182 research outputs found
Terahertz-driven, all-optical electron gun
Ultrashort electron beams with narrow energy spread, high charge, and low
jitter are essential for resolving phase transitions in metals, semiconductors,
and molecular crystals. These semirelativistic beams, produced by
phototriggered electron guns, are also injected into accelerators for x-ray
light sources. The achievable resolution of these time-resolved electron
diffraction or x-ray experiments has been hindered by surface field and timing
jitter limitations in conventional RF guns, which thus far are <200 MV/m and
>96 fs, respectively. A gun driven by optically-generated single-cycle THz
pulses provides a practical solution to enable not only GV/m surface fields but
also absolute timing stability, since the pulses are generated by the same
laser as the phototrigger. Here, we demonstrate an all-optical THz gun yielding
peak electron energies approaching 1 keV, accelerated by 300 MV/m THz fields in
a novel micron-scale waveguide structure. We also achieve quasimonoenergetic,
sub-keV bunches with 32 fC of charge, which can already be used for
time-resolved low-energy electron diffraction. Such ultracompact, easy to
implement guns driven by intrinsically synchronized THz pulses that are pumped
by an amplified arm of the already present photoinjector laser provide a new
tool with potential to transform accelerator based science.Comment: 24 pages, 9 figure
Genetic variability of the neogregarine apicystis bombi, an etiological agent of an emergent bumblebee disease
The worldwide spread of diseases is considered a major threat to biodiversity and a possible driver of the decline of pollinator populations, particularly when novel species or strains of parasites emerge. Previous studies have suggested that populations of introduced European honeybee (Apis mellifera) and bumblebee species (Bombus terrestris and Bombus ruderatus) in Argentina share the neogregarine parasite Apicystis bombi with the native bumblebee (Bombus dahlbomii). In this study we investigated whether A. bombi is acting as an emergent parasite in the non-native populations. Specifically, we asked whether A. bombi, recently identified in Argentina, was introduced by European, non-native bees. Using ITS1 and ITS2 to assess the parasite's intraspecific genetic variation in bees from Argentina and Europe, we found a largely unstructured parasite population, with only 15% of the genetic variation being explained by geographic location. The most abundant haplotype in Argentina (found in all 9 specimens of non-native species) was identical to the most abundant haplotype in Europe (found in 6 out of 8 specimens). Similarly, there was no evidence of structuring by host species, with this factor explaining only 17% of the genetic variation. Interestingly, parasites in native Bombus ephippiatus from Mexico were genetically distant from the Argentine and European samples, suggesting that sufficient variability does exist in the ITS region to identify continent-level genetic structure in the parasite. Thus, the data suggest that A. bombi from Argentina and Europe share a common, relatively recent origin. Although our data did not provide information on the direction of transfer, the absence of genetic structure across space and host species suggests that A. bombi may be acting as an emergent infectious disease across bee taxa and continents
Identifying a Window of Vulnerability during Fetal Development in a Maternal Iron Restriction Model
It is well acknowledged from observations in humans that iron deficiency during pregnancy can be associated with a number of developmental problems in the newborn and developing child. Due to the obvious limitations of human studies, the stage during gestation at which maternal iron deficiency causes an apparent impairment in the offspring remains elusive. In order to begin to understand the time window(s) during pregnancy that is/are especially susceptible to suboptimal iron levels, which may result in negative effects on the development of the fetus, we developed a rat model in which we were able to manipulate and monitor the dietary iron intake during specific stages of pregnancy and analyzed the developing fetuses. We established four different dietary-feeding protocols that were designed to render the fetuses iron deficient at different gestational stages. Based on a functional analysis that employed Auditory Brainstem Response measurements, we found that maternal iron restriction initiated prior to conception and during the first trimester were associated with profound changes in the developing fetus compared to iron restriction initiated later in pregnancy. We also showed that the presence of iron deficiency anemia, low body weight, and changes in core body temperature were not defining factors in the establishment of neural impairment in the rodent offspring
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