| 1 - 1 |
Chip calorimetry Preface
Hohne GWH, Schick C |
| 2 - 23 |
Phase transitions and nucleation mechanisms in metals studied by nanocalorimetry: A review
Zhao BG, Li LF, Lu FG, Zhai QJ, Yang B, Schick C, Gao YL |
| 24 - 28 |
Nanocalorimetry measurements of metastable states
Perepezko JH, Glendenning TW, Wang JQ |
| 29 - 38 |
Nucleation behavior of melted Bi films at cooling rates from 10(1) to 10(4) K/s studied by combining scanning AC and DC nano-calorimetry techniques
Xiao KC, Vlassak JJ |
| 39 - 45 |
Experimental determination of the nucleation rates of undercooled micron-sized liquid droplets based on fast chip calorimetry
Simon C, Peterlechner M, Wilde G |
| 46 - 52 |
Reprint of: Characterization of bulk metallic glasses via fast differential scanning calorimetry
Pogatscher S, Leutenegger D, Hagmann A, Uggowitzer PJ, Loffier JF |
| 53 - 62 |
Application of in-situ nano-scanning calorimetry and X-ray diffraction to characterize Ni-Ti-Hf high-temperature shape memory alloys
McCluskey PJ, Xiao KC, Gregoire JM, Dale D, Vlassak JJ |
| 63 - 68 |
Kissinger method applied to the crystallization of glass-forming liquids: Regimes revealed by ultra-fast-heating calorimetry
Orava J, Greer AL |
| 69 - 78 |
Nanocalorimetry study of the evolution of melting characteristics of single layer silver alkanethiolate lamella: Fast heating/cooling and electrical annealing
Ye ZC, de la Rama LP, Hu L, Efremov MY, Allen LH |
| 79 - 84 |
Combining TMDSC measurements between chip-calorimeter and molecular simulation to study reversible melting of polymer crystals
Jiang XM, Li ZL, Wang J, Gao HH, Zhou DS, Tang YW, Hu WB |
| 85 - 93 |
Analysis of non-isothermal crystallization during cooling and reorganization during heating of isotactic polypropylene by fast scanning DSC
Schawe JEK |
| 94 - 102 |
Fast cooling of (non)-nucleated virgin and recycled poly(propylenes): Effect of processing conditions on structural and mechanical properties
Luijsterburg BJ, de Kort GW, van Drongelen M, Govaert LE, Goossens JGP |
| 103 - 109 |
Crystallization kinetics of polyamide 66 at processing-relevant cooling conditions and high supercooling
Rhoades AM, Williams JL, Androsch R |
| 110 - 115 |
Vitrification and crystallization of poly(butylene-2,6-naphthalate)
Nishida K, Zhuravlev E, Yang B, Schick C, Shiraishi Y, Kanaya T |
| 116 - 122 |
Fast scanning calorimetry study of the structural relaxation in a random propylene-co-1-octene copolymer
Arranz-Andres J, Cerrada ML, Perez E |
| 123 - 127 |
Measurement of the limiting fictive temperature over five decades of cooling and heating rates
Gao SY, Simon SL |
| 128 - 134 |
Measurement of the thermal glass transition of polystyrene in a cooling rate range of more than six decades
Schawe JEK |
| 135 - 141 |
Structural recovery of a single polystyrene thin film using nanocalorimetry to extend the aging time and temperature range
Koh YP, Grassia L, Simon SL |
| 142 - 148 |
Enthalpy relaxation of selenium observed by fast scanning calorimetry
Pilar R, Honcova P, Schulz G, Schick C, Malek J |
| 149 - 161 |
Reprint of "Heat capacity and transition behavior of sucrose by standard, fast scanning and temperature-modulated calorimetry"
Magon A, Wurm A, Schick C, Pangloli P, Zivanovic S, Skotnicki M, Pyda M |
| 162 - 171 |
Fast differential scanning calorimetry of liquid samples with chips
Splinter R, van Herwaarden AW, van Wetten IA, Pfreundt A, Svendsen WE |
| 172 - 183 |
Toward high-throughput chip calorimetry by use of segmented-flow technology
Wolf A, Hartmann T, Bertolini M, Schemberg J, Grodrian A, Lemke K, Forster T, Kessler E, Hanschke F, Mertens F, Paus R, Lerchner J |
| 184 - 196 |
A continuous flow microfluidic calorimeter: 3-D numerical modeling with aqueous reactants
Sen MA, Kowalski GJ, Fiering J, Larson D |
| 197 - 204 |
Reprint of "An evaluation of thermal lags of fast-scan microchip DSC with polymer film samples"
Toda A, Konishi M |
| 205 - 217 |
Dynamics of the temperature distribution in ultra-fast thin-film calorimeter sensors
Minakov AA, Schick C |
| 218 - 226 |
Thermocouples, their characteristic temperatures, and simple approximation of the emf vs. T
Drebushchak VA |
| 227 - 236 |
Temperature modulated differential scanning calorimetry - extension to high and low frequencies
Shoifet E, Schulz G, Schick C |
| 237 - 243 |
Detection of sunflower oil in extra virgin olive oil by fast differential scanning calorimetry
van Wetten IA, van Herwaarden AW, Splinter R, Boerrigter-Eenling R, van Ruth SM |
| 244 - 252 |
New design of a microcalorimeter for measuring absolute heat capacity from 300 to 550 K
Lee WJ, Kim HJ, Kim JW, Nam DH, Choi KY, Kim KH |
