavior of PBA on highly oriented PE substrate from solution as well
as melt was studied by optical microscopy, transmission electron microscopy, and X-ray diffraction. The
results show that the PE exhibits very strong nucleation ability toward PBA as reflected by the occurrence
of heteroepitaxy and transcrystallization of PBA on the PE substrate. The epitaxial crystallization of
PBA on PE substrate results in the formation of β-PBA crystals at any crystallization conditions. This is
associated with the perfect lattice matching between the β-form PBA and PE crystals and can provide us
a simple way to control the crystalline modification of PBA during different processing process in order
to regulate its crystal size.
Abstract:Recently, there has been increasing interest in utilizing solar thermophotovoltaics (STPV) to convert sunlight into electricity, given their potential to exceed the Shockley-Queisser limit. Encouragingly, there have also been several recent demonstrations of improved systemlevel efficiency as high as 6.2%. In this work, we review prior work in the field, with particular emphasis on the role of several key principles in their experimental operation, performance, and reliability. In particular, for the problem of designing selective solar absorbers, we consider the trade-off between solar absorption and thermal losses, particularly radiative and convective mechanisms. For the selective thermal emitters, we consider the tradeoff between emission at critical wavelengths and parasitic losses. Then for the thermophotovoltaic (TPV) diodes, we consider the trade-off between increasing the potential short-circuit current, and maintaining a reasonable opencircuit voltage. This treatment parallels the historic development of the field, but also connects early insights with recent developments in adjacent fields. With these various components connecting in multiple ways, a system-level end-to-end modeling approach is necessary for a comprehensive understanding and appropriate improvement of STPV systems. This approach will ultimately allow researchers to design STPV systems capable of exceeding recently demonstrated efficiency values.
Detailed knowledge of the tip apex structure is necessary for quantitative comparison between theory-based simulations and experimental observations of tip-substrate interactions in scanning probe microscopy (SPM). Here, we discuss field ion microscopy (FIM) techniques to characterize and atomically define SPM tungsten tips. The tip radius can be estimated from field emission data, while FIM imaging allows the full atomic characterization of the tip apex. We find that when FIM is applied to tips with a radius of a few nanometers (as is desirable for high-resolution atomic force microscopy imaging), limitations not apparent with less sharp tips arise; successful resolution of these limitations will extend the utility of FIM. Field evaporation can be used to atomically engineer the apex into a desired atomic configuration. Starting from a W(111) wire, a tip terminating in three atoms can reproducibly be fabricated; due to its geometry and stability, this apex configuration is well suited for application as an atomically defined electrical contact in SPM experiments aimed at understanding contact mechanics at the atomic scale
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