611 likes | 653 Vues
Molecular Devices. Chennai, September 14, 2005. K.L. Sebastian IPC Department, IISc http://ipc.iisc.ernet.in/~kls. Outline. Motivation – examples from biology Molecular Rollers and Rocker Molecular Wheel Molecular Rattle . Fluxionality for Rotational Motion
E N D
Molecular Devices Chennai, September 14, 2005 K.L. Sebastian IPC Department, IISc http://ipc.iisc.ernet.in/~kls
Outline • Motivation – examples from biology • Molecular Rollers and Rocker • Molecular Wheel • Molecular Rattle • . Fluxionality for Rotational Motion • Nature does it very well! (Biological Molecular Motors) • Synthetic Molecular Motors • Light driven molecular motor
Is that a flower? It is a motor Height ~ 8 nm Width ~ 10 n
Seems rather difficult, perhaps we can try to use fluxionality! Can one design molecules that would prefer to roll on a surface? MOLECULAR ROLLER What do you mean?
God! He is crazy!! ConsiderHypostrophene-itis fluxional -perhaps we can use this property! To explain, let us start with Pentaprismane
H hypostrophene pentaprismane Symmetry is broken! It can bebroken inFIVEdifferent ways! Pentaprismane (C10H10) D5h Hypostrophene C2v
Five degenerate minima! It should be possible to jump from one to the other It does! Known asDegenerate Cope Rearrangement
Activation energy B3LYP/6-31G** (kcal/mol) 25.31 GS TS Rate constant Degenerate Cope Rearrangement for Hypostrophene Rate constant ~ 1.8 X 10-5 sec-1 Activation energy Q and Q* are the partition functions of GS and TS
Rolling Motion Rolling-TS Eact ~ 18 kcal/mol Translation-TS: Eact ~ 65.5 kcal/mol
Same thing can happen with syn-TOD! Molecular Roller
Syn-TOD Cubane C2v Td Activation energy B3LYP/6-31G** (kcal/mol) GS 24.25 TS
Activation energy 13.6 kcal/mol (B3LYP/6-31G** C,H and 3-21G for Al) TS
MOLECULAR ROLLERS We conclude that: Hypostrophene and tricyclooctadiene when chemisorbed on Al(100) surface should behave as ‘Molecular roller’ Bidisa Das, K.L Sebastian, Chemical Physics Letters, 330, 433 (2000).
GS GS TS Activation energy B3LYP/6-31G** (kcal/mol) 5.5 Cope Rearrangement of Semibullvalene
MOLECULAR ROCKER Metal surface: cluster of 14 or 32 Al atoms in two layers Hydrogen atoms at the edges. B3LYP/Al:3-21G, C,H:6-31G** Ea = 21.8 kcal/mol
Fluxionality for Rotational Motion Fe(CO)3 Fe(CO)3 Fe(CO)3 Fe(CO)3 moving around hypostrophene
203i cm-1 4.3 kcal/mol 33.6 kcal/mol Hypostrophene
C5H5Ge(CH3)3is known to be fluxional! MOLECULAR WHEEL Eact ~ 16.0 kcal/mol
M atom bonded to Cp and basis-sets used rate constant at 298.15 K (sec-1) Eact (kcal/mol) Si (C,H: 6-31G** & Si: 6-31G**) 14.04 3.2X102 Ge (C,H: 6-31G** & Ge: 6-31G**) 12.21 1.6X103 Sn (C,H: 6-31G** & Sn: 3-21G) 5.74 3.7X108 The activation barriers and rate constants
Cyclopentadienyl adsorbed on Ge surface, should move like awheel! Hopping onto adjacent Ge atoms Adsorbed to the same site! Eact ~ 11.9 kcal/mol
M atom bonded to Cp and basis-sets used Rate constant (sec-1) 298.15 K Eact (kcal/mol) Si (C,H: 6-31G** & Si: 6-31G**) 13.45 8.5X102 Ge (C,H: 6-31G** & Ge: 6-31G**) 11.90 1.9X104 Sn (C,H: 6-31G** & Sn: 3-21G) 5.97 2.5X108
Molecular Wheel Sn That is not bad! Why don’t you call it amolecular “seal”? Ea = 5.97 kcal/mol B. Das and K.L. Sebastian: CPL 357, 25 ( 2002)
We conclude that : The cyclopentadienyl co-adsorbed with hydrogen on Si/Ge/Sn (111) surfaces would form a system where the five membered ring can undergo spinning motion with low activation energies. Bidisa Das, K.L Sebastian, Chemical Physics Letters, 357, 25 (2002).
Molecular Rattle A B B A B A
H+ - Does not happen! Ionization potential of H too large! - H+ Perhaps, in an excited state, this might happen
Li+ Replace H with Li! - - Li+ Ring too small
Eact~42.4 kcal/mol Eact a:315 kcal/mol b:36.6kcal/mol c:33.6kcal/mol These are the molecules that we studied but activation energies for the ‘umbrella inversion’ kind of motion was found to be high. M. Oda, Pure & Appl. Chem. 58, 7 (1986), T.Z. Ktaz, P. A. Garratt, J. Am. Chem. Soc. 85, 2852 (1963).
Molecular Rattle Proton going through benzene (C6H7+) Mahapatra, Sathyamurthy, Current Science, 1995 Ea = 11.7 kcal/mol B. Das and K.L. Sebastian: CPL, 365, 320 (2002)
Cyclononatetraenyl-lithium The activation barrier for the ‘umbrella inversion’ in this case is ~11.5 kcal/mol Normal mode analysis: 276 cm-1(GS), 274i cm-1(TS) 1D through ring motion calc.: 277 cm-1(GS), 267i cm-1 (TS)
We know of several, efficient molecular motors! Biological Molecular Motors All of them occur in BIOLOGICAL systems
Energy from photosynthesis Figures and animation from: http://www.sp.uconn.edu/~terry/images/anim/ATPmito.html
Most powerful known motor ATP Synthase (Rotary) ATP Synthase Synthesizes ATP. Rotates while it does this!
Proteins that WALK! Kinesin (Walker) Works like a PORTER at the railway station See animation at http://mc11.mcri.ac.uk/wrongtrousers.html
Proteins that PUSH! Myosin Myosin For an animation, see the CD of the book: Molecular Biology of the Cell by B. Alberts et. Al. See also: http://www.rpi.edu/dept/bcbp/molbiochem/MBWeb/mb2/part1/myosin.htm
NO WAY near the natural ones! Synthetic Molecular Motors
shuttle station stopper station Rotaxane
+e -e Electron Removal
Proton Addition - H+ + H+
2-catenane 3-catenane Catenanes
-e +e Switching by Oxidation-Reduction Reations
Leigh et. al. Nature, 424, 174 (2003) Excitation of the station leads to unbinding! Catenanes – how to have light driven motor? station shuttle