<div dir="ltr"><br>Thank you very much Vladimir,<br><div><br></div><div>1) I know CP2K is not a choice for small molecules. But I am investigating an organic reaction which could take place in gas phase and on C3N4 surface. I have to compare the data between the gas phase and the surface. So, I can’t use gaussian or orca to that. DMol3 or CASTEP maybe is best choice for me, but I think we should give open source software a chance. So, CP2K is my choice right now. I am not very familiar with CP2K that it’s why I go to this forum and ask for some help. </div><br>2) Agree. <br><br>3) Yes, it was. <br><br>4) 10000 times is an exaggeration, I apologize for that. Form the same initial structure, it took gaussian 41 seconds with a single Xeon 2680v2 CPU to finish the geometry optimization, but it took CP2k 40 minutes with 20 CPU to do the same thing. If we include the frequencies calculation the time is 4 minutes vs 71 minutesX20CPU. A single SCF calculation of CP2K was pretty fast, but most of time was wasting in locating the minimize. <br>This efficiency issue only happened in this 1-butene molecular. Another molecular I tested, cyclobutene, seemed much batter than 1-butene. <br><br>I attach all the input and the output file. So, you guy can help me to improve this. Thanks all.<br><br><br>Best,<br>LInfeng<br><br><br>On Friday, May 15, 2020 at 7:41:12 PM UTC+8, Vladimir Rybkin wrote:<blockquote class="gmail_quote" style="margin: 0;margin-left: 0.8ex;border-left: 1px #ccc solid;padding-left: 1ex;"><div dir="ltr">Dear Linfeng,<div><br></div><div>a few general remarks:</div><div>1) CP2K is not the most efficient tool for small molecules. For instance, it does a lot of integrations over cells in real and reciprocal space, and for a small molecule the cell is almost everywhere empty.</div><div>2) CP2K does not use internal coordinates for optimisation. This has to do with the fact that it's mostly meant for large periodic systems. Gaussians' Berny algorithm does use internal coordinates and is very efficient for small systems.</div><div>3) It's very likely that you 150 steps have not change the geometry significantly. </div><div>4) It's not completely clear where this 10000 times come from. It may have to do with how you compile and run your applications.</div><div><br></div><div>That said, there's no specific problems with optimisers and efficiency. It's about applicability of tools for specific purposes. If you going to work with small molecules, you'd better stick to programs made for them, i.e. Gaussian. CP2K is meant for large and/or periodic systems.</div><div><br></div><div>Yours,</div><div><br></div><div>Vladimir<br><br>пятница, 15 мая 2020 г., 2:51:51 UTC+2 пользователь Linfeng Gan написал:<blockquote class="gmail_quote" style="margin:0;margin-left:0.8ex;border-left:1px #ccc solid;padding-left:1ex"><div dir="ltr">
<p class="MsoNormal"><span lang="EN-US">Hi all,</span></p>
<p class="MsoNormal"><span lang="EN-US">When I optimized 1-butene molecular at
B3lYP/6-311G** level, it took much much longer than gaussian16 did. <span> </span>I had test optimizer CG, BDGS and LBFGD,
nothing better. It seems the optimizers have some efficiency issues. All three
optimizer had taken at least 150 optimization steps to get the final structure,
but the initial structure had been optimized by gaussian. <span> </span><span> </span>How
could I improve that?</span></p>
<p class="MsoNormal"><span lang="EN-US"> </span></p>
<p class="MsoNormal"><span lang="EN-US">Best</span></p>
<p class="MsoNormal"><span lang="EN-US">Linfeng</span></p>
</div></blockquote></div></div></blockquote></div>