Surfer determines the orientation of each grid cell and calculates reflectance of a point light source on the grid surface. Colors are assigned predicated on slope orientation relative to a light source. Shaded mitigation maps are raster images predicated on grid files. Each anchor point can be assigned a unique color, and the colors are automatically coalesced between adjacent anchor points. You can integrate color anchors at any percentage point between 0 and 100. Surfer automatically blends colors between percentage values so you culminate up with a smooth color gradation over the entire map. Surfer image maps use different colors to represent elevations of a grid file. Overlay several surface maps to engender informative block diagrams. Transmute the lighting, exhibit angle and tilt with a click of the mouse. The 3D surface map uses shading and color to accentuate your data features. You can accept the Surfer perspicacious defaults to automatically engender a contour map, or double-click a map to facilely customize map features.
Surfer contour maps give you full control over all map parameters. Engendering publication quality maps has never been more expeditious or more facile. Virtually all aspects of your maps can be customized to engender precisely the presentation you optate. Integrate base maps and cumulate map types to engender the most informative exhibit possible. Exhibit your grid as outstanding contour, 3D surface, 3D wireframe, watershed, vector, image, shaded assuagement, and post maps. You can additionally use grid files obtained from other sources, such as USGS DEM files or ESRI grid files.
Surfer provides more gridding methods and more control over gridding parameters, including customized variograms, than any other software package on the market. Surfer’s sophisticated interpolation engine transforms your XYZ data into publication-quality maps. Surfer is utilized extensively for terrain modeling, bathymetric modeling, landscape visualization, surface analysis, contour mapping, watershed and 3D surface mapping, gridding as well as volumetrics. Surfer comes packing a full-function 3D visualization, contouring and surface modeling package that runs under Microsoft Windows.
Read more about how to correctly acknowledge RSC content. Permission is not required) please go to the Copyright If you want to reproduce the wholeĪrticle in a third-party commercial publication (excluding your thesis/dissertation for which If you are the author of this article, you do not need to request permission to reproduce figuresĪnd diagrams provided correct acknowledgement is given. Provided correct acknowledgement is given. If you are an author contributing to an RSC publication, you do not need to request permission Please go to the Copyright Clearance Center request page. To request permission to reproduce material from this article in a commercial publication, Provided that the correct acknowledgement is given and it is not used for commercial purposes. This article in other publications, without requesting further permission from the RSC, Kou,Ĭreative Commons Attribution-NonCommercial 3.0 Unported Licence. Investigation of the solid–liquid ternary phase diagrams of 2HNIW HMX cocrystal could be prepared by the isothermal slurry conversion crystallization method.By properly selecting the ratios, the 2HNIW The results show that the choice of solvent has a crucial influence on the dissolution behavior of the cocrystal and the size and position of each region in the phase diagram, while the temperature has no apparent effect on the overall appearance of the phase diagram. The cocrystal exhibits a wider thermodynamically stable region in the HMX–HNIW–ethyl acetate system. HMX cocrystal has a narrow thermodynamically stable region at both temperatures.
In the HMX–HNIW–acetonitrile system, the 2HNIW HMX and HNIW showed inconsistent dissolution behavior and congruent dissolution behavior in acetonitrile and ethyl acetate, respectively. HMX cocrystal in acetonitrile and ethyl acetate at 15 ☌ and 25 ☌.Ternary phase diagrams were constructed for the 2HNIW The influence of temperature and solvent on the solid–liquid ternary phase diagrams of the 2HNIW