Victoria Norman scite author profile

N-type organic small molecules (SMs) are attracting attention in the organic electronics field, due to their easy purification procedures with high yield. However, only a few reports show SMs that perform well in both organic fieldeffect transistors (OFETs) and organic solar cells (OSCs). Here, the synthesis and characterization of an n-type small molecule with an indacenodithieno[3,2b]thiophene (IDTT) core unit and linear alkylated side chain (C 16 ) (IDTTIC) are reported. Compared to the state-of-the-art n-type mole cule IDTIC, IDTTIC exhibits smaller optical bandgap and higher absorption coefficient, which is due to the enhanced intramolecular effect. After mixing with the polymer donor PBDB-T, IDTIC-based solar cells deliver a power conversion efficiency of only 5.67%. In stark contrast, the OSC performance of IDTTIC improves significantly to 11.2%. It is found that the superior photovoltaic properties of PBDB-T:IDTTIC blends are mainly due to reduced trap-assisted recombination and enhanced molecular packing coherence length and higher domain purity when compared to IDTIC. Moreover, a significantly higher electron mobility of 0.50 cm 2 V −1 s −1 for IDTTIC in OFET devices than for IDTIC (0.15 cm 2 V −1 s −1 ) is obtained. These superior performances in OSCs and OFETs demonstrate that SMs with extended π-conjugation of the backbone possess a great potential for application in organic electronic devices.

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CrbpI regulates mammary retinoic acid homeostasis and the mammary microenvironment

Pierzchalski

Norman

et al. 2013

FASEB j.

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Cellular retinol-binding protein, type I (CrbpI), encoded by retinol-binding protein, type 1 (Rbp1), is a chaperone of vitamin A (retinol) that is epigenetically silenced in ~25% of human breast cancers. CrbpI delivers vitamin A to enzymes for metabolism into an active metabolite, all-trans retinoic acid (atRA), where atRA is essential to cell proliferation, apoptosis, differentiation, and migration. Here, we show the effect of CrbpI loss on mammary atRA homeostasis using the Rbp1(-/-) mouse model. Rbp1(-/-) mouse mammary tissue has disrupted retinoid homeostasis that results in 40% depleted endogenous atRA. CrbpI loss and atRA depletion precede defects in atRA biosynthesis enzyme expression. Compensation by CrbpIII as a retinoid chaperone does not functionally replace CrbpI. Mammary subcellular fractions isolated from Rbp1(-/-) mice have altered retinol dehydrogenase/reductase (Rdh) enzyme activity that results in 24-42% less atRA production. Rbp1(-/-) mammary tissue has epithelial hyperplasia, stromal hypercellularity, increased collagen, and increased oxidative stress characteristic of atRA deficiency and early tissue dysfunction that precedes tumor formation. Consistent with the findings from the Rbp1(-/-) mouse, tumorigenic epithelial cells lacking CrbpI expression produce 51% less atRA. Together, these data show that CrbpI loss disrupts atRA homeostasis in mammary tissue, resulting in microenvironmental defects similar to those observed at the early stages of tumorigenesis.

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Distinct differences in the nanoscale behaviors of the twist–bend liquid crystal phase of a flexible linear trimer and homologous dimer

Tuchband

Paterson

Salamończyk

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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We synthesized the liquid crystal dimer and trimer members of a series of flexible linear oligomers and characterized their microscopic and nanoscopic properties using resonant soft X-ray scattering and a number of other experimental techniques. On the microscopic scale, the twist–bend phases of the dimer and trimer appear essentially identical. However, while the liquid crystal dimer exhibits a temperature-dependent variation of its twist–bend helical pitch varying from 100 to 170 Å on heating, the trimer exhibits an essentially temperature-independent pitch of 66 Å, significantly shorter than those reported for other twist–bend forming materials in the literature. We attribute this to a specific combination of intrinsic conformational bend of the trimer molecules and a sterically favorable intercalation of the trimers over a commensurate fraction (two-thirds) of the molecular length. We develop a geometric model of the twist–bend phase for these materials with the molecules arranging into helical chain structures, and we fully determine their respective geometric parameters.

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Preferred crystallographic orientation of cellulose in plant primary cell walls

Rongpipi

Kiemle

et al. 2020

Nat Commun

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Cellulose, the most abundant biopolymer on earth, is a versatile, energy rich material found in the cell walls of plants, bacteria, algae, and tunicates. It is well established that cellulose is crystalline, although the orientational order of cellulose crystallites normal to the plane of the cell wall has not been characterized. A preferred orientational alignment of cellulose crystals could be an important determinant of the mechanical properties of the cell wall and of cellulose-cellulose and cellulose-matrix interactions. Here, the crystalline structures of cellulose in primary cell walls of onion (Allium cepa), the model eudicot Arabidopsis (Arabidopsis thaliana), and moss (Physcomitrella patens) were examined through grazing incidence wide angle X-ray scattering (GIWAXS). We find that GIWAXS can decouple diffraction from cellulose and epicuticular wax crystals in cell walls. Pole figures constructed from a combination of GIWAXS and X-ray rocking scans reveal that cellulose crystals have a preferred crystallographic orientation with the (200) and (110)/($$1\bar 10$$ 1 1 ¯ 0 ) planes preferentially stacked parallel to the cell wall. This orientational ordering of cellulose crystals, termed texturing in materials science, represents a previously unreported measure of cellulose organization and contradicts the predominant hypothesis of twisting of microfibrils in plant primary cell walls.

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Novel color center platforms enabling fundamental scientific discovery

Norman

Majety

Wang

et al. 2020

InfoMat

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Color centers are versatile systems that generate quantum light, sense magnetic fields and produce spin‐photon entanglement. We review how these properties have pushed the limits of fundamental knowledge in a variety of scientific disciplines, from rejecting local‐realistic theories to sensing superconducting phase transitions. In the light of recent progress in material processing and device fabrication, we identify new opportunities for interdisciplinary fundamental discoveries in physics and geochemistry.

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Victoria Norman

A Highly Crystalline Fused‐Ring n‐Type Small Molecule for Non‐Fullerene Acceptor Based Organic Solar Cells and Field‐Effect Transistors

CrbpI regulates mammary retinoic acid homeostasis and the mammary microenvironment

Distinct differences in the nanoscale behaviors of the twist–bend liquid crystal phase of a flexible linear trimer and homologous dimer

Preferred crystallographic orientation of cellulose in plant primary cell walls

Novel color center platforms enabling fundamental scientific discovery

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