Although lithium−sulfur (Li−S) batteries have long been touted as next-generation energy storage devices, the rampant dendrite growth at the anode side and sluggish redox kinetics at the cathode side drastically impede their practical application. Herein, a dual-functional fibrous skeleton implanted with single-atom Co− N x dispersion is devised as an advanced modificator to realize concurrent regulation of both electrodes. The rational integration of single-atomic Co−N x sites could convert the fibrous carbon skeleton from lithiophobic to lithiophilic, helping assuage the dendritic formation for the Li anode. Meanwhile, the favorable electrocatalytic activity from the Co−N x species affording a lightweight feature effectively enables expedited bidirectional conversion kinetics of sulfur electrochemistry, thereby inhibiting the polysulfide shuttle. Moreover, the interconnected porous framework endows the entire skeleton with good mechanical robustness and fast electron/ion transportation. Benefiting from the synergistic effects between atomically dispersed Co−N x sites and three-dimensional conductive networks, the integrated Li−S full batteries can achieve a reversible areal capacity (>7.0 mAh cm −2 ) at a sulfur loading of 6.9 mg cm −2 . This work might be beneficial to the development of practically viable Li−S batteries harnessing single-atom mediators.
Mass
production of graphene powders affording high quality and
environmental benignancy serves as a prerequisite for the practical
usage of graphene in multiple energy storage applications. Herein,
we exploit a salt-templated CVD approach to harness the direct synthesis
of nitrogen-doped graphene (NG) nanosheets and related ink dispersions
in a scalable, safe, efficient, and green fashion. Thus-fabricated
NG accompanying large productivity, excellent electrical conductivity,
and favorable solution processability possesses implications in printable
energy storage devices. With the NG-based ink in hand, self-standing
3D architectures with programmable patterns can be directly printed
over a myriad of substrates. Accordingly, both electrode preparation
for flexible supercapacitors and separator modification in Li–S
batteries can be enabled via printing by employing
our NG-based composite inks. This work thus represents a practical
route for mass production of graphene inks with cost-effectiveness
and eco-friendliness for emerging energy storage technology.
Cassava plants (Manihot esculenta Crantz) resist environmental stresses by shedding leaves in leaf pulvinus abscission zones (AZs), thus leading to adaptation to new environmental conditions. Little is known about the roles of cassava R2R3 MYB factors in regulating AZ separation. Herein, 166 cassava R2R3 MYB genes were identified. Evolutionary analysis indicated that the 166 R2R3 MYB genes could be divided into 11 subfamilies. Transcriptome analysis indicated that 26 R2R3 MYB genes were expressed in AZs across six time points during both ethylene- and water-deficit stress-induced leaf abscission. Comparative expression profile analysis of similar SOTA (Self Organizing Tree Algorithm) clusters demonstrated that 10 R2R3 MYB genes had similar expression patterns at six time points in response to both treatments. GO (Gene Ontology) annotation confirmed that all 10 R2R3 MYB genes participated in the responses to stress and ethylene and auxin stimuli. Analysis of the putative 10 R2R3 MYB promoter regions showed that those genes primarily contained ethylene- and stress-related cis-elements. The expression profiles of the genes acting downstream of the selected MYBs were confirmed to be involved in cassava abscission zone separation. All these results indicated that R2R3 MYB plays an important regulatory role in AZ separation.
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