MG2C:a user-friendly online tool for drawing genetic maps

Genetic map is a linear arrangement of the relative positions of sites in the chromosome or genome based on the recombination frequency between genetic markers.It is the important basis for genetic analysis.Several kinds of software have been designed for genetic mapping,but all these tools require users to write or edit code,making it time-costing and difficult for researchers without programming skills to handle with.Here,MG2C,a new online tool was designed,based on PERL and SVG languages.Users can get a standard genetic map,only by providing the location of genes(or quantitative trait loci)and the length of the chromosome,without writing additional code.The operation interface of MG2C contains three sections:data input,data output and parameters.There are 33 attribute parameters in MG2C,which are further divided into 8 modules.Values of the parameters can be changed according to the users’requirements.The information submitted by users will be transformed into the genetic map in SVG file,which can be further modified by other image processing tools.MG2C is a user-friendly and time-saving online tool for drawing genetic maps,especially for those without programming skills.The tool has been running smoothly since 2015,and updated to version 2.1.It significantly lowers the technical barriers for the users,and provides great convenience for the researchers.

Simulation study of the dose and energy responses of FNTD personal neutron dosimetry

The objective of this work was to use the Geant4 toolkit to perform simulation studies on the personal dose response of fluorescent nuclear track detectors(FNTDs).The entire structure of the FNTD response can be designed,and the detector's energy and dose responses can be optimized in a broad energy range(0.01 eV-20 MeV). In general, the detectors used ~6LiF and CH_2 converters that have high energy and high dose response at neutron energies lower than 10 eV and greater than 1 MeV, respectively. The method of least squares was used to optimize the dose response of H*(10) and the energy response corresponding to Rtotal. The values of the optimized response of H*(10) lie between 0.8 and 1.4, corresponding to the energy ranges 0.01 eV-70 keV and 4-14 MeV, respectively. This occupies nearly eight out of the nine orders of the total energy range. Even though the optimized response of Rtotal is constrained between 0.89 and 1.1 in the energy range of 0.01 eV-20 MeV, it is suitable for obtaining the broad neutron spectrum of fluence with good accuracy.

Synthesis and electrochemical performance of Li_2Mg_(0.15)Mn_(0.4)Co_(0.45)SiO_4/C cathode material for lithium ion batteries

The synthesis, structure and performance of Li2Mg0.15Mn0.4Co0.45SiO4/C cathode material were studied. The Li2Mg0.15Mn0.4Co0.45SiO4/C solid solution with orthorhombic unit cell （space group Pmn21） was synthesized successfully by combination of wet process and solid-state reaction at high temperature, and its electrochemical performance was investigated primarily. Li2Mg0.15Mn0.4Co0.45SiO4/C composite materials deliver a charge capacity of 302 mA-h/g and a discharge capacity of 171 mA.h/g in the first cycle. The discharge capacity is stabilized at about 100 mA-h/g after 10 cycles at a current density of 10 mA/g in the voltage of 1.5-4.8 V vs Li/Li^＋. The results show that Mg-substitution for the Co ions in Li2Mn0.4Co0.6SiO4 improves the stabilization of initial structure and the electrochemical nerformance.