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Ê×ÏȽéÉܲο¼Îĵµ ftp://10.76.120.7/pub/Èí¼þʹÓýéÉÜ/VASP.pdf http://cms.mpi.univie.ac.at/vasp/vasp/vasp.html VASP = Vienna Ab-initio Simulation Package VASP is a complex package for performing ab-initio quantum-mechanical molecular dynamics (MD) simulations using pseudopotentials (È糬ÈíØÍÊÆUS-PP) or the projector-augmented wave (PAW) method and a plane wave basis set. The approach implemented in VASP is based on the (finite-temperature) local-density approximation with the free energy as variational quantity and an exact evaluation of the instantaneous electronic ground state at each MD time step. ËüµÄºÃ´¦Ö÷Òª°üÀ¨ »ù×éСÊÊÓÚµÚÒ»ÐÐÔªËغ͹ý¶É½ðÊô£¬ ´óÌåϵ¼ÆËã¿ì(<4000¼Ûµç×Ó)£¬ ÊÊÓÚƽÐмÆËã(Unix/Linux) ÆäËûÌØÐÔ»¹°üÀ¨×Ô¶¯¶Ô³ÆÐÔ·ÖÎö¡¢¼ÓËÙÊÕÁ²Ëã·¨ÁíÎÄÉæ¼°¡£ Ò»¸ö¼òµ¥µÄVASP×÷ÒµÖ÷ÒªÉæ¼°ËĸöÊäÈëÎļþ£º INCAR(×÷ҵϸ½Ú) POSCAR(Ìåϵ×ø±ê) POTCAR(ØÍÊÆ) KPONITS(k¿Õ¼äÃèÊö) [ Last edited by wuli8 on 2009-6-13 at 21:28 ] |
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15Â¥2008-10-09 08:47:16
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±¾Îļòµ¥½éÉܵãÄÜ´øÀíÂ۵Ļù´¡ÖªÊ¶ ÒÔÀûÓÚºóÎÄÌÖÂÛ ²¼ÀïºÕ(F.Bloch) ²Î¿¼Ê飺¡¶¹ÌÌåÄÜ´øÀíÂÛ¡·Ð»Ï£µÂ ½¶° Ö÷±à Bloch¶¨Àí ÖÜÆÚÐÔÊƳ¡µÄµ¥µç×ÓѦ¶¨ÚÌ·½³ÌµÄ·Ç¼ò²¢½âºÍÊʵ±Ñ¡Ôñ×éºÏϵÊýµÄ¼ò²¢½âͬʱ ÊÇƽÒÆËã·ûT(Rl)µÄÊôÓÚ±¾Õ÷Öµexp(ik¡¤Rl)µÄ±¾Õ÷º¯Êý Êýѧ±íʾ£º T(Rl)¦×n(k£¬r) = ¦×n(k£¬r+Rl) = exp(ik¡¤Rl)¡¤¦×n(k£¬r) ¦×n(k£¬r)³ÆΪBlochº¯Êý£¬ÓÃËüÃèдµÄµç×ÓÒ²³ÆΪ²¼ÀïºÕµç×Ó ÍÆÂÛÒ»£º ¾§¸ñµç×Ó¿ÉÓÃͨ¹ý¾§¸ñÖÜÆÚÐÔµ÷·ùµÄƽÃ沨±íʾ¡£ÓÉ´ËÎÒÃÇÖªµÀkµÄÎïÀíÒâÒå ²¨Ê¸ ÍÆÂÛ¶þ£º ÈôKm¡¤Rl = 2n¦Ð£¬¼´KmΪµ¹¸ñʸ£¬ÄÇô ¦×n(k£¬r) = ¦×n(k+Km£¬r) ËùÒÔÎÒÃǽ«kÖµÏÞ¶¨ÔÚÒ»¸ö°üÀ¨ËùÓв»µÈ¼ÛkµÄÇøÓòÇó½âѦ¶¨ÚÌ·½³Ì£¬Õâ¸öÇøÓò³ÆΪ ²¼ÀïÔ¨Çø(Brillouin£¬Ã»´í£¬¾ÍÊÇÁ¿»¯¿ÎÉÏCI·½·¨ÖÐ×îÖØÒªµÄ»ùʯBrillouin¶¨ÀíµÄÄÇλ )ÔÚ²¼ÀïÔ¨Çø£¬¶ÔÓÚÿ¸ön,En(k)ÊÇÒ»¸ökµÄÁ¬Ðø¡¢¿ÉÇø·Ö(·Ç¼ò²¢Çé¿ö)µÄº¯Êý£¬³ÆΪÄÜ´ø £¬ËùÓеÄÄÜ´ø³ÆΪÄÜ´ø½á¹¹¡£ ok ÄÇôʵ¼ÊÉÏVASPµÄ¼ÆËã¾ÍÊÇÀûÓÃÒÔÉ϶¨Àí£¬Í¨¹ýTËã·ûµÄ±ä»»£¬½«Êµ¿Õ¼ä(r¿Õ¼ä)ºÍ¶¯ Á¿¿Õ¼ä(k¿Õ¼ä)ÁªÏµÆðÀ´£¬ÀûÓþ§¸ñµÄÖÜÆÚÐÔ¼ò»¯¼ÆË㣬ËùÒÔÔÚºóÃæµÄÌÖÂÛÖн«³£³öÏÖ band,k-points,projectors in real spaceµÈ¸ÅÄî¡£ [ Last edited by zzgyb on 2008-1-27 at 14:39 ] |
2Â¥2008-01-27 14:37:26
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POSCAR = position + CAR µÚ1ÐУºÈÎÒâÎÄ×Ö×¢ÊÍ µÚ2ÐУº¾§¸ñ³£Êý£¬µ¥Î»A£¬ºóÃæËùÓеij¤¶ÈÖµµÃ×ÔÔÖµ³ýÒÔ´ËÖµ a=b=cʱȡa¼´¿É£¬·ñÔò¸öÈËÏ°¹ßÈ¡ÈýÕß×î´ó ÈôÈ¡¸ºÖµ£¬ÔòΪ¾§°ûÌå»ý£¬µ¥Î»A3 µÚ3-5ÐУº¶¨Ò徧ʸ ²Î¼û¡¶¹ÌÌåÁ¿×Ó»¯Ñ§¡ª¡ª²ÄÁÏ»¯Ñ§µÄÀíÂÛ»ù´¡¡·ÕԳɴó Èç ¶ÔÓÚÕý½»¾§Ìå a=20.022 b=19.899 c=13.383 ¦Á=¦Â=¦Ã=90 ¿ÉÒÔÕâÑù¶¨Òå 20.022 1.00000 0.00000 0.00000 0.00000 0.99386 0.00000 0.00000 0.00000 0.66841 ÓÖÈç ¶ÔÓÚÃæÐÄÁ¢·½¾§Ìå a=b=c=3.57 ¦Á=¦Â=¦Ã=90 ¿ÉÒÔ¶¨ÒåÈçÏ 3.57 0.0 0.5 0.5 (1/2(b+c)) 0.5 0.0 0.5 (1/2(a+c)) 0.5 0.5 0.0 (1/2(a+b)) µÚ6ÐУºÃ¿ÖÖÔªËصÄÔ×ÓÊý£¬Ìرð×¢Òâ˳Ðò,ÒªÓëÏÂÃæµÄ×ø±ê˳ÐòÒÔ¼°POTCARÖÐ µÄ˳ÐòÒ»Ö µÚ7ÐУº¿ÉÊ¡ÂÔ£¬ÎÞÐè¿ÕÐС£ ×ö¶¯Á¦Ñ§Ê±£¬ÊÇ·ñÐèÒª¹Ì¶¨²¿·ÖÀë×ÓµÄ×ø±ê¡£ÈôÊÇ£¬´ËÐÐÒÔ'S'»òÕß's'Ê××Ö¼´¿É¡£ µÚ8ÐпªÊ¼ÎªÀë×ÓµÄ×ø±ê£¬¸ñʽΪ option line coordinate1 of element1 coordinate2 of element1 ... coordinateN of element1 option line coordinate1 of element2 coordinate2 of element2 ... coordinateM of element2 ... ÆäÖУ¬option lineÖ¸¶¨ÊäÈë×ø±êµÄ¸ñʽ£¬³ýÁ˵ÚÒ»¸öÒÔÍ⣬Èç¹ûºóÃæµÄÊäÈë¸ñʽͬǰ£¬ Ôò¶¼¿ÉÒÔÎÞ¿ÕÐÐÊ¡ÂÔ¡£ option line¿ÉÖ¸¶¨µÄÊäÈë×ø±ê¸ñʽÓÐÁ½ÖÖ 'D'or'd' for direct mode 'C'or'c'or'K'or'k' for cartesian mode ¹ËÃû˼Ò壬ǰÕßÊǶ¨ÒåÔÚÈý¸ö¾§Ê¸·½ÏòÉϵÄ×ø±ê R=R1¡Áx+R2¡Áy+R3¡Áz R1,R2,R3ΪǰÃæµÄ¾§Ê¸£¬x,y,zΪÊäÈëµÄÈý¸ö×ø±ê£¬RΪ×ø±êλʸ ¶øºóÕßÖ»ÊǼòµ¥µÄ½«Ö±½Ç×ø±ê³ýÒÔÇ°ÃæµÚ¶þÐж¨ÒåµÄ¾§°û³£Êý Á½Õß¿ÉÒÔ»ìÓ㬵«²»ÍƼö¡£ Èç¹ûµÚ7ÐÐÉ趨ÁËS(Selective Dynamic),Ôò¿ÉÒÔÓÃÒÔÏÂÐÎʽ¶¨Òå¸÷×ø±êÊÇ·ñ¿ÉÒÔÒƶ¯ Selective dynamics Cartesian 0.00 0.00 0.00 T T F 0.25 0.25 0.25 F F F [ Last edited by zzgyb on 2008-1-27 at 14:40 ] |
3Â¥2008-01-27 14:37:44
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- Ó¦Öú: 0 (Ó׶ùÔ°)
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ÈçÇ°ËùÊö The Bloch theorem changes the problem of calculating an infinite number of electronic wavefucntions to one of calculating a finite number of wavefunctions at an infinite number of k-points. (²Î¼ûCASTEPµÄ°ïÖúÎĵµ£¬ËûºÍ VASPÊÇÇ×ÐÖµÜ)¡£ ËùÒÔÄØ£¬Ò»°ãÀ´Ëµ£¬kµãÔ½ÃÜÔ½¶à£¬¼ÆË㾫¶ÈÒ²Ô½¸ß£¬µ±È»¼ÆËã³É±¾Ò²Ô½¸ß¡£ àÅ£¬¶ÔÓÚkµãµÄÐèÇ󣬽ðÊô>>°ëµ¼Ì壬¾øÔµÌ壬²»¹ýÄØ£¬ºÜ¶àʱºòÖ÷Òª»¹ÊÇÊÜÓ²¼þÏÞÖÆ ¼òÔ¼»¯¿ÉÒÔʹkµãµÄÊýÄ¿´ó´óϽµ¡£¶ÔÓÚÔ×ÓÊý½Ï¶àµÄÌåϵµÄ¼ÆË㣬¾ÍÐèÒª½÷É÷µÄ³¢ÊÔ kµãÊýÄ¿£¬ÔÚ±ÜÃâ»òÕßÔ¤ÏÈÆÀ¹Àwrap-around errorµÄÇ°ÌáϾ¡Á¿¼õÉÙkµãÊýÄ¿¡£ ÁíÒ»¸öÎÊÌâÊÇk¿Õ¼äÍø¸ñ(k-points grid)µÄλÖúÍÐÎ×´£¬ ÊÇ·ñ°üÀ¨§¤µã(Gammaµã£¬Ò²¿ÉÀí½âΪԵã)£¿(Ò»°ã²»°üÀ¨µÄ»°ºÜ¿ÉÄÜ»á´øÀ´Îó²î£¬ÓÈÆä ÊÇʹÓÃÁËtetrahedron·½·¨µÄʱºò¡£ÔÝʱ»¹²»ÖªµÀ²»°üÀ¨µÄºÃ´¦£¬ÎªÁ˼õÉÙkµã£¿) ·½ÐΣ¿ÏßÐΣ¿»¹Êdz¤·½ÐΣ¿»òÕßÆæÐιÖ×´£¿ £º£© ºóÎÄÁíÊö¡£ÄÇôÏÖÔÚÀ´¿´¿´KPOINTS fileµÄ½á¹¹£º Line1: comment line ×¢ÊÍÐÐ no problem Line2: kµã×ÜÊý »òÕß '0'×Ô¶¯Éú³ÉÍø¸ñ(Automatic k-mesh generation) Èç¹ûÊÇÇ°Õߣ¬¸ø³ökµã×ÜÊý£¬ÓÖ·ÖÁ½ÖÖÇé¿ö M.È«ÊÖ¶¯ Entering all k-points explicitly Line3: ÊäÈë¸ñʽ±êʶ¡£Ö±½Ç×ø±ê (Cartesian)»òÕß µ¹¸ñ×ø±ê£¨Reciprocal£© ͬÑùµÄ 'cCkK' for Cartesian£¬ÆäËûÊ××ÖĸÔò×Ô¶¯Çл»µ½ Reciprocal Line4-n: Öð¸ökµãµÄÃèÊö¡£ ¸ñʽΪ x y z W¡£ xyzÊÇÈý¸ö×ø±ê£¬WÊÇȨÖØ¡£ËùÓÐkµãµÄȨ ÖØÏ໥֮¼äµÄ±ÈÀý¶ÔÁ˾ÍÐУ¬VASP»á×Ô¶¯¹éÒ»µÄ ×¢ÒâC×ø±êºÍR×ø±êµÄ¶¨Òå C: k=(2¦Ð/a)(x y z) R: k=x*b1+y*b2+z*b3 b1-3Ϊµ¹¸ñ»ùʸ £¨ÕâÀïÎÒÃÇ¿´µ½xyzÖ»ÊÇ´ú±íÁË×ø±êµÄ˳Ðò£¬Óë×ø±êÖáÎ޹أ© ±ÈÈçһЩ³£Óõĸ߶ԳÆÐÔµãµÄCºÍR×ø±ê£º Point Cartesian coordinates Reciprocal coordinates (units of 2pi/a) (units of b1,b2,b3) ------------------------------------------------------ G ( 0 0 0 ) ( 0 0 0 ) X ( 0 0 1 ) ( 1/2 1/2 0 ) W ( 1/2 0 1 ) ( 1/2 3/4 1/4 ) K ( 3/4 3/4 0 ) ( 3/8 3/8 3/4 ) L ( 1/2 1/2 1/2 ) ( 1/2 1/2 1/2 ) ÊäÈëʾÀý£º Example file 4 Cartesian 0.0 0.0 0.0 1. 0.0 0.0 0.5 1. 0.0 0.5 0.5 2. 0.5 0.5 0.5 4. Ò»°ãÈç·Ç±ØÒª£¬¿ÉÒÔÏÈÓÃ×Ô¶¯Ä£Ê½Éú³Ékµã£¬VASP»á×Ô¶¯Éú³ÉÒ»¸ö¼òÔ¼»¯ºóµÄkµã¾ØÕó£¬ ´æÓÚIBZKPT file£¬¿ÉÒÔÖ±½Ó¸´ÖÆÀïÃæµÄÊý¾Ýµ½KPOINTS fileÀ´Óã¬ÆäʵÕâÒ²ÊÇÕâ¸öÊäÈë ·¨µÄÖ÷ÒªÓÃ;£¬ÎªÁ˼õÉÙÖظ´×Ô¶¯Éú³É¸ñµãµÄʱ¼ä¡£ ÁíÒ»¸öÓÃ;ÊÇΪÁË×ö¾«È·µÄDOS(Density of status)µÄ¼ÆË㣬ÓÉÓÚÕâÀà¼ÆËãËùÐèkµãÊý¼« ´ó£¬Í¨¹ýÈ«ÊÖ¶¯¾¡¿ÉÄܵÄÓÅ»¯kµãÒ²¾Í±ØÐèÁË¡£ L.°ëÊÖ¶¯/ÏßÐÎģʽ Strings of k-points for bandstructure calculations ¿´µ½À²£¬¶ÔÓÚÄÜ´ø½á¹¹µÄ¼ÆË㣬ͬǰÃæµÄÀíÓÉ£¬ÐèÒª¾«È·µÄÑ¡È¡kµã£¬ÔÚÖ¸¶¨µÄ¸ß¶Ô³ÆÐÔ ·½ÏòÉÏÉú³ÉÖ¸¶¨ÊýÄ¿µÄkµã¡£ Line2: Ö¸¶¨Á½µã¼äÉú³ÉµÄkµãÊý ²»Í¬ÓÚÈ«×Ô¶¯µÄ×ÜkµãÊý Line2.5: 'L' for Line-mode ±íʾÊÇÏßÐÎģʽ Line3: ÊäÈë¸ñʽ±êʶ¡£Í¬Ç°¡£C or R Line4-n: ÿÐÐÃèÊöÒ»¸öµã ¸ñʽΪ x y z¡£Ã¿Á½ÐеĵãÁ¬³ÉÒ»Ïߣ¬ÔÚÁ½µã¼äÉú³ÉÖ¸¶¨Êý Ä¿µÄkµã¡£Ã¿Á½ÐÐÁ½ÐÐÖ®¼äÒÔ¿ÕÐÐÇø·Ö£¨²»¿ÕµÄ»°,VASP¿ÉÄÜÒ²Èϵóö£¬Ã»ÊÔ¹ý£© ±ÈÈ磺 10 ! 10 intersections Line-mode rec 0 0 0 ! gamma 0.5 0.5 0 ! X 0.5 0.5 0 ! X 0.5 0.75 0.25 ! W ok£¬ÄÇô¸ü³£Óõķ½·¨ÊÇÈÃVASP×Ô¶¯Éú³ÉÍø¸ñ Line2: 0 £¡number of k-points = 0 ->automatic generation scheme £¨!ºóÃæ×Ö·ûΪעÊÍ£© Line3: A for fully automatic or G for §¤/Gamma or M for Monkhorst-Pack Èô¶¼²»ÊÇÕâЩÊ××Öĸ£¬Ôò×Ô¶¯Çл»Îª¸ß¼¶Ä£Ê½¡£ A mode È«×Ô¶¯Ä£Ê½£¬¿ÉÒÔ¿´×÷ÒÔ§¤µãΪԲÐÄÒÔlΪ°ë¾¶×öÔ²£¬µ±È»¸÷¾§¸ñʸ²»Í¬Ê±£¬Ïà Ó¦µÄÔ²¾ÍÀ³ÉÁËÍÖÔ²£¬À´È·±£Èý¸öµ¹¸ñʸ·½ÏòÉϸ²¸ÇµÄkµãÊýΪl Line4£ºlength (l) Useful values for the length vary between 10 (large gap insulators) and 100 (d-metals). ½øÒ»²½µÄ×ö·¨ÊÇ·Ö±ðÖ¸¶¨Èý¸öµ¹¸ñʸ·½ÏòÉϵĸñµãÊýN1,N2,N3¡£G mode Line4: N1 N2 N3 Line5: s1 s2 s3 Æ«ÒÆÔµãµÄλʸ Ò»°ãÉè³É 0 0 0 À²¡£ ÒÔ¼°Monkhorst-Pack·¨£¬Éú³ÉµÄ¸ñµã²»°üÀ¨§¤µã£¬´Ó§¤µãÖÜΧ1/2³¤¶È´¦¿ªÊ¼È¡µã¡£ M mode Line4: N1 N2 N3 Line5: s1 s2 s3 ͬÉÏ ËùνµÄ¸ß¼¶Ä£Ê½£¬¾ÍÊÇÓÃC×ø±ê»òÕßR×ø±êÖ±½ÓÊäÈëеĻùʸ Èç c c 0.25 0 0 0.25 0 0 0 0.25 0 0 0.25 0 0 0 0.25 0 0 0.25 0.0 0.0 0.0 0.5 0.5 0.5 ·Ö±ðµÈ¼ÛÓÚ g m 4 4 4 4 4 4 0 0 0 0 0 0 ÒòΪ´æÔÚÕâÖֵȼ۹Øϵ£¬ËùÒÔÒ»°ãҲûÓбØҪʹÓø߼¶Ä£Ê½ ºÃÀ²£¬¾ÍÕâЩ¡£×îºóÌáÐÑÒ»µã£¬VASPµÄ°ïÖúÎĵµÌرðÌáÐÑ£¬¶ÔÓÚÁù·½¾§Ïµ£¬²»ÒªÓÃMÀ´×Ô ¶¯Éú³É¸ñµã£¬¶øÒªÓÃG¡£ ¹ØÓÚtetrahedra·½·¨£¬°ïÖúÎĵµËµÓÃÓÚÈ«ÊÖ¶¯Ä£Ê½£¬¿ÉÑ¡¡£¾ßÌåÉ趨ÔÎÄÈçÏ£º In this case, the next line must start with 'T' or 't' signaling that this connection list is supplied. On the next line after this 'control line' one must enter the number of tetrahedra and the volume weight for a single tetrahedron (all tetrahedra must have the same volume). The volume weight is simply the ratio between the tetrahedron volume and the volume of the (total) Brillouin zone. Then a list with the (symmetry degeneration) weight and the four corner points of each tetrahedron follows (four integers which represent the indices to the points in the k-point list given above, 1 corresponds to the first entry in the list). Warning: In contrast to the weighting factors for each k-point you must provide the correct 'volume weight' and (symmetry degeneration) weight for each tetrahedron - no internal renormalization will be done by VASP! ʾÀý£º Example file 4 Cartesian 0.0 0.0 0.0 1. 0.0 0.0 0.5 1. 0.0 0.5 0.5 2. 0.5 0.5 0.5 4. Tetrahedra 1 0.183333333333333 6 1 2 3 4 ¾ßÌåÇë²Î¼û°ïÖúÎĵµ8.4½Ú [ Last edited by zzgyb on 2008-1-27 at 14:41 ] |
4Â¥2008-01-27 14:37:53
