| 1 - 5 |
Infrared spectroscopy of the Ti(H2O)Ar+ ion-molecule complex: Electronic state switching induced by argon
Ward TB, Carnegie PD, Duncan MA |
| 6 - 8 |
Rational design of improved dienophiles for in vivo tetrazine-trans-cyclooctene ligation
Stauch T, Scholtes JF, Dreuw A |
| 9 - 12 |
Effect of molecular coverage on the electric conductance of a multi-walled carbon nanotube thin film
Kokabu T, Inoue S, Matsumura Y |
| 13 - 17 |
Modulating TiO2 photocatalyst by Al doping: Density functional theory approach
Zhao YF, Li C, Lu S, Gong YY, Niu LY, Liu XJ |
| 18 - 22 |
Identification of the cationic excited state of cyclopentanone via time-resolved Ion yield measurements
Zuo WL, Yin H, Liu XC, Lv H, Zhao L, Shi Y, Yan B, Jin MX, Ding DJ, Xu HF |
| 23 - 28 |
Exploring "aerogen-hydride" interactions between ZOF(2) (Z = Kr, Xe) and metal hydrides: An ab initio study
Esrafili MD, Mohammadian-Sabet F |
| 29 - 36 |
DFT investigation of the interaction of gold nanoclusters with poly(amidoamine) PAMAM G0 dendrimer
Camarada MB |
| 37 - 40 |
Single ZnO nanowire ultraviolet detector with free-recovered contact performance
Wang F, Wang L, Li X, Li ZH, Feng SL, Lu WQ |
| 41 - 45 |
Theoretical study of the pyrolysis of vanillin as a model of secondary lignin pyrolysis
Wang M, Liu C, Xu XX, Li Q |
| 46 - 51 |
New insights into electrocatalytic ozone generation via splitting of water over PbO2 electrode: A DFT study
Gibson G, Morgan A, Hu P, Lin WF |
| 52 - 57 |
Size dependence of vacancy migration energy in ionic nano particles: A potential energy landscape perspective
Niiyama T, Okushima T, Ikeda KS, Shimizu Y |
| 58 - 62 |
Untangling the reaction dynamics of the silylidyne radical (SiH; X-2 Pi) with acetylene (C2H2; X-1 Sigma(+)(g))
Yang T, Dangi BB, Thomas AM, Kaiser RI |
| 63 - 71 |
Photocycle populations with femtosecond excitation of crystalline photoactive yellow protein
Hutchison CDM, Kaucikas M, Tenboer J, Kupitz C, Moffat K, Schmidt M, van Thor JJ |
| 72 - 75 |
Refractive index measurement of nanoparticles by immersion refractometry based on a surface plasmon resonance sensor
Kano H, Iseda A, Ohenoja K, Niskanen I |
| 76 - 80 |
M@B-40 (M = Li, Na, K) serving as a potential promising novel NLO nanomaterial
Shakerzadeh E, Biglari Z, Tahmasebi E |
| 81 - 85 |
Raman study of the temperature-induced decomposition of the fullerene dimers C-120
Meletov KP, Arvanitidis J, Christofilos D, Kourouklis GA, Davydov VA |
| 86 - 91 |
A highly conductive poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) film with the solvent bath treatment by dimethyl sulfoxide as cathode for polymer tantalum capacitor
Ma XP, Wang XY, Li MX, Chen TN, Zhang H, Chen Q, Ding BN, Liu YP |
| 92 - 96 |
Acceleration or deceleration of self-motion by the Marangoni effect
Matsuda Y, Suematsu NJ, Kitahata H, Ikura YS, Nakata S |
| 97 - 102 |
Schottky contribution to the heat capacity of monazite type (La,Pr)PO4 from low temperature calorimetry and fluorescence measurements
Bauer JD, Hirsch A, Bayarjargal L, Peters L, Roth G, Winkler B |
| 103 - 106 |
Size-controlled synthesis of thermal stable single-cored Ru@H-SiO2 core-shell nanoparticles
Yu XL, Yu HB, Lim ZY, Yang GM, Xie ZH, Zhou SH, Yin HF |
| 107 - 113 |
A facile method for synthesis of well-coated ZnO@graphene core/shell structure by self-assembly of amine-functionalized ZnO and graphene oxide
Zhang YL, Song LX, Zhang YZ, Wang PP, Liu YQ, Wu LN, Zhang T |
| 114 - 118 |
Variational calculation of energy levels for metastable states of antiprotonic helium
Hu MH, Yao SM, Wang Y, Li W, Gu YY, Zhong ZX |
| 119 - 124 |
Anion photoelectron spectroscopy and CCSD(T) calculations of the Cl-center dot center dot center dot N-2 complex
Watson PD, Yong HW, Lapere KML, Kettner M, McKinley AJ, Wild DA |
| 125 - 134 |
Normal coordinate analysis and fungicidal activity study on anilazine and its related compound using spectroscopic techniques
Mol GPS, Dhas DDA, Joe IH, Balachandran S |
| 135 - 138 |
Enhancement of magnetic anisotropy for L1(0)-(001) FePt films grown on SrTiO3 substrate
Zhang AM, Wu XS, Tang SL, Zhou SM |
| 139 - 140 |
Comment on "Radicalicity: A scale to compare reactivities of radicals" (Chem. Phys. Lett. 618 (2015) 99-101)
Poutsma ML, Scientist G |
| 141 - 141 |
Reply to comment on "Radicalicity: A scale to compare reactivities of radicals"
Fiser B, Mucsi Z, Gomez-Bengoa E, Viskolcz B, Jensen SJK, Csizmadia IG |
