Anisotropic Subdiffractive Solitons

We study solitons in the two-dimensional defocusing nonlinear Schroedinger equation with the spatio-temporal modulation of the external potential. The spatial modulation is due to a square lattice; the resulting macroscopic diffraction is rotationally symmetric in the long-wavelength limit but becomes anisotropic for shorter wavelengths. Anisotropic solitons -- solitons with the square (x,y)-geometry -- are obtained both in the original nonlinear Schroedinger model and in its averaged amplitude equation

Histidine-Mediated Nickel and Zinc Translocation in Intact Plants of the Hyperaccumulator Noccaea caerulescens

In this work, the effect of exogenous histidine supply on zinc (Zn) and nickel (Ni) translocation to the shoots in intact plants of the hyperaccumulator Noccaea caerulescens F.K. Mey was studied. Three series of experiments were carried out. (1) Intact N. caerulescens plants (St-Félix-de-Pallières population) were pretreated for 4 h (12:00 till 16:00) with a MES/KOH-buffered 1 mM L-histidine solution or demineralized water, then exposed overnight (20 h) to 5, 25 or 250 µM Ni or Zn and harvested. (2) Intact N. caerulescens plants of the same population were pretreated with 1 mM L-histidine solution or demineralized water overnight (20 h) and then exposed to 250 µM Ni or Zn for 8 h during the day (10:00 till 18:00) and harvested. (3) Intact N. caerulescens plants (the calamine populations St-Félix-de-Pallières (SF) and La Calamine (LC), and the ultramafic population Monte Prinzera (MP)) were exposed for 8 h (10:00 till 18:00) to 250 µM Ni or Zn and then to 1 mM L-histidine solution or demineralized water overnight (20 h) and harvested. The Ni and Zn concentrations in the roots and shoots were determined by atomic absorption spectrophotometry. The translocation factor (TF), expressed as the shoot to root metal concentration ratio, the total plant Ni or Zn content, and the percentage of the total Ni or Zn content present in the shoot (% translocated) were calculated. A 4 h pretreatment with L-histidine during the afternoon (before metal exposure overnight) significantly decreased the Ni and Zn concentrations in the root and increased the concentration of Ni, but not of Zn, in the shoot, significantly increased both TF and the % translocated for both metals, albeit much more strongly for Ni, and also slightly, but significantly, increased the total plant content of Ni, but not of Zn. Overnight pretreatment with L-histidine (followed by metal exposure during the day) of the same population (SF) had basically similar effects on Ni translocation, but significantly decreased the plant total Ni content, and was without significant effects on Zn translocation, but considerably decreased the root Zn concentration. The different populations under study (SF, MP, LC) showed significant differences in their Ni and Zn uptake and translocation capacities, but in general showed qualitatively similar responses to post-treatment with L‑histidine that strongly increased the TF and the % translocated for both metals in SF and MP, whereas in LC the effect was prominent only for Ni. Significant population × histidine treatment effect interactions were obtained for the root Zn concentration, and the TF and % translocated for Ni, which were largely explained by a relatively low responsiveness to the L-histidine treatment in LC, compared to SF and/or MP. It is concluded that the high endogenous L-histidine concentrations in N. caerulescens are probably functional in the hyperaccumulation of both Ni and Zn. The overall stronger effect of exogenous L-histidine supply on the translocation of Ni, compared to Zn, seems to result, at least in part, from the high Zn burdens at the start of the treatments, particularly in the shoots, which largely mask the apparent effects of exogenous L-histidine supply on the shoot Zn concentration and, to a lower degree, the % Zn translocated

Sampling of a driving cycle for e-trucks with a mechatronic transmission

Traction battery vehicles (TBV) are currently gaining more and more popularity and are gradually replacing vehicles with ICE and traditional transmissions. The usage of an electric traction drive as part of TBV solves a number of problems that manufacturers of this type of equipment face today: reducing harmful emissions into the atmosphere, reducing noise, used lubricants recycling, and the increase of the energy efficiency. From the point of view of the scientific research, this type of wheeled vehicles is also of high interest due to the large number of problems and tasks that have formed at the moment. It is a common knowledge, that one of the main problematic issues for the TBV is a rather limited range. In cargo electric vehicles and buses, in order to reduce the size and increase the usable volume of the passenger compartment or cargo space, as well as to unify the products of the power unit and drive, there are used the transmissions, which are the combination of mechanical and electrical components with appropriate control systems. The mechanical component includes a gearbox with one or more gear ratios, an inter-wheel differential, axle shafts, bearings and other components. The electrical component is a traction motor located directly in the drive axle (integrated) or on the outside of the crankcase, as well as a voltage converter with a control system and the necessary switching elements. Similar implementations of the driving axles of vehicles with traction batteries are called mechatronic transmissions