![lighttable vs atom lighttable vs atom](https://periodic-table.org/wp-content/uploads/2019/05/Spectrum-of-Radiation.jpg)
This often comes as a surprise to people, but I honestly don't like to program very much - it just happens to be the only way to create the things I want. You've heard us mention "Aurora" a number of times now and I think that's the best description for this crowd of what we're out to accomplish programming designed for humans. That is what I think will end up being the ultimate legacy of Light Table - a version of programming that is meaningfully designed for humans. It's going to take a different way of thinking about the problem. The truth is that I think we can do orders of magnitude better and I have some evidence of that already, but it's going to take more than a new tool. From the outset, our goal has been to make programming better and I've honestly come to the conclusion that LT on its own can't do that. The main value of LT isn't about being a better standard editor, it's taking that editor and making it do things that standard ones can't do. The mailing list isn't public, so here's the post (some parts snipped ):ĭepending on how things play out, it might make sense to try and merge. By "puttering out" I am referring to a mailing list post by the LightTable author. Doing an end-run around atom/LightTable by embedding neovim inside a webkit document, or embedding webkit inside emacs, makes more sense than losing the existing ecosystem of plugins and familiarity. To that end, neovim is showing great promise, and emacs' transition to guile will remove baggage and improve performance.
#Lighttable vs atom code#
There's a massive wealth of community familiarity and code to be tapped, and instead of throwing it all out and using the latest hot technology stack, you gain a lot of leverage by making a 10% effort to modify those existing tools (vim, emacs, Java, unix. There's so much institutional knowledge and legacy code/plugins that ends up being really important-for the same reason Java continues to be important, with its existing libraries. The findings may bring us closer to the ultimate goal of first-principles material design.After seeing LightTable putter out, I'm pretty convinced that nothing is going to replace vim/emacs in the next decade or more. The methods developed in this thesis could be expanded to other classes of materials, including ternary hydrides and other light binaries, and used as a guide to designing high-throughput workflows for other material properties. Incorporating this screening step into a high-throughput workflow allows us to study superconductivity in binary hydrides from across the whole periodic table, resulting in one of the most comprehensive studies of superconductivity in binary hydrides ever produced and leading to the identification of several above- and near-room-temperature candidates. The work presented in this thesis provides a solution to this problem by identifying physically motivated descriptors from scattering theory and density of states calculations, we are able to construct a model for Tc and therefore obtain a method for cheaply identifying the most promising candidate structures.
![lighttable vs atom lighttable vs atom](https://www.evolvingsciences.com/wpimages/wp2c214432_06.png)
This drastically slows down the rate of discovery. It is common for papers in this field to focus on the stability and superconductivity of a limited number of metal hydrides, largely because the electron-phonon calculations involved are computationally expensive and because it is not clear which hydrides are potential high-Tc candidates before performing these calculations. It also addresses the real need to reduce the operational pressure of superconducting hydrides and offers a solution through the use of machine learning methods, leading to the discovery of several superconductors inhabiting favourable regions of P-Tc space. It showcases the calculation of an anharmonic phase diagram of solid hydrogen, demonstrates that current theoretical techniques can produce structures and superconducting critical temperatures (Tc) in agreement with experiment for the record-holding binary hydride LaH10, and reveals a metastable hexagonal phase of this material that provides an explanation for recent experimental observations. This thesis adds to the knowledge of these high-pressure light-atom systems and introduces new tools for predicting their superconducting properties. One of the most sought after phenomena of recent years is high-temperature superconductivity, which has been predicted in solid hydrogen and experimentally verified in numerous metal hydrides. The use of high pressure in physics provides access to unusual chemistry, rich phase behaviour, and various interesting phenomena.