Article pubs.acs.org/jced
Studies on the Interactions of Saccharides and Methyl Glycosides with Lithium Chloride in Aqueous Solutions at (288.15 to 318.15) K Parampaul K. Banipal,* Amanpreet K. Hundal, Neha Aggarwal, and Tarlok S. Banipal Department of Chemistry, Guru Nanak Dev University, Amritsar 143 005, India S Supporting Information *
ABSTRACT: Standard partial molar volumes, V2o, at infinite dilution and viscosity B-coefficients (employing the Jones−Dole equation) have been calculated from the respective density and efflux time measurements for various solutes (mono-, di-, and trisaccharides, and their derivatives; methyl glycosides) in aqueous solutions of lithium chloride of (0.5, 1.0, 2.0, and 3.0) mol·kg−1 at temperatures of (288.15 to 318.15) K. The corresponding transfer parameters, interaction coefficients, partial molar expansibilities, and dB/dT coefficients have been evaluated and discussed in terms of the solute−solvent and solute−cosolute interactions. The results have been compared for the solutes studied in the presence of (1:1 and 1:2/2:1) electrolytes to arrive at the conclusions of how these solutes interact with the mono- and divalent cations.
1. INTRODUCTION Saccharides and their derivatives are important chemicals in life processes. With the recognition of these compounds in various biological processes such as protein/enzyme stability, cell−cell recognition (immune responses), protective efficacy (glycopeptides of Antarctic fish), and so forth, the understanding of their hydration characteristics is very important.1−3 The properties of saccharide solutions are of great interest in various aspects of basic research and applications.4−12 The conversion of saccharides into biofuels and other biomaterials has been currently one of the most intensive persuits worldwide.5,6 Thermodynamic and transport properties play a pivotal role in the study of reaction conditions (e.g., feasibility and optimization) of industrial processes. The properties are also useful in geochemical studies to assess the relative stabilities of biomolecules at high temperature and pressure.13 The interactions of saccharides with inorganic salts are of great interest due to the importance of saccharide−metal complexes in chemistry and biology. In spite of the weak complexes formed (stability constant, β < 10), their interactions are selective. Many studies are available on the interactions of saccharides with Groups I and II metal ions, but a relationship of thermodynamic properties with the size or charge of the complexed cations has not been established.14 Further, the thermodynamic information on alkali metal chlorides (particularly LiCl) is not available as a function of temperature.15 The properties of Li+ ions and its compounds show similarities with Group II elements (particularly Mg2+) than they show toward their own group. Therefore, it will be interesting to study that how Li+ ions will influence the hydration behavior of saccharides. Further the accurate data on thermodynamic and transport properties are useful to test the models designed to understand the hydration of ions.16 The efficiency of an © 2014 American Chemical Society
absorption refrigeration machine and heat pump cycles is largely dependent on the physical and chemical properties of heat transfer (LiCl/LiBr + CH3OH) fluids.17 The microstructure of LiCl(aq) solutions at near- and supercritical conditions are of interest in industrial applications and geochemistry.18 In view of increasing biological and technological applications, physicochemical properties of saccharides have been studied in a variety of aqueous electrolyte solutions. In continuation of our previous studies,19−25 we report in present work the apparent molar volumes, V2,ϕ, and viscosities, η, for various monosaccharides; (+)-D-xylose (Xyl), (−)-D-arabinose (Ara), (−)-D-ribose (Rib), (−)-D-fructose (Fru), (+)-Dgalactose (Gal), (+)-D-mannose (Man), and (+)-D-glucose (Glc), disaccharides; (+)-melibiose (Mel), (+)-cellobiose (Cel), (+)-lactose monohydrate (Lac), (+)-maltose monohydrate (Mal), (+)-trehalose dihydrate (Tre), and sucrose (Suc), trisaccharide; (+)-raffinose pentahydrate (Raf) and methyl glycosides; (+)-methyl α-D-glucopyranoside (Me α-Glc), methyl α-D-xylopyranoside (Me α-Xyl) and methyl β-Dxylopyranoside (Me β-Xyl) in (0.5, 1.0, 2.0, and 3.0) mol· kg−1 aqueous solutions of lithium chloride (LiCl) at (288.15, 298.15, 308.15, and 318.15) K. Standard partial molar volumes of transfer, ΔtV2o, at infinite dilution and viscosity B-coefficients of transfer of saccharides and their derivatives (solutes) from water to aqueous solutions of LiCl (cosolute) have been determined. Partial molar expansion coefficients, (∂V2o/∂T)P, second-order derivatives (∂2V2o/∂T2)P, the dB/dT coefficients, and interaction coefficients (YAB, YABB) have been determined. Received: February 14, 2014 Accepted: July 8, 2014 Published: July 21, 2014 2437
dx.doi.org/10.1021/je5001523 | J. Chem. Eng. Data 2014, 59, 2437−2455
Journal of Chemical & Engineering Data
Article
Their signs and magnitudes have been interpreted in terms of various molecular interactions. The behavior of various solutes studied in LiCl(aq) solutions has been compared with that observed in aqueous solutions of alkali and alkaline earth metal chlorides.
V2, ϕ = [M /ρ] − [(ρ − ρo )/(mA ρρo )]
where M and mA are the molar mass and molality of the solute; ρo and ρ are the densities of solvent and solution, respectively. The densities and V2,ϕ results are given in Table 2. The densities of solutes in solutions {representative 3-D plot (Figure 1) of ρ vs mA, molality of (+)-D-mannose in mB = 0.5 mol·kg−1 LiCl solutions} increase with concentration of cosolute (LiCl) but decrease with the rise of temperature. The combined uncertainty in apparent molar volumes, U(V2,ϕ) resulting from the experimentally measured densities, u(ρ) = 2.67·10−3 kg·m−3, molalities u(m) = 1.08·10−6 mol·kg−1, and temperature u(T) = 0.01 K ranges from (0.16 to 0.06)·10−6 m3· mol−1 (level of confidence = 0.95, k ≈ 2) for the low (≤ 0.04 mol·kg−1) and high concentration range of the solutes, respectively. Infinite-dilution standard partial molar volumes (V2o = Vo2,ϕ) were evaluated by least-squares fitting of the following equation to the V2,ϕ data as
2. EXPERIMENTAL SECTION The sources along with mole fraction purity of chemicals used are given in Table 1. The chemicals were dried over anhydrous Table 1. Specifications of the Chemicals Used compound (+)-D-xylose (Xyl) (−)-D-arabinose (Ara) (−)-D-ribose (Rib) (+)-D-glucose (Glc) (+)-D-mannose (Man) (+)-D-galactose (Gal) (−)-D-fructose (Fru) (+)-melibiose (Mel) (+)-cellobiose (Cel) sucrose (Suc) (+)-maltose monohydrate (Mal) (+)-lactose monohydrate (Lac) (+)-trehalose dehydrate (Tre) (+)-raffinose pentahydrate (Raf) (+)-methyl α-D-glucopyranoside (Me α-Glc) methyl α-D-xylopyranoside (Me αXyl) methyl β-D-xylopyranoside (Me βXyl) lithium chloride (LiCl)
source
grade/mole fraction puritya
SRLb SRL SRL SRL SRL SRL SRL SRL SRL Lancaster SRL SRL SRL SRL SRL
AR/0.999 AR/0.999 AR/0.999 AR/0.994 AR/0.999 AR/0.997 AR/0.994 AR/0.994 AR/0.994 AR/0.990 AR/0.994 AR/0.999 AR/0.998 AR/0.999 AR/0.989
SD Fine Chem. Ltd. SD Fine Chem. Ltd. CDHc
AR/0.980
(1)
V2, ϕ = V2° + Svm
(2)
V2o
The values along with slopes (Sv) for the solutes are given in Table 3. The V2o values increase with cosolute (LiCl) concentration as well as with temperature. Infinite-dilution standard partial molar volumes of transfer, ΔtV2o, of each solute from water to aqueous lithium chloride solutions have been calculated as Δt V2 o = V2 o{in LiCl(aq)} − V2 o{in H 2O(l)}
(3)
and plotted vs mB, molality of LiCl (only representative plots are given in Figure 2a−g). The ΔtV2o values for most solutes are positive (except in few cases) and increase with concentration of LiCl at all of the temperatures studied. The ΔtV2o values also increase with the rise of temperature. In the case of pentoses (Figure 2a), the ΔtV2o values show a slight dip at mB ≈ 0.5 mol·kg−1, and the values become positive afterward. The hexoses show a continuous increase in ΔtV2o values at all concentrations and temperatures (Figure 2b). Among the disaccharides, only (+)-maltose monohydrate (Figure 2c) shows some leveling-off effect for the ΔtV2o values at higher concentrations from mB ≈ (2.0 to 3.0) mol·kg−1, whereas the rest of the disaccharides show a linear increase at all concentrations (Figure 2d). The (+)-trehalose dihydrate and (+)-raffinose pentahydrate show almost similar behavior (Figure 2e). Therefore, it may be noticed that the variation of ΔtV2o values for various saccharides with the concentration of LiCl is not the same. However, the ΔtV2o values of saccharides increase linearly with the increase in NaCl concentration reported earlier.25 The methyl α-D-xylo- and methyl β-D-xylo-pyranosides (Figure 2f) have negative Δ t V 2o values in the lower concentration range of LiCl and show a minima at mB ≈ 0.6 mol·kg−1, and values increase continuously afterward which become positive at higher concentrations of LiCl. However, in the case of the (+)-methyl α-D-glucopyranoside, the ΔtV2o values increase with the concentration of LiCl (Figure 2g), and the magnitudes are higher in comparison to Me α-Xyl and Me β-Xyl. The ΔtV2o values increase systematically with the complexity of saccharides as Xyl < Ara < Rib < Man < Fru < Glc < Gal < Mel < Cel < Suc < Mal < Lac < Tre < Raf. A similar behavior for volumes of mono-, di-, and trisaccharides was observed in NaCl(aq)25 and KCl(aq)22 solutions. The hydration of saccharide/derivative molecules in water has relations with the stereochemistry, and the most crucial
AR/0.980 AR/0.999
a
As declared by supplier. bSisco Research Laboratory, India. cCentral Drug House Pvt. Ltd., India.
CaCl2 in a vacuum desiccator for 48 h before use. All of the solutions were prepared freshly on a mass basis with a Mettler balance having a precision of ± 0.01 mg in double-distilled, deionized, and degassed water. A vibrating-tube digital densimeter (model DMA 60/602, Anton Paar, Austria) was used to measure the densities of the solutions. An efficient constant temperature bath (Julabo F 25/ Germany) with stability within ± 0.01 K was used to control the temperature of the water circulating around the densimeter cell. The details of principle and functioning of the densimeter have been described elsewhere.25 Densities for pure water have been taken from the literature.26 The viscosities of solutions were measured by using Ubbelohde-type capillary viscometer, calibrated by measuring the efflux time of pure water from (298.15 to 318.15) K. The efflux time was measured with a digital stopwatch with a resolution of ± 0.01 s, and the average of at least four flow time readings was considered as the final value. The temperature of the water surrounding the viscometer was controlled within ± 0.01 K. The reproducibility of the measured viscosities was better than ± 0.002 mPa·s.
3. RESULTS AND DISCUSSION Apparent molar volumes, V2,ϕ, of the saccharides and methyl glycosides studied in LiCl(aq), mB = (0.5, 1.0, 2.0, and 3.0) mol· kg−1 solutions at (288.15, 298.15, 308.15, and 318.15) K were determined from the experimentally measured densities: 2438
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Table 2. Densities, ρ, and Apparent Molar Volumes, V2,ϕ, of Saccharides and Methyl Glycosides in Water and LiCl(aq) Solutions over the Temperature Range (288.15 to 318.15) K ρ·10−3
mAa mol·kg
−1
kg·m
−3
V2,ϕ·106 −1
m ·mol 3
ρ·10−3
mA mol·kg
−1
T/K = 288.15 K
kg·m
−3
V2,ϕ·106 −1
m ·mol 3
ρ·10−3
mA mol·kg
−1
298.15 K
0.00000 0.05004 0.07584 0.10076 0.12470 0.18456 0.20098
1.012049 1.014769 1.016160 1.017498 1.018773 1.021941 1.022803
95.02 95.03 95.03 95.06 95.08 95.09
0.00000 0.05004 0.07584 0.10076 0.12470 0.18456 0.20098
1.009463 1.012153 1.013527 1.014845 1.016100 1.019215 1.020056
0.00000 0.05320 0.06417 0.09053 0.11023 0.12576 0.14627
1.023756 1.026586 1.027164 1.028548 1.029577 1.030384 1.031445
95.63 95.65 95.69 95.72 95.74 95.77
0.00000 0.05320 0.06417 0.09053 0.11023 0.12576 0.14627
1.020938 1.023707 1.024269 1.025609 1.026596 1.027369 1.028377
0.00000 0.04697 0.06820 0.09017 0.10207 0.12224 0.14850
1.045096 1.047451 1.048495 1.049562 1.050136 1.051097 1.052335
97.53 97.70 97.89 97.97 98.14 98.34
0.00000 0.04697 0.06820 0.09017 0.10207 0.12224 0.14850
1.041174 1.043515 1.044561 1.045634 1.046212 1.047187 1.048448
0.00000 0.05104 0.06726 0.08277 0.09384 0.11584 0.15527
1.062674 1.065167 1.065949 1.066695 1.067224 1.068269 1.070122
97.79 97.85 97.89 97.92 97.99 98.11
0.00000 0.05104 0.06726 0.08277 0.09384 0.11584 0.15527
1.057689 1.060140 1.060908 1.061639 1.062159 1.063186 1.065005
0.04764 0.06284 0.09294 0.10034 0.13348 0.16027
1.014756 1.015614 1.017305 1.017718 1.019564 1.021044
92.61 92.62 92.65 92.66 92.69 92.72
0.04764 0.06284 0.09294 0.10034 0.13348 0.16027
1.012131 1.012974 1.014633 1.015039 1.016846 1.018294
0.05214 0.06284 0.08034 0.11036 0.12048 0.14723
1.026644 1.027226 1.028180 1.029802 1.030335 1.031760
93.53 93.64 93.70 93.82 93.94 94.04
0.05214 0.06284 0.08034 0.11036 0.12048 0.14723
1.023784 1.024361 1.025299 1.026900 1.027434 1.028844
0.05876 0.07496 0.09286 0.12088 0.14249 0.16647
1.048204 1.049051 1.049984 1.051435 1.052548 1.053775
94.95 94.98 95.01 95.06 95.09 95.13
0.05876 0.07496 0.09286 0.12088 0.14249 0.16647
1.044232 1.045066 1.045983 1.047410 1.048503 1.049707
kg·m
−3
V2,ϕ·106 m ·mol 3
−1
ρ·10−3
mA mol·kg
−1
308.15 K (+)-D-Xylose mBb = 0.5 mol·kg−1 0.00000 95.72 0.05004 95.75 0.07584 95.79 0.10076 95.86 0.12470 95.94 0.18456 95.99 0.20098 mB = 1.0 mol·kg−1 0.00000 96.85 0.05320 96.93 0.06417 97.11 0.09053 97.27 0.11023 97.38 0.12576 97.55 0.14627 mB = 2.0 mol·kg−1 0.00000 98.00 0.04697 98.06 0.06820 98.15 0.09017 98.19 0.10207 98.25 0.12224 98.32 0.14850 mB = 3.0 mol·kg−1 0.00000 98.79 0.05104 98.86 0.06726 98.91 0.08277 98.94 0.09384 99.01 0.11584 99.14 0.15527 (−)-D-Arabinose mB = 0.5 mol·kg−1 93.51 0.04764 93.56 0.06284 93.65 0.09294 93.67 0.10034 93.76 0.13348 93.83 0.16027 mB = 1.0 mol·kg−1 94.42 0.05214 94.47 0.06284 94.57 0.08034 94.67 0.11036 94.72 0.12048 94.80 0.14723 mB = 2.0 mol·kg−1 95.90 0.05876 95.94 0.07496 95.98 0.09286 96.03 0.12088 96.07 0.14249 96.12 0.16647
2439
kg·m
−3
V2,ϕ·106 m3·mol−1
318.15 K
1.006130 1.008799 1.010159 1.011464 1.012702 1.015791 1.016628
96.28 96.35 96.41 96.52 96.58 96.61
0.00000 0.05004 0.07584 0.10076 0.12470 0.18456 0.20098
1.002068 1.004703 1.006050 1.007341 1.008572 1.011629 1.012453
97.12 97.14 97.19 97.25 97.30 97.35
1.017112 1.019858 1.020412 1.021736 1.022714 1.023474 1.024473
97.45 97.57 97.79 97.94 98.09 98.25
0.00000 0.05320 0.06417 0.09053 0.11023 0.12576 0.14627
1.012401 1.015128 1.015685 1.017017 1.018007 1.018783 1.019805
98.02 98.04 98.10 98.13 98.16 98.19
1.036240 1.038549 1.039582 1.040644 1.041216 1.042181 1.043427
98.88 98.93 98.97 99.00 99.05 99.12
0.00000 0.04697 0.06820 0.09017 0.10207 0.12224 0.14850
1.031324 1.033603 1.034620 1.035665 1.036227 1.037175 1.038401
99.74 99.82 99.89 99.93 100.00 100.08
1.051579 1.054004 1.054767 1.055493 1.056010 1.057031 1.058845
99.58 99.60 99.63 99.65 99.69 99.76
0.00000 0.05104 0.06726 0.08277 0.09384 0.11584 0.15527
1.047466 1.049839 1.050585 1.051294 1.051798 1.052793 1.054562
100.72 100.76 100.81 100.84 100.90 100.99
1.008761 1.009591 1.011223 1.011623 1.013408 1.014830
94.41 94.48 94.60 94.62 94.67 94.77
0.04764 0.06284 0.09294 0.10034 0.13348 0.16027
1.004654 1.005467 1.007076 1.007459 1.009201 1.010590
95.52 95.63 95.68 95.80 95.92 96.05
1.019933 1.020505 1.021435 1.023020 1.023547 1.024941
95.05 95.10 95.19 95.30 95.37 95.47
0.05214 0.06284 0.08034 0.11036 0.12048 0.14723
1.015169 1.015729 1.016643 1.018199 1.018715 1.020083
96.24 96.30 96.37 96.48 96.56 96.65
1.039234 1.040050 1.040946 1.042338 1.043403 1.044578
97.14 97.19 97.24 97.33 97.39 97.45
0.05876 0.07496 0.09286 0.12088 0.14249 0.16647
1.034258 1.035052 1.035923 1.037273 1.038309 1.039441
98.34 98.45 98.57 98.73 98.81 98.95
dx.doi.org/10.1021/je5001523 | J. Chem. Eng. Data 2014, 59, 2437−2455
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Table 2. continued mAa
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
1.053964 1.055062 1.055638 1.056504 1.057251 1.058154
97.80 97.85 97.88 97.93 97.97 98.02
0.04820 0.07064 0.08246 0.10036 0.11586 0.13472
1.049789 1.050858 1.051418 1.052262 1.052988 1.053868
99.18 99.24 99.27 99.32 99.36 99.41
1.008813 1.009858 1.010490 1.011416 1.012545 1.013697
96.73 96.79 96.83 96.89 96.94 97.03
0.05074 0.07074 0.08289 0.10078 0.12268 0.14527
1.004723 1.005751 1.006372 1.007276 1.008378 1.009506
97.45 97.61 97.69 97.85 97.98 98.10
1.019600 1.020746 1.021518 1.022233 1.022828 1.024571
98.53 98.63 98.71 98.77 98.82 98.96
0.04924 0.07224 0.08788 0.10240 0.11456 0.15046
1.014842 1.015966 1.016724 1.017423 1.018006 1.019710
99.68 99.79 99.87 99.95 100.00 100.17
1.038358 1.039680 1.040180 1.041010 1.042660 1.043807
100.21 100.23 100.23 100.25 100.27 100.28
0.04436 0.07228 0.08288 0.10057 0.13592 0.16064
1.033405 1.034702 1.035192 1.036007 1.037626 1.038750
101.27 101.30 101.31 101.33 101.36 101.38
1.053850 1.054403 1.055581 1.056075 1.057259 1.058045
101.54 101.57 101.62 101.65 101.70 101.75
0.05008 0.06240 0.08878 0.09994 0.12678 0.14476
1.049669 1.050207 1.051353 1.051835 1.052990 1.053758
103.01 103.02 103.04 103.05 103.07 103.09
1.009292 1.010680 1.011875 1.012336 1.014253 1.015615
114.15 114.23 114.29 114.33 114.42 114.50
0.04838 0.06989 0.08851 0.09575 0.12594 0.14759
1.005198 1.006575 1.007761 1.008219 1.010124 1.011478
115.00 115.05 115.08 115.11 115.16 115.21
1.020106 1.021122 1.022091 1.023874 1.024603 1.026348
116.67 116.77 116.85 117.00 117.08 117.25
0.04815 0.06472 0.08061 0.11013 0.12234 0.15179
1.015358 1.016363 1.017320 1.019081 1.019804 1.021530
117.69 117.76 117.84 118.00 118.05 118.21
1.039515 1.040425 1.041574 1.042678 1.043311 1.044874
118.89 118.96 119.02 119.08 119.12 119.20
0.05587 0.07161 0.09160 0.11094 0.12212 0.14983
1.034550 1.035449 1.036585 1.037678 1.038308 1.039859
120.03 120.05 120.08 120.10 120.11 120.14
−1
0.04820 0.07064 0.08246 0.10036 0.11586 0.13472
1.065149 1.066289 1.066876 1.067771 1.068539 1.069470
95.59 95.63 95.77 95.84 95.92 95.99
0.04820 0.07064 0.08246 0.10036 0.11586 0.13472
1.060121 1.061241 1.061828 1.062713 1.063475 1.064398
0.05074 0.07074 0.08289 0.10078 0.12268 0.14527
1.014830 1.015917 1.016576 1.017541 1.018719 1.019925
94.56 94.58 94.59 94.61 94.63 94.66
0.05074 0.07074 0.08289 0.10078 0.12268 0.14527
1.012214 1.013287 1.013933 1.014877 1.016031 1.017212
0.04924 0.07224 0.08788 0.10240 0.11456 0.15046
1.026354 1.027555 1.028366 1.029117 1.029744 1.031582
96.07 96.11 96.16 96.19 96.21 96.28
0.04924 0.07224 0.08788 0.10240 0.11456 0.15046
1.023503 1.024689 1.025491 1.026233 1.026852 1.028669
0.04436 0.07228 0.08288 0.10057 0.13592 0.16064
1.047312 1.048693 1.049212 1.050078 1.051793 1.052981
97.70 97.75 97.80 97.83 97.91 97.97
0.04436 0.07228 0.08288 0.10057 0.13592 0.16064
1.043358 1.044715 1.045227 1.046078 1.047758 1.048919
0.05008 0.06240 0.08878 0.09994 0.12678 0.14476
1.065087 1.065675 1.066929 1.067457 1.068721 1.069562
98.39 98.41 98.44 98.45 98.48 98.50
0.05008 0.06240 0.08878 0.09994 0.12678 0.14476
1.060039 1.060612 1.061832 1.062346 1.063574 1.064392
0.04838 0.06989 0.08851 0.09575 0.12594 0.14759
1.015285 1.016707 1.017930 1.018402 1.020363 1.021756
112.35 112.43 112.49 112.53 112.64 112.72
0.04838 0.06989 0.08851 0.09575 0.12594 0.14759
1.012665 1.014073 1.015286 1.015755 1.017702 1.019085
0.04815 0.06472 0.08061 0.11013 0.12234 0.15179
1.026837 1.027881 1.028875 1.030706 1.031456 1.033249
114.58 114.71 114.81 114.99 115.06 115.24
0.04815 0.06472 0.08061 0.11013 0.12234 0.15179
1.023974 1.025004 1.025985 1.027789 1.028531 1.030301
0.05587 0.07161 0.09160 0.11094 0.12212 0.14983
1.048483 1.049418 1.050598 1.051729 1.052380 1.053974
116.51 116.65 116.78 116.90 116.96 117.14
0.05587 0.07161 0.09160 0.11094 0.12212 0.14983
1.044498 1.045422 1.046585 1.047704 1.048346 1.049927
mB = 3.0 mol·kg 96.61 0.04820 96.67 0.07064 96.69 0.08246 96.73 0.10036 96.77 0.11586 96.81 0.13472 (−)-D-Ribose mB = 0.5 mol·kg−1 95.30 0.05074 95.37 0.07074 95.43 0.08289 95.54 0.10078 95.61 0.12268 95.69 0.14527 mB = 1.0 mol·kg−1 96.83 0.04924 96.88 0.07224 96.91 0.08788 96.94 0.10240 96.96 0.11456 97.02 0.15046 mB = 2.0 mol·kg−1 98.56 0.04436 98.67 0.07228 98.70 0.08288 98.75 0.10057 98.88 0.13592 98.98 0.16064 mB = 3.0 mol·kg−1 99.78 0.05008 99.79 0.06240 99.84 0.08878 99.85 0.09994 99.89 0.12678 99.92 0.14476 (+)-D-Glucose mB = 0.5 mol·kg−1 113.16 0.04838 113.22 0.06989 113.26 0.08851 113.28 0.09575 113.35 0.12594 113.41 0.14759 mB = 1.0 mol·kg−1 115.63 0.04815 115.73 0.06472 115.82 0.08061 116.00 0.11013 116.06 0.12234 116.22 0.15179 mB = 2.0 mol·kg−1 117.77 0.05587 117.83 0.07161 117.93 0.09160 118.00 0.11094 118.05 0.12212 118.15 0.14983
2440
dx.doi.org/10.1021/je5001523 | J. Chem. Eng. Data 2014, 59, 2437−2455
Journal of Chemical & Engineering Data
Article
Table 2. continued mAa
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
1.054411 1.055792 1.056522 1.057221 1.059147 1.060903
119.89 119.96 119.98 120.00 120.08 120.15
0.05011 0.07487 0.08802 0.10067 0.13584 0.16827
1.050248 1.051608 1.052327 1.053016 1.054917 1.056655
121.07 121.09 121.10 121.11 121.14 121.16
1.009353 1.011016 1.012689 1.013933 1.014675 1.016073
113.24 113.31 113.37 113.43 113.46 113.52
0.04864 0.07402 0.09976 0.11904 0.13059 0.15247
1.005262 1.006912 1.008575 1.009810 1.010545 1.011934
114.02 114.06 114.09 114.14 114.18 114.22
1.020252 1.021514 1.022381 1.023221 1.023612 1.026158
114.00 114.01 114.02 114.03 114.04 114.06
0.04835 0.06795 0.08146 0.09462 0.10076 0.14091
1.015501 1.016746 1.017600 1.018429 1.018815 1.021319
115.04 115.07 115.09 115.11 115.12 115.19
1.039797 1.040540 1.041320 1.042515 1.043927 1.045056
116.00 116.01 116.02 116.03 116.05 116.06
0.05765 0.06981 0.08260 0.10230 0.12570 0.14452
1.034828 1.035558 1.036323 1.037495 1.038876 1.039980
117.15 117.18 117.22 117.27 117.34 117.39
1.054186 1.055202 1.056266 1.057308 1.058428 1.059997
118.61 118.70 118.79 118.88 118.93 119.07
0.04498 0.06274 0.08150 0.10003 0.11998 0.14839
1.050032 1.051034 1.052084 1.053113 1.054213 1.055770
119.70 119.75 119.82 119.90 119.97 120.04
1.009420 1.010041 1.012176 1.013392 1.014205 1.016304
112.80 112.85 113.00 113.08 113.13 113.27
0.04932 0.05874 0.09135 0.11009 0.12268 0.15546
1.005318 1.005931 1.008041 1.009243 1.010046 1.012118
113.80 113.85 113.99 114.07 114.12 114.26
1.019986 1.021552 1.022775 1.024408 1.025396 1.027034
114.74 114.77 114.80 114.84 114.87 114.91
0.04476 0.06939 0.08874 0.11474 0.13058 0.15697
1.015235 1.016780 1.017987 1.019598 1.020574 1.022191
115.85 115.88 115.90 115.93 115.95 115.98
1.038956 1.040275 1.041743 1.042291 1.044196 1.045530
116.91 116.96 117.02 117.04 117.11 117.17
0.04466 0.06657 0.09116 0.10039 0.13267 0.15549
1.034002 1.035303 1.036756 1.037299 1.039186 1.040510
118.01 118.03 118.04 118.05 118.07 118.09
−1
0.05011 0.07487 0.08802 0.10067 0.13584 0.16827
1.065619 1.067048 1.067796 1.068516 1.070493 1.072287
117.17 117.32 117.44 117.50 117.70 117.88
0.05011 0.07487 0.08802 0.10067 0.13584 0.16827
1.060567 1.061969 1.062709 1.063416 1.065366 1.067144
0.04864 0.07402 0.09976 0.11904 0.13059 0.15247
1.015326 1.017015 1.018712 1.019977 1.020730 1.022151
111.88 111.97 112.07 112.11 112.15 112.21
0.04864 0.07402 0.09976 0.11904 0.13059 0.15247
1.012705 1.014374 1.016047 1.017294 1.018032 1.019429
0.04835 0.06795 0.08146 0.09462 0.10076 0.14091
1.026966 1.028255 1.029140 1.029998 1.030396 1.032990
112.28 112.31 112.33 112.35 112.37 112.44
0.04835 0.06795 0.08146 0.09462 0.10076 0.14091
1.024110 1.025382 1.026256 1.027104 1.027499 1.030061
0.05765 0.06981 0.08260 0.10230 0.12570 0.14452
1.048749 1.049512 1.050312 1.051540 1.052990 1.054150
113.98 113.99 114.00 114.01 114.03 114.04
0.05765 0.06981 0.08260 0.10230 0.12570 0.14452
1.044776 1.045528 1.046317 1.047527 1.048955 1.050098
0.04498 0.06274 0.08150 0.10003 0.11998 0.14839
1.065364 1.066417 1.067524 1.068612 1.069777 1.071426
116.28 116.30 116.31 116.32 116.33 116.35
0.04498 0.06274 0.08150 0.10003 0.11998 0.14839
1.060330 1.061359 1.062436 1.063491 1.064622 1.066212
0.04932 0.05874 0.09135 0.11009 0.12268 0.15546
1.015421 1.016059 1.018256 1.019510 1.020349 1.022518
110.90 110.92 110.99 111.03 111.05 111.12
0.04932 0.05874 0.09135 0.11009 0.12268 0.15546
1.012794 1.013424 1.015589 1.016824 1.017650 1.019783
0.04476 0.06939 0.08874 0.11474 0.13058 0.15697
1.026701 1.028300 1.029546 1.031207 1.032209 1.033869
112.87 113.00 113.09 113.20 113.28 113.39
0.04476 0.06939 0.08874 0.11474 0.13058 0.15697
1.023849 1.025434 1.026670 1.028321 1.029319 1.030973
0.04466 0.06657 0.09116 0.10039 0.13267 0.15549
1.047889 1.049244 1.050755 1.051318 1.053277 1.054648
114.83 114.88 114.93 114.96 115.03 115.09
0.04466 0.06657 0.09116 0.10039 0.13267 0.15549
1.043928 1.045264 1.046753 1.047309 1.049239 1.050592
mB = 3.0 mol·kg 118.67 0.05011 118.75 0.07487 118.79 0.08802 118.84 0.10067 118.95 0.13584 119.04 0.16827 (+)-D-Mannose mB = 0.5 mol·kg−1 112.69 0.04864 112.81 0.07402 112.97 0.09976 113.04 0.11904 113.12 0.13059 113.21 0.15247 mB = 1.0 mol·kg−1 113.18 0.04835 113.22 0.06795 113.24 0.08146 113.26 0.09462 113.27 0.10076 113.34 0.14091 mB = 2.0 mol·kg−1 115.00 0.05765 115.02 0.06981 115.03 0.08260 115.05 0.10230 115.07 0.12570 115.09 0.14452 mB = 3.0 mol·kg−1 117.56 0.04498 117.64 0.06274 117.74 0.08150 117.84 0.10003 117.91 0.11998 118.04 0.14839 (+)-D-Galactose mB = 0.5 mol·kg−1 111.83 0.04932 111.85 0.05874 111.98 0.09135 112.04 0.11009 112.07 0.12268 112.18 0.15546 mB = 1.0 mol·kg−1 113.74 0.04476 113.80 0.06939 113.85 0.08874 113.91 0.11474 113.95 0.13058 114.01 0.15697 mB = 2.0 mol·kg−1 115.85 0.04466 115.90 0.06657 115.96 0.09116 115.98 0.10039 116.06 0.13267 116.11 0.15549
2441
dx.doi.org/10.1021/je5001523 | J. Chem. Eng. Data 2014, 59, 2437−2455
Journal of Chemical & Engineering Data
Article
Table 2. continued mAa
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
1.054542 1.055727 1.056823 1.057445 1.058383 1.059500
118.71 118.75 118.78 118.80 118.83 118.87
0.05125 0.07199 0.09128 0.10228 0.11896 0.13894
1.050378 1.051545 1.052624 1.053237 1.054163 1.055265
119.87 119.89 119.90 119.91 119.92 119.94
1.009579 1.011884 1.014293 1.015617 1.018128 1.019483
113.51 113.59 113.66 113.70 113.77 113.84
0.05228 0.08769 0.12506 0.14578 0.18537 0.20704
1.005479 1.007758 1.010138 1.011446 1.013923 1.015267
114.43 114.52 114.60 114.65 114.74 114.79
1.020374 1.021421 1.022303 1.023446 1.024208 1.026583
114.78 114.85 114.90 114.96 115.00 115.13
0.05087 0.06740 0.08140 0.09963 0.11184 0.15027
1.015617 1.016649 1.017518 1.018643 1.019392 1.021729
115.91 115.98 116.04 116.11 116.16 116.32
1.039171 1.040284 1.041629 1.042706 1.043549 1.045077
117.24 117.28 117.32 117.37 117.41 117.46
0.04849 0.06710 0.08973 0.10799 0.12237 0.14856
1.034215 1.035312 1.036638 1.037702 1.038535 1.040041
118.31 118.35 118.40 118.43 118.46 118.52
1.054017 1.054937 1.056815 1.057888 1.058649 1.060435
118.70 118.72 118.75 118.77 118.79 118.82
0.04211 0.05815 0.09108 0.11005 0.12358 0.15549
1.049865 1.050771 1.052617 1.053673 1.054422 1.056177
119.80 119.82 119.86 119.88 119.90 119.94
1.013196 1.016952 1.019263 1.021180 1.022304 1.025030
216.77 216.84 216.88 216.92 216.94 217.00
0.05725 0.08832 0.10766 0.12384 0.13338 0.15671
1.009062 1.012771 1.015049 1.016938 1.018045 1.020729
218.40 218.57 218.68 218.77 218.81 218.93
1.023798 1.025584 1.028146 1.030451 1.033115 1.034747
218.44 218.49 218.56 218.62 218.69 218.74
0.05540 0.07046 0.09226 0.11207 0.13521 0.14952
1.019034 1.020809 1.023356 1.025649 1.028301 1.029927
219.85 219.86 219.88 219.90 219.92 219.94
1.042137 1.043447 1.045393 1.047562 1.049012 1.051552
221.80 221.82 221.87 221.92 221.95 222.00
0.05120 0.06275 0.08004 0.09949 0.11259 0.13574
1.037158 1.038452 1.040373 1.042516 1.043944 1.046448
223.51 223.56 223.65 223.71 223.78 223.87
−1
0.05125 0.07199 0.09128 0.10228 0.11896 0.13894
1.065729 1.066951 1.068080 1.068720 1.069686 1.070837
116.41 116.46 116.50 116.53 116.57 116.61
0.05125 0.07199 0.09128 0.10228 0.11896 0.13894
1.060698 1.061903 1.063018 1.063649 1.064605 1.065742
0.05228 0.08769 0.12506 0.14578 0.18537 0.20704
1.015601 1.017979 1.020464 1.021832 1.024425 1.025832
111.29 111.34 111.39 111.42 111.47 111.50
0.05228 0.08769 0.12506 0.14578 0.18537 0.20704
1.012959 1.015297 1.017737 1.019081 1.021626 1.023005
0.05087 0.06740 0.08140 0.09963 0.11184 0.15027
1.027120 1.028200 1.029108 1.030285 1.031070 1.033512
112.51 112.58 112.66 112.73 112.78 112.96
0.05087 0.06740 0.08140 0.09963 0.11184 0.15027
1.024249 1.025310 1.026203 1.027361 1.028131 1.030532
0.04849 0.06710 0.08973 0.10799 0.12237 0.14856
1.048125 1.049273 1.050658 1.051767 1.052636 1.054207
114.86 114.93 115.02 115.09 115.14 115.23
0.04849 0.06710 0.08973 0.10799 0.12237 0.14856
1.044147 1.045274 1.046634 1.047722 1.048573 1.050116
0.04211 0.05815 0.09108 0.11005 0.12358 0.15549
1.065195 1.066145 1.068081 1.069186 1.069968 1.071804
116.24 116.29 116.37 116.42 116.47 116.54
0.04211 0.05815 0.09108 0.11005 0.12358 0.15549
1.060160 1.061091 1.062985 1.064067 1.064832 1.066622
0.05725 0.08832 0.10766 0.12384 0.13338 0.15671
1.019239 1.023064 1.025418 1.027372 1.028516 1.031296
214.08 214.13 214.16 214.18 214.20 214.24
0.05725 0.08832 0.10766 0.12384 0.13338 0.15671
1.016580 1.020356 1.022677 1.024601 1.025724 1.028457
0.05540 0.07046 0.09226 0.11207 0.13521 0.14952
1.030569 1.032386 1.034994 1.037336 1.040046 1.041702
215.58 215.67 215.77 215.88 215.97 216.05
0.05540 0.07046 0.09226 0.11207 0.13521 0.14952
1.027698 1.029505 1.032099 1.034433 1.037132 1.038787
0.05120 0.06275 0.08004 0.09949 0.11259 0.13574
1.051108 1.052443 1.054427 1.056639 1.058116 1.060703
218.76 218.79 218.84 218.89 218.93 218.99
0.05120 0.06275 0.08004 0.09949 0.11259 0.13574
1.047122 1.048442 1.050402 1.052586 1.054043 1.056596
mB = 3.0 mol·kg 117.51 0.05125 117.54 0.07199 117.56 0.09128 117.58 0.10228 117.60 0.11896 117.63 0.13894 (−)-D-Fructose mB = 0.5 mol·kg−1 112.45 0.05228 112.53 0.08769 112.62 0.12506 112.65 0.14578 112.72 0.18537 112.77 0.20704 mB = 1.0 mol·kg−1 113.66 0.05087 113.74 0.06740 113.82 0.08140 113.90 0.09963 113.96 0.11184 114.14 0.15027 mB = 2.0 mol·kg−1 116.14 0.04849 116.21 0.06710 116.29 0.08973 116.37 0.10799 116.43 0.12237 116.51 0.14856 mB = 3.0 mol·kg−1 117.61 0.04211 117.66 0.05815 117.77 0.09108 117.82 0.11005 117.87 0.12358 117.98 0.15549 (+)-Melibiose mB = 0.5 mol·kg−1 215.57 0.05725 215.73 0.08832 215.82 0.10766 215.90 0.12384 215.97 0.13338 216.08 0.15671 mB = 1.0 mol·kg−1 216.78 0.05540 216.81 0.07046 216.85 0.09226 216.89 0.11207 216.93 0.13521 216.96 0.14952 mB = 2.0 mol·kg−1 220.34 0.05120 220.38 0.06275 220.45 0.08004 220.53 0.09949 220.60 0.11259 220.69 0.13574
2442
dx.doi.org/10.1021/je5001523 | J. Chem. Eng. Data 2014, 59, 2437−2455
Journal of Chemical & Engineering Data
Article
Table 2. continued mAa
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
1.057056 1.058858 1.060561 1.062191 1.063882 1.067176
224.90 224.94 224.97 225.00 225.03 225.09
0.04981 0.06648 0.08236 0.09768 0.11370 0.14528
1.052882 1.054665 1.056351 1.057964 1.059640 1.062902
226.51 226.53 226.54 226.56 226.57 226.61
1.012647 1.015498 1.017634 1.018576 1.021306 1.025412
214.31 214.46 214.59 214.64 214.77 214.97
0.05170 0.07478 0.09226 0.10002 0.12268 0.15726
1.008545 1.011379 1.013501 1.014437 1.017152 1.021232
215.44 215.59 215.72 215.77 215.90 216.10
1.023459 1.026706 1.029350 1.029397 1.032089 1.033948
215.30 215.39 215.45 215.46 215.51 215.57
0.05117 0.07785 0.09983 0.10023 0.12284 0.13862
1.018709 1.021934 1.024560 1.024606 1.027278 1.029126
216.49 216.59 216.67 216.69 216.76 216.81
1.042942 1.044955 1.047598 1.047751 1.049445 1.052821
220.84 220.87 220.91 220.92 220.95 221.00
0.05776 0.07543 0.09886 0.10023 0.11540 0.14596
1.037944 1.039930 1.042536 1.042687 1.044355 1.047680
222.72 222.78 222.85 222.86 222.92 223.01
1.056692 1.058735 1.060647 1.062522 1.062591 1.066344
223.81 223.85 223.89 223.92 223.93 224.00
0.04596 0.06462 0.08226 0.09970 0.10035 0.13574
1.052522 1.054541 1.056432 1.058284 1.058352 1.062061
225.44 225.48 225.52 225.56 225.57 225.65
1.012851 1.014804 1.017307 1.019385 1.021435 1.023881
215.00 215.02 215.04 215.05 215.07 215.09
0.05364 0.06947 0.08992 0.10704 0.12406 0.14453
1.008729 1.010662 1.013137 1.015190 1.017213 1.019625
216.48 216.54 216.61 216.67 216.74 216.82
1.022340 1.025574 1.027227 1.027960 1.030623 1.034082
217.79 217.84 217.87 217.89 217.93 217.99
0.04296 0.06998 0.08392 0.09014 0.11286 0.14275
1.017582 1.020782 1.022414 1.023138 1.025768 1.029181
219.33 219.45 219.52 219.56 219.65 219.78
1.041854 1.043887 1.045803 1.047689 1.050471 1.052505
221.95 221.98 222.00 222.02 222.05 222.07
0.04878 0.06674 0.08380 0.10072 0.12594 0.14457
1.036873 1.038879 1.040765 1.042621 1.045358 1.047353
223.75 223.84 223.93 224.00 224.09 224.18
−1
0.04981 0.06648 0.08236 0.09768 0.11370 0.14528
1.068251 1.070086 1.071821 1.073481 1.075205 1.078562
221.80 221.83 221.85 221.88 221.90 221.95
0.04981 0.06648 0.08236 0.09768 0.11370 0.14528
1.063210 1.065025 1.066739 1.068381 1.070082 1.073395
0.05170 0.07478 0.09226 0.10002 0.12268 0.15726
1.018674 1.021579 1.023760 1.024722 1.027510 1.031712
211.72 211.80 211.84 211.87 211.94 212.03
0.05170 0.07478 0.09226 0.10002 0.12268 0.15726
1.016036 1.018919 1.021082 1.022037 1.024804 1.028972
0.05117 0.07785 0.09983 0.10023 0.12284 0.13862
1.030206 1.033504 1.036186 1.036234 1.038965 1.040853
212.74 212.86 212.97 212.98 213.06 213.12
0.05117 0.07785 0.09983 0.10023 0.12284 0.13862
1.027340 1.030617 1.033286 1.033334 1.036052 1.037929
0.05776 0.07543 0.09886 0.10023 0.11540 0.14596
1.051998 1.054070 1.056789 1.056946 1.058690 1.062160
216.69 216.74 216.81 216.83 216.86 216.95
0.05776 0.07543 0.09886 0.10023 0.11540 0.14596
1.048002 1.050049 1.052734 1.052889 1.054609 1.058032
0.04596 0.06462 0.08226 0.09970 0.10035 0.13574
1.067959 1.070072 1.072051 1.073993 1.074064 1.077955
219.20 219.21 219.23 219.24 219.25 219.27
0.04596 0.06462 0.08226 0.09970 0.10035 0.13574
1.062918 1.065007 1.066964 1.068882 1.068952 1.072791
0.05364 0.06947 0.08992 0.10704 0.12406 0.14453
1.018868 1.020850 1.023389 1.025498 1.027578 1.030060
212.67 212.69 212.71 212.73 212.75 212.77
0.05364 0.06947 0.08992 0.10704 0.12406 0.14453
1.016232 1.018199 1.020718 1.022810 1.024874 1.027334
0.04296 0.06998 0.08392 0.09014 0.11286 0.14275
1.029060 1.032335 1.034006 1.034746 1.037436 1.040929
215.45 215.58 215.66 215.71 215.82 215.95
0.04296 0.06998 0.08392 0.09014 0.11286 0.14275
1.026208 1.029468 1.031133 1.031873 1.034558 1.038046
0.04878 0.06674 0.08380 0.10072 0.12594 0.14457
1.050814 1.052888 1.054841 1.056763 1.059600 1.061675
219.00 219.01 219.02 219.03 219.05 219.06
0.04878 0.06674 0.08380 0.10072 0.12594 0.14457
1.046822 1.048862 1.050778 1.052662 1.055437 1.057460
mB = 3.0 mol·kg 223.38 0.04981 223.44 0.06648 223.49 0.08236 223.53 0.09768 223.58 0.11370 223.67 0.14528 (+)-Cellobiose mB = 0.5 mol·kg−1 212.94 0.05170 213.01 0.07478 213.05 0.09226 213.07 0.10002 213.14 0.12268 213.23 0.15726 mB= 1.0 mol·kg−1 213.91 0.05117 213.97 0.07785 214.02 0.09983 214.03 0.10023 214.07 0.12284 214.12 0.13862 mB = 2.0 mol·kg−1 218.29 0.05776 218.37 0.07543 218.47 0.09886 218.49 0.10023 218.55 0.11540 218.68 0.14596 mB = 3.0 mol·kg−1 220.83 0.04596 220.87 0.06462 220.91 0.08226 220.94 0.09970 220.95 0.10035 221.02 0.13574 Sucrose mB = 0.5 mol·kg−1 213.81 0.05364 213.84 0.06947 213.87 0.08992 213.90 0.10704 213.92 0.12406 213.96 0.14453 mB = 1.0 mol·kg−1 216.48 0.04296 216.53 0.06998 216.56 0.08392 216.57 0.09014 216.61 0.11286 216.67 0.14275 mB = 2.0 mol·kg−1 220.75 0.04878 220.87 0.06674 221.00 0.08380 221.11 0.10072 221.26 0.12594 221.38 0.14457
2443
dx.doi.org/10.1021/je5001523 | J. Chem. Eng. Data 2014, 59, 2437−2455
Journal of Chemical & Engineering Data
Article
Table 2. continued mAa
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
1.056852 1.059226 1.061209 1.062389 1.062410 1.066787
225.20 225.27 225.33 225.38 225.39 225.52
0.04808 0.07013 0.08876 0.09994 0.10015 0.14218
1.052677 1.055024 1.056986 1.058154 1.058175 1.062508
226.87 226.92 226.97 227.00 227.01 227.10
1.012743 1.015587 1.017544 1.020957 1.022589 1.025168
232.25 232.32 232.37 232.45 232.49 232.56
0.05254 0.07558 0.09159 0.11982 0.13347 0.15523
1.008589 1.011393 1.013322 1.016683 1.018291 1.020832
234.43 234.51 234.56 234.67 234.72 234.79
1.024546 1.026218 1.027275 1.029186 1.031380 1.034042
236.72 236.82 236.89 236.99 237.11 237.25
0.06206 0.07634 0.08543 0.10198 0.12118 0.14476
1.019737 1.021390 1.022436 1.024326 1.026500 1.029141
238.84 238.89 238.92 238.99 239.05 239.12
1.042195 1.043744 1.044642 1.046028 1.048382 1.049549
242.05 242.07 242.08 242.09 242.12 242.13
0.05319 0.06727 0.07548 0.08821 0.11005 0.12096
1.037168 1.038685 1.039564 1.040919 1.043221 1.044361
244.69 244.74 244.77 244.82 244.90 244.94
1.056415 1.057752 1.059171 1.061345 1.064884 1.067700
242.77 242.82 242.87 242.95 243.07 243.17
0.04429 0.05674 0.07005 0.09064 0.12469 0.15227
1.052207 1.053518 1.054909 1.057041 1.060514 1.063278
245.31 245.35 245.40 245.46 245.55 245.63
1.012709 1.014925 1.017510 1.019343 1.020309 1.023002
233.64 233.69 233.73 233.78 233.80 233.85
0.05286 0.07099 0.09234 0.10764 0.11574 0.13850
1.008589 1.010782 1.013342 1.015156 1.016113 1.018778
235.19 235.27 235.33 235.40 235.42 235.49
1.022449 1.026603 1.026937 1.029003 1.031570 1.034047
237.18 237.33 237.34 237.4 237.48 237.56
0.04454 0.07998 0.08286 0.10076 0.12325 0.14521
1.017692 1.021812 1.022143 1.024192 1.026739 1.029195
238.76 238.88 238.89 238.94 239.01 239.09
1.041807 1.043554 1.045243 1.046358 1.048365 1.051178
241.60 241.64 241.69 241.72 241.76 241.83
0.04946 0.06527 0.08068 0.09093 0.10950 0.13586
1.036827 1.038554 1.040221 1.041323 1.043302 1.046076
243.46 243.52 243.59 243.62 243.69 243.79
−1
0.04808 0.07013 0.08876 0.09994 0.10015 0.14218
1.068057 1.070480 1.072505 1.073710 1.073731 1.078200
221.84 221.92 221.98 222.02 222.04 222.17
0.04808 0.07013 0.08876 0.09994 0.10015 0.14218
1.063023 1.065426 1.067433 1.068630 1.068651 1.073088
0.05254 0.07558 0.09159 0.11982 0.13347 0.15523
1.018834 1.021756 1.023767 1.027276 1.028954 1.031610
228.40 228.44 228.46 228.51 228.54 228.57
0.05254 0.07558 0.09159 0.11982 0.13347 0.15523
1.016165 1.019047 1.021030 1.024489 1.026141 1.028753
0.06206 0.07634 0.08543 0.10198 0.12118 0.14476
1.031412 1.033139 1.034232 1.036209 1.038481 1.041244
232.51 232.55 232.57 232.61 232.66 232.71
0.06206 0.07634 0.08543 0.10198 0.12118 0.14476
1.028488 1.030187 1.031261 1.033205 1.035438 1.038147
0.05319 0.06727 0.07548 0.08821 0.11005 0.12096
1.051224 1.052818 1.053742 1.055167 1.057590 1.058790
237.89 237.91 237.92 237.94 237.97 237.99
0.05319 0.06727 0.07548 0.08821 0.11005 0.12096
1.047221 1.048794 1.049705 1.051110 1.053500 1.054684
0.04429 0.05674 0.07005 0.09064 0.12469 0.15227
1.067658 1.069036 1.070500 1.072743 1.076397 1.079306
238.30 238.34 238.37 238.43 238.52 238.60
0.04429 0.05674 0.07005 0.09064 0.12469 0.15227
1.062604 1.063964 1.065406 1.067617 1.071217 1.074084
0.05286 0.07099 0.09234 0.10764 0.11574 0.13850
1.018739 1.020995 1.023626 1.025496 1.026480 1.029226
230.93 230.95 230.97 230.98 230.99 231.01
0.05286 0.07099 0.09234 0.10764 0.11574 0.13850
1.016096 1.018331 1.020937 1.022787 1.023761 1.026477
0.04454 0.07998 0.08286 0.10076 0.12325 0.14521
1.029190 1.033419 1.033758 1.035857 1.038470 1.040988
234.30 234.46 234.48 234.59 234.67 234.77
0.04454 0.07998 0.08286 0.10076 0.12325 0.14521
1.026319 1.030505 1.030840 1.032919 1.035504 1.037995
0.04946 0.06527 0.08068 0.09093 0.10950 0.13586
1.050777 1.052561 1.054284 1.055424 1.057468 1.060339
238.30 238.35 238.40 238.42 238.49 238.56
0.04946 0.06527 0.08068 0.09093 0.10950 0.13586
1.046802 1.048571 1.050282 1.051413 1.053447 1.056302
mB = 3.0 mol·kg 223.33 0.04808 223.38 0.07013 223.44 0.08876 223.46 0.09994 223.47 0.10015 223.56 0.14218 (+)-Maltose Monohydrate mB = 0.5 mol·kg−1 230.22 0.05254 230.30 0.07558 230.36 0.09159 230.44 0.11982 230.50 0.13347 230.58 0.15523 mB = 1.0 mol·kg−1 234.47 0.06206 234.56 0.07634 234.62 0.08543 234.70 0.10198 234.79 0.12118 234.91 0.14476 mB = 2.0 mol·kg−1 239.79 0.05319 239.82 0.06727 239.84 0.07548 239.86 0.08821 239.90 0.11005 239.92 0.12096 mB = 3.0 mol·kg−1 240.34 0.04429 240.38 0.05674 240.43 0.07005 240.49 0.09064 240.60 0.12469 240.68 0.15227 (+)-Lactose Monohydrate mB = 0.5 mol·kg−1 232.26 0.05286 232.31 0.07099 232.35 0.09234 232.39 0.10764 232.41 0.11574 232.46 0.13850 mB = 1.0 mol·kg−1 235.78 0.04454 235.95 0.07998 235.98 0.08286 236.07 0.10076 236.17 0.12325 236.28 0.14521 mB = 2.0 mol·kg−1 239.80 0.04946 239.81 0.06527 239.82 0.08068 239.83 0.09093 239.84 0.10950 239.86 0.13586
2444
dx.doi.org/10.1021/je5001523 | J. Chem. Eng. Data 2014, 59, 2437−2455
Journal of Chemical & Engineering Data
Article
Table 2. continued mAa
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
1.056977 1.058987 1.061027 1.064584 1.065758 1.068836
243.58 243.64 243.71 243.82 243.86 243.95
0.04991 0.06886 0.08832 0.12276 0.13428 0.16482
1.052802 1.054788 1.056802 1.060314 1.061472 1.064509
245.29 245.36 245.45 245.58 245.63 245.74
1.012125 1.014264 1.018515 1.021097 1.022292 1.024260
252.51 252.55 252.63 252.68 252.72 252.76
0.04854 0.06617 0.10171 0.12364 0.13389 0.15087
1.007976 1.010081 1.014258 1.016794 1.017967 1.019897
254.84 254.91 255.09 255.19 255.24 255.32
1.022885 1.025436 1.027583 1.029057 1.031539 1.034668
254.79 254.86 254.91 254.95 254.99 255.08
0.04822 0.06996 0.08845 0.10127 0.12302 0.15087
1.018097 1.020617 1.022739 1.024198 1.026650 1.029751
257.01 257.03 257.04 257.05 257.07 257.09
1.041656 1.043664 1.044282 1.047287 1.048948 1.052029
259.30 259.44 259.46 259.62 259.70 259.87
0.04829 0.06661 0.07227 0.10016 0.11578 0.14520
1.036659 1.038642 1.039251 1.042219 1.043861 1.046913
261.62 261.69 261.71 261.80 261.85 261.94
1.057230 1.058767 1.061376 1.063432 1.066586 1.067853
261.01 261.05 261.13 261.18 261.27 261.31
0.05249 0.06705 0.09208 0.11206 0.14319 0.15587
1.053017 1.054527 1.057094 1.059119 1.062226 1.063476
263.41 263.43 263.46 263.48 263.52 263.54
1.015600 1.019446 1.022408 1.024479 1.027824 1.032808
405.80 405.83 405.85 405.87 405.89 405.93
0.05160 0.07320 0.09009 0.10204 0.12158 0.15127
1.011469 1.015288 1.018228 1.020284 1.023605 1.028552
408.04 408.07 408.09 408.10 408.12 408.16
1.026056 1.027827 1.032912 1.035965 1.041694 1.043823
407.95 407.98 408.04 408.07 408.15 408.18
0.04998 0.06013 0.08976 0.10790 0.14270 0.15589
1.021282 1.023041 1.028091 1.031123 1.036816 1.038933
410.28 410.30 410.34 410.37 410.42 410.44
1.044610 1.049624 1.050982 1.054754 1.057621 1.061446
412.20 412.35 412.39 412.51 412.59 412.71
0.04927 0.07987 0.08830 0.11206 0.13045 0.15547
1.039639 1.044630 1.045982 1.049744 1.052604 1.056426
414.47 414.50 414.51 414.53 414.55 414.58
−1
0.04991 0.06886 0.08832 0.12276 0.13428 0.16482
1.068193 1.070252 1.072344 1.075998 1.077205 1.080373
239.89 239.90 239.92 239.94 239.95 239.97
0.04991 0.06886 0.08832 0.12276 0.13428 0.16482
1.063147 1.065179 1.067245 1.070847 1.072035 1.075151
0.04854 0.06617 0.10171 0.12364 0.13389 0.15087
1.018202 1.020398 1.024762 1.027415 1.028645 1.030666
248.56 248.59 248.67 248.71 248.73 248.77
0.04854 0.06617 0.10171 0.12364 0.13389 0.15087
1.015538 1.017706 1.022014 1.024632 1.025844 1.027839
0.04822 0.06996 0.08845 0.10127 0.12302 0.15087
1.029690 1.032310 1.034514 1.036027 1.038572 1.041782
250.69 250.79 250.87 250.93 251.01 251.13
0.04822 0.06996 0.08845 0.10127 0.12302 0.15087
1.026792 1.029378 1.031553 1.033046 1.035559 1.038732
0.04829 0.06661 0.07227 0.10016 0.11578 0.14520
1.050686 1.052762 1.053400 1.056506 1.058224 1.061418
254.66 254.76 254.78 254.92 254.99 255.10
0.04829 0.06661 0.07227 0.10016 0.11578 0.14520
1.046681 1.048732 1.049362 1.052436 1.054137 1.057303
0.05249 0.06705 0.09208 0.11206 0.14319 0.15587
1.068503 1.070087 1.072779 1.074900 1.078155 1.079463
256.28 256.32 256.40 256.45 256.54 256.58
0.05249 0.06705 0.09208 0.11206 0.14319 0.15587
1.063431 1.064993 1.067647 1.069740 1.072952 1.074245
0.05160 0.07320 0.09009 0.10204 0.12158 0.15127
1.021702 1.025622 1.028640 1.030751 1.034157 1.039235
400.99 401.04 401.07 401.10 401.15 401.21
0.05160 0.07320 0.09009 0.10204 0.12158 0.15127
1.019018 1.022900 1.025889 1.027978 1.031353 1.036382
0.04998 0.06013 0.08976 0.10790 0.14270 0.15589
1.032879 1.034686 1.039876 1.042992 1.048846 1.051021
402.99 403.00 403.04 403.06 403.10 403.12
0.04998 0.06013 0.08976 0.10790 0.14270 0.15589
1.029956 1.031741 1.036863 1.039936 1.045706 1.047848
0.04927 0.07987 0.08830 0.11206 0.13045 0.15547
1.053619 1.058730 1.060114 1.063965 1.066890 1.070801
407.18 407.27 407.30 407.36 407.42 407.48
0.04927 0.07987 0.08830 0.11206 0.13045 0.15547
1.049609 1.054668 1.056038 1.059847 1.062743 1.066611
mB = 3.0 mol·kg 241.65 0.04991 241.71 0.06886 241.76 0.08832 241.84 0.12276 241.88 0.13428 241.96 0.16482 (+)-Trehalose Dihydrate mB = 0.5 mol·kg−1 250.45 0.04854 250.49 0.06617 250.57 0.10171 250.62 0.12364 250.65 0.13389 250.69 0.15087 mB = 1.0 mol·kg−1 252.65 0.04822 252.74 0.06996 252.80 0.08845 252.86 0.10127 252.92 0.12302 253.01 0.15087 mB = 2.0 mol·kg−1 256.81 0.04829 256.83 0.06661 256.84 0.07227 256.87 0.10016 256.89 0.11578 256.92 0.14520 mB = 3.0 mol·kg−1 258.51 0.05249 258.54 0.06705 258.59 0.09208 258.62 0.11206 258.68 0.14319 258.70 0.15587 (+)-Raffinose Pentahydrate mB = 0.5 mol·kg−1 403.42 0.05160 403.45 0.07320 403.47 0.09009 403.49 0.10204 403.52 0.12158 403.56 0.15127 mB = 1.0 mol·kg−1 405.64 0.04998 405.68 0.06013 405.79 0.08976 405.86 0.10790 405.97 0.14270 406.02 0.15589 mB = 2.0 mol·kg−1 409.78 0.04927 409.86 0.07987 409.88 0.08830 409.95 0.11206 410.00 0.13045 410.07 0.15547
2445
dx.doi.org/10.1021/je5001523 | J. Chem. Eng. Data 2014, 59, 2437−2455
Journal of Chemical & Engineering Data
Article
Table 2. continued mAa
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
414.80 414.83 414.88 414.94 414.97 415.03
0.05214 0.06506 0.09103 0.10817 0.12560 0.15049
1.055864 1.057881 1.061864 1.064437 1.067012 1.070624
417.45 417.53 417.69 417.82 417.95 418.09
135.69 135.76 135.84 135.96 136.13
0.05460 0.07040 0.08546 0.10706 0.14527
1.005149 1.006029 1.006863 1.008053 1.010134
137.16 137.20 137.24 137.29 137.38
136.96 136.98 137.01 137.02 137.05
0.05231 0.07019 0.10960 0.11238 0.14207
1.015222 1.016172 1.018246 1.018389 1.019929
138.80 138.86 138.97 138.99 139.07
138.29 138.36 138.45 138.47 138.55
0.05514 0.07719 0.10578 0.11240 0.14276
1.034134 1.035244 1.036672 1.037002 1.038501
139.99 140.00 140.02 140.02 140.04
138.65 138.73 138.78 138.85 138.91
0.05270 0.07698 0.09158 0.11420 0.13497
1.050043 1.051213 1.051911 1.052985 1.053964
140.47 140.52 140.55 140.59 140.63
116.86 116.94 116.98 117.05 117.09
0.05196 0.08516 0.10032 0.13458 0.15547
1.004434 1.005928 1.006604 1.008123 1.009043
118.19 118.23 118.26 118.30 118.32
117.55 117.61 117.66 117.77 117.81 117.85
0.05076 0.08086 0.10057 0.15463 0.17482 0.19360
1.014636 1.015946 1.016797 1.019107 1.019961 1.020750
118.93 118.96 118.99 119.05 119.07 119.09
119.21 119.25 119.32 119.38 119.40
0.05116 0.06274 0.08012 0.09596 0.10002
1.033405 1.033869 1.034561 1.035186 1.035346
120.69 120.74 120.81 120.88 120.90
119.93 119.96 119.99 120.01 120.04
0.05430 0.07690 0.09946 0.11597 0.13358
1.049554 1.050412 1.051264 1.051882 1.052540
121.44 121.46 121.48 121.50 121.51
−1
0.05214 0.06506 0.09103 0.10817 0.12560 0.15049
1.071289 1.073363 1.077461 1.080116 1.082775 1.086504
409.83 409.86 409.92 409.95 409.99 410.05
0.05214 0.06506 0.09103 0.10817 0.12560 0.15049
0.05460 0.07040 0.08546 0.10706 0.14527
1.015327 1.016263 1.017150 1.018415 1.020624
132.82 132.87 132.92 132.98 133.11
0.05460 0.07040 0.08546 0.10706 0.14527
0.05231 0.07019 0.10960 0.11238 0.14207
1.026775 1.027794 1.030018 1.030173 1.031827
134.22 134.26 134.34 134.35 134.41
0.05231 0.07019 0.10960 0.11238 0.14207
0.05514 0.07719 0.10578 0.11240 0.14276
1.048114 1.049303 1.050830 1.051181 1.052779
135.30 135.36 135.43 135.45 135.53
0.05514 0.07719 0.10578 0.11240 0.14276
0.05270 0.07698 0.09158 0.11420 0.13497
1.065456 1.066718 1.067471 1.068630 1.069684
135.62 135.69 135.73 135.78 135.84
0.05270 0.07698 0.09158 0.11420 0.13497
0.05196 0.08516 0.10032 0.13458 0.15547
1.014559 1.016143 1.016862 1.018475 1.019450
114.76 114.80 114.82 114.86 114.89
0.05196 0.08516 0.10032 0.13458 0.15547
0.05076 0.08086 0.10057 0.15463 0.17482 0.19360
1.026141 1.027538 1.028447 1.030913 1.031825 1.032669
115.26 115.30 115.32 115.38 115.40 115.42
0.05076 0.08086 0.10057 0.15463 0.17482 0.19360
0.05116 0.06274 0.08012 0.09596 0.10002
1.047329 1.047827 1.048571 1.049245 1.049416
116.87 116.92 116.98 117.03 117.05
0.05116 0.06274 0.08012 0.09596 0.10002
0.05430 0.07690 0.09946 0.11597 0.13358
1.064920 1.065841 1.066752 1.067414 1.068114
117.60 117.66 117.72 117.76 117.81
0.05430 0.07690 0.09946 0.11597 0.13358
mB = 3.0 mol·kg 1.066231 412.32 0.05214 1.060067 1.068289 412.33 0.06506 1.062111 1.072357 412.35 0.09103 1.066149 1.074993 412.36 0.10817 1.068762 1.077635 412.37 0.12560 1.071383 1.081341 412.39 0.15049 1.075056 (+)-Methyl α-D-Glucopyranoside mB = 0.5 mol·kg−1 1.012688 133.97 0.05460 1.009274 1.013611 133.99 0.07040 1.010170 1.014486 134.01 0.08546 1.011018 1.015736 134.03 0.10706 1.012222 1.017924 134.08 0.14527 1.014330 mB = 1.0 mol·kg−1 1.023897 135.53 0.05231 1.020011 1.024897 135.56 0.07019 1.020990 1.027080 135.62 0.10960 1.023132 1.027232 135.63 0.11238 1.023281 1.028857 135.67 0.14207 1.024875 mB = 2.0 mol·kg−1 1.044122 136.80 0.05514 1.039124 1.045283 136.86 0.07719 1.040259 1.046774 136.93 0.10578 1.041716 1.047116 136.95 0.11240 1.042051 1.048677 137.03 0.14276 1.043576 mB = 3.0 mol·kg−1 1.060400 137.26 0.05270 1.054240 1.061624 137.39 0.07698 1.055445 1.062353 137.46 0.09158 1.056164 1.063472 137.57 0.11420 1.057269 1.064487 137.68 0.13497 1.058275 Methyl α-D-Xylopyranoside mB = 0.5 mol·kg−1 1.011928 115.79 0.05196 1.008551 1.013481 115.86 0.08516 1.010075 1.014186 115.88 0.10032 1.010765 1.015766 115.94 0.13458 1.012314 1.016720 115.98 0.15547 1.013250 mB = 1.0 mol·kg−1 1.023275 116.35 0.05076 1.019401 1.024643 116.41 0.08086 1.020740 1.025532 116.44 0.10057 1.021608 1.027943 116.53 0.15463 1.023964 1.028834 116.56 0.17482 1.024833 1.029657 116.59 0.19360 1.025636 mB = 2.0 mol·kg−1 1.043366 117.89 0.05116 1.038380 1.043857 117.92 0.06274 1.038858 1.044588 117.97 0.08012 1.039571 1.045251 118.01 0.09596 1.040215 1.045421 118.02 0.10002 1.040379 mB = 3.0 mol·kg−1 1.059890 118.73 0.05430 1.053737 1.060794 118.77 0.07690 1.054623 1.061688 118.82 0.09946 1.055502 1.062338 118.85 0.11597 1.056142 1.063028 118.88 0.13358 1.056818
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Table 2. continued mAa
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mA
ρ·10−3
V2,ϕ·106
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
mol·kg−1
kg·m−3
m3·mol−1
1.008423 1.008965 1.009687 1.011071 1.012739
118.22 118.26 118.30 118.37 118.44
0.05070 0.06284 0.07906 0.11040 0.14857
1.004290 1.004817 1.005520 1.006868 1.008494
119.91 119.92 119.93 119.95 119.98
1.019385 1.020378 1.021427 1.021968 1.023347
118.94 119.00 119.06 119.09 119.16
0.05207 0.07514 0.09970 0.11245 0.14520
1.014595 1.015553 1.016564 1.017086 1.018414
120.78 120.85 120.91 120.94 121.03
1.038502 1.039198 1.039844 1.040327 1.040843
119.89 119.97 120.04 120.09 120.15
0.05504 0.07230 0.08842 0.10054 0.11360
1.033491 1.034158 1.034775 1.035235 1.035727
121.91 121.99 122.07 122.14 122.21
1.053706 1.054425 1.055454 1.055979 1.056753
120.27 120.33 120.41 120.45 120.51
0.05404 0.07260 0.09941 0.11318 0.13366
1.049495 1.050181 1.051162 1.051662 1.052400
122.27 122.32 122.40 122.44 122.50
0.05070 0.06284 0.07906 0.11040 0.14857
1.014467 1.015040 1.015800 1.017256 1.019006
115.36 115.40 115.45 115.56 115.69
0.05070 0.06284 0.07906 0.11040 0.14857
1.011826 1.012387 1.013133 1.014566 1.016296
0.05207 0.07514 0.09970 0.11245 0.14520
1.026167 1.027217 1.028323 1.028894 1.030346
115.90 116.01 116.13 116.17 116.30
0.05207 0.07514 0.09970 0.11245 0.14520
1.023292 1.024323 1.025412 1.025974 1.027408
0.05504 0.07230 0.08842 0.10054 0.11360
1.047523 1.048271 1.048963 1.049480 1.050034
116.43 116.52 116.60 116.66 116.73
0.05504 0.07230 0.08842 0.10054 0.11360
1.043527 1.044252 1.044925 1.045427 1.045967
0.05404 0.07260 0.09941 0.11318 0.13366
1.064959 1.065731 1.066834 1.067398 1.068228
116.79 116.85 116.96 117.00 117.07
0.05404 0.07260 0.09941 0.11318 0.13366
1.059895 1.060641 1.061704 1.062244 1.063044
Methyl β-D-Xylopyranoside mB = 0.5 mol·kg−1 116.61 0.05070 116.62 0.06284 116.64 0.07906 116.67 0.11040 116.70 0.14857 mB = 1.0 mol·kg−1 117.15 0.05207 117.19 0.07514 117.23 0.09970 117.25 0.11245 117.30 0.14520 mB = 2.0 mol·kg−1 117.97 0.05504 118.05 0.07230 118.11 0.08842 118.16 0.10054 118.20 0.11360 mB = 3.0 mol·kg−1 118.47 0.05404 118.53 0.07260 118.65 0.09941 118.72 0.11318 118.79 0.13366
mA is the molality of saccharide in water or water + LiCl. bmB is the molality of LiCl in water. Standard uncertainties u are u(ρ) = 2.67·10−3 kg·m−3, u(m) = 1.08·10−6 mol·kg−1, u(T) = 0.01 K, and the combined uncertainty Uc is Uc(V2,ϕ) = (0.16 to 0.06)·10−6 m3·mol−1 (level of confidence = 0.95, k ≈ 2) for the low (≤0.04 mol·kg−1) and high concentration range of the saccharides. a
groups.27 Among the pentoses and hexoses, Ara (1a2e3e4a) and Gal (1e2e3e4a6e) containing axial(a) −OH(4) and equatorial(e) −OH(2) groups have higher ΔtV2o values, as these exhibit large disturbing effects on the water structure.7,27 These do not fit well into the structure of water; therefore, dehydration contributes more positive values to ΔtV2o in these cases. Fru (1e2a3e4e5a) has lower ΔtV2o values than aldohexoses, probably due to the exocyclic −CHOH moiety situated at the anomeric center, instead at the 5-position. The different nature of the keto (−CO) group and steric strain of furanose form may also be responsible for their lower ΔtV2o values. On average, the methyl hexopyranosides disturb more water molecules than the methyl pentopyranosides. Therefore, Me α-Glu has higher ΔtV2o values than Me α-Xyl and Me βXyl. Further, the low values of methyl glycosides than their respective parent saccharides may be due to the additional methoxy (−OCH3) group that introduces a hydrophobic hydration, hence manifesting significantly weaker hydration of derivatives in comparison to saccharides.27 The differences of transfer volumes among the Me α-Xyl and Me β-Xyl may be assigned to different types of linkage. Among the disaccharides, Lac consisting of Gal + Glc has the most, Suc consisting of Glc + Fru has the least, and Cel and Mal both consisting of Glc + Glc subunits have the moderate, disturbed hydration layers.23 As Lac does not fit well into the structure of water, therefore, dehydration contributes more positive values to ΔtV2o than others. The volumetric results can be explained by taking into consideration the effects of solute and cosolute on the tetrahedral structure of water and interactions between them.
Figure 1. Plot of density, ρ, vs molality, mA, for (+)-D-mannose in LiCl(aq) {mB = 0.5 mol·kg−1} solutions at (288.15, 298.15, 308.15, and 318.15) K.
factor is the position of −OH(4) group in conjunction with relative position of −OH(2) and the derivatization of −OH 2447
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Table 3. Infinite-Dilution Standard Partial Molar Volumes, V2o of Saccharides and Methyl Glycosides in Water and in LiCl(aq) Solutions over the Temperature Range (288.15 to 318.15) Ka V2o·106
mBb mol·kg
−1
T/K =
V2o·106
−1
m3·mol−1
m ·mol 3
288.15
0.0d 0.5 1.0 2.0 3.0
95.10 94.99 95.55 97.16 97.64
(2.82)c (0.48) (1.49) (7.99) (3.03)
0.0 0.5 1.0 2.0 3.0
94.61 94.51 95.97 97.59 98.34
(3.80) (1.04) (2.11) (2.34) (1.13)
0.0 0.5 1.0 2.0 3.0
111.05 111.73 112.19 113.94 116.26
(5.30) (3.17) (1.74) (0.69) (0.63)
0.0 0.5 1.0 2.0 3.0
110.18 111.20 112.28 114.68 116.13
(4.51) (1.35) (4.50) (3.72) (2.66)
0.0 0.5 1.0 2.0 3.0
210.17 211.57 212.52 216.52 219.16
(7.53) (2.93) (4.39) (2.96) (0.81)
0.0 0.5 1.0 2.0 3.0
226.55 228.31 232.36 237.79 238.18
(1.84) (1.68) (2.42) (1.46) (2.75)
0.0 0.5 1.0 2.0 3.0
242.15 248.46 250.49 254.45 256.13
(6.15) (2.05) (4.25) (4.56) (2.89)
0.0 0.5 1.0 2.0 3.0
131.96 132.65 134.11 135.16 135.48
(6.06) (3.18) (2.11) (2.61) (2.63)
0.0 0.5 1.0 2.0 3.0
116.18 115.19 115.69 116.15 116.60
(4.51) (3.38) (4.29) (5.09) (3.57)
298.15
308.15
(+)-D-Xylose (0.74) 96.20 (2.44) (1.79) 96.19 (2.15) (7.48) 97.01 (8.50) (3.23) 98.77 (2.34) (3.28) 99.49 (1.76) (−)-D-Ribose 95.09 (11.70) 96.62 (7.55) 95.08 (4.27) 96.57 (3.11) 96.77 (1.87) 98.41 (4.27) 98.40 (3.54) 100.18 (0.62) 99.70 (1.50) 101.43 (2.16) (+)-D-Mannose 111.67 (1.98) 112.30 (3.85) 112.44 (5.09) 113.11 (2.69) 113.10 (1.70) 113.97 (0.67) 114.95 (0.99) 115.96 (0.69) 117.35 (4.67) 118.43 (4.35) (−)-D-Fructose 111.09(11.28 112.12 (3.48) 112.35 (2.03) 113.40 (2.04) 113.42 (4.82) 114.61 (3.47) 115.96 (3.77) 117.13 (2.24) 117.47 (3.24) 118.66 (1.05) D-(+)-Cellobiose 211.31 (6.33) 212.42 (1.24) 212.80 (2.74) 214.00 (6.26) 213.79 (2.36) 215.15 (3.00) 218.04 (4.43) 220.73 (1.84) 220.73 (2.11) 223.71 (2.11) (+)-Maltose Monohydrate 228.12 (1.22) 229.73 (1.57) 230.04 (3.46) 232.09 (2.99) 234.16 (5.22) 236.33 (6.37) 239.69 (1.89) 241.99 (1.17) 240.20 (3.15) 242.61 (3.69) (+)-Trehalose Dihydrate 243.65 (3.27) 245.20 (2.69) 250.33 (2.34) 252.39 (2.43) 252.49 (3.48) 254.66 (2.74) 256.76 (1.14) 259.04 (5.73) 258.42 (1.83) 260.86 (2.89) (+)-Methyl α-D-Glucopyranoside 133.16 (5.15) 134.39 (14.69) 133.91 (1.19) 135.42 (4.93) 135.45 (1.57) 136.91 (0.97) 136.66 (2.61) 138.13 (2.99) 137.00 (5.06) 138.49 (3.17) Methyl β-D-Xylopyranoside 117.45 (5.34) 119.11 (8.26) 116.56 (0.93) 118.12 (2.21) 117.06 (1.61) 118.82 (2.36) 117.76 (3.94) 119.65 (4.41) 118.24 (4.15) 120.11 (3.00)
95.67 95.62 96.45 97.85 98.63
318.15
288.15
96.87 (1.85) 97.04 (1.50) 97.92 (1.85) 99.59 (3.34) 100.59 (2.62)
92.69 92.56 93.28 94.85 95.33
(7.42) (0.98) (5.18) (1.66) (4.95)
97.09 (1.30) 97.19 (6.95) 99.45 (5.06) 101.23 (0.94) 102.95 (0.82)
111.08 112.17 114.29 116.22 117.16
112.94 113.91 114.96 116.99 119.54
(1.93) (1.95) (1.62) (2.78) (3.43)
109.51(12.29) 110.80 (2.07) 112.67 (4.60) 114.72 (2.33) 116.29 (2.30)
112.94 114.31 115.70 118.21 119.75
(1.69) (2.31) (4.10) (2.06) (1.23)
212.98 213.99 215.32 218.62 221.72
(8.35) (1.58) (4.90) (2.73) (1.56)
213.52 215.13 216.30 222.53 225.33
(1.40) (6.26) (3.70) (3.31) (2.35)
210.87 212.59 215.23 218.97 221.67
(8.80) (1.10) (5.10) (0.64) (3.52)
231.31 234.24 238.63 244.49 245.19
(1.62) (3.55) (3.43) (3.71) (2.93)
225.89 230.88 234.09 238.15 239.85
(0.61) (0.92) (4.71) (3.02) (0.70)
246.79 254.60 256.97 261.47 263.35
(1.04) (4.74) (0.77) (3.27) (1.23)
395.48 400.87 402.93 407.04 409.72
(1.74) (2.22) (1.22) (2.84) (2.20)
135.67 137.03 138.65 139.96 140.37
(6.40) (2.42) (2.99) (0.58) (1.93)
116.21 114.69 115.21 116.69 117.46
(14.68) (1.24) (1.10) (3.57) (2.63)
120.74 119.87 120.66 121.62 122.11
(6.70) (0.70) (2.64) (5.14) (2.90)
(1.21) (3.74) (6.27) (6.55) (5.98)
298.15
308.15
(−)-D-Arabinose (2.06) 94.32 (0.40) (2.83) 94.29 (3.02) (4.01) 95.12 (4.42) (1.99) 96.97 (2.91) (2.29) 97.67 (2.57) (+)-D-Glucose 111.87 (0.09) 112.81 (0.72) 113.09 (2.47) 114.01 (3.50) 115.36 (5.72) 116.41 (5.52) 117.54 (4.10) 118.72 (3.25) 118.51 (3.16) 119.79 (2.15) (+)-D-Galactose 110.30 (5.58) 110.84 (2.64) 111.66 (3.35) 112.59 (4.41) 113.63 (2.41) 114.67 (1.54) 115.74 (2.36) 116.81 (2.32) 117.44 (1.35) 118.62 (1.80) (+)-Melibiose 214.18 (4.19) 215.50 (3.02) 215.27 (5.14) 216.64 (2.29) 216.68 (1.90) 218.27 (3.15) 220.12 (4.21) 221.67 (2.43) 223.24 (3.00) 224.81 (1.96) Sucrose 211.91 (3.18) 212.70 (1.03) 213.73 (1.60) 214.95 (0.96) 216.40 (1.89) 217.70 (2.02) 220.44 (6.56) 221.89 (1.23) 223.21 (2.48) 225.03 (3.45) (+)-Lactose Monohydrate 227.01 (2.57) 228.34 (2.53) 232.14 (2.51) 233.51 (2.46) 235.56 (4.96) 237.02 (3.72) 239.77 (0.69) 241.47 (2.67) 241.52 (2.65) 243.42 (3.25) (+)-Raffinose Pentahydrate 397.09 (3.54) 398.96 (1.53) 403.35 (1.42) 405.73 (1.29) 405.47 (3.56) 407.85 (2.12) 409.64 (2.75) 411.97 (4.80) 412.28 (0.70) 414.68 (2.36) Methyl α-D-Xylopyranoside 116.89 (1.04) 117.90 (0.75) 115.70 (1.80) 116.75 (2.22) 116.27 (1.66) 117.44 (2.10) 117.75 (2.68) 119.01 (3.89) 118.62 (1.93) 119.86 (1.36) 93.41 93.38 94.22 95.79 96.50
318.15 95.14 95.31 96.23 98.03 98.92
(1.32) (4.57) (4.29) (5.55) (2.66)
113.57 114.90 117.44 119.97 121.03
(1.45) (2.08) (5.05) (1.17) (0.77)
111.83 113.59 115.80 117.98 119.83
(13.65) (4.30) (1.15) (0.69) (0.76)
216.75 218.10 219.79 223.30 226.46
(2.60) (5.35) (0.95) (4.25) (0.97)
213.81 216.28 219.14 223.55 226.75
(2.41) (3.71) (4.53) (4.39) (2.49)
229.60 235.01 238.62 243.27 245.09
(1.04) (3.50) (3.22) (3.81) (3.95)
400.20 407.98 410.21 414.42 417.10
(5.58) (1.17) (1.49) (1.02) (6.63)
119.03 118.12 118.87 120.47 121.39
(1.87) (1.28) (1.13) (4.26) (0.91)
Standard deviations for fitting of eq 2 lie in the range of ± (0.01 to 0.05)·106 m3·mol−1. bmB is the molality of LiCl in water. cParentheses contain SV (m3·kg·mol−2) values. dReference 22. a
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Figure 2. Standard partial molar volumes of transfer, ΔtVo2, vs molalities, mB, of LiCl of (a) (−)-D-arabinose, (b) (−)-D-fructose, (c) (+)-maltose monohydrate, (d) (+)-lactose monohydrate, (e) (+)-raffinose pentahydrate, (f) methyl β-D-xylopyranoside, and (g) (+)-methyl α-D-glucopyranoside at ⧫, 288.15 K; ■, 298.15 K; ▲, 308.15 K; ×, 318.15 K.
to “electrostriction” and decrease in hydrogen bonded network of water molecules in the solvation sphere, whereas the overlap of two hydrophobic hydration cospheres lead to negative volume change. In the currently studied ternary system, the
In light of the cosphere overlap model28 of Gurney, thermodynamic properties change due to overlap of hydration cospheres of molecules. The overlap of two ionic or hydrophilic-ionic species lead to positive volume change due 2449
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order to make distinction between structure-making or -breaking ability of solutes, Hepler33 used a mathematical relation: (∂CoP,2/∂P)T = −T(∂2V2o/∂T2)P, which correlates the change in heat capacity with pressure to the second-order derivative of volume w.r.t. temperature. In the present study, the positive (∂2V2o/∂T2)P values obtained in most of the cases (Table S1) also supports the view that the saccharides and methyl glycosides behave as “structure makers” in the presence of lithium chloride solutions. Viscosity B-coefficients were determined by fitting the relative viscosities, ηr (ηr = η/ηo, where ηo and η are the viscosities of solvent and solution, respectively), data to the Jones−Dole equation:
hydrophilic−ionic interactions among the hydrophilic sites (−OH, −CO, and −O−) of the saccharides/methyl glycosides and the ions (Li+/Cl−) of the cosolute contribute positively, whereas the hydrophobic−ionic interactions among the hydrophobic alkyl groups (R = CH, CH2, CH3) of the solute and ions of the cosolute contribute negative volume change. The significant positive ΔtV2o obtained for most of the systems studied suggest that the hydrophilic−ionic interactions predominate and get strengthened with an increase in concentration of LiCl. In cases of pentoses and methyl glycosides (Me α-xyl and Me β-xyl), the negative contributions to ΔtV2o values (at low concentrations) from hydrophobic− ionic interactions decrease with the increase in temperature and concentration of cosolute. Using the Shahidi’s equation,29 the positive ΔtV2o values can be attributed to the decrease in the volume of shrinkage, Vshrinkage in LiCl(aq) solutions, and the reverse is true for the negative ΔtV2o values. The comparison of ΔtV2o values for saccharides and methyl glycosides studied in various cosolutes22,23,25 generally follows the order: MgCl2 > KCl > LiCl > NaCl. These results indicate that the interactions of solutes with divalent cations are stronger than with monovalent cations. Due to the high charge density as well as the ionic strength, the Mg2+ ions undergo more hydration than Li+, Na+, and K+ ions, thus resulting in large ΔtV2o values. In addition to the conformational and stereochemical aspects of the solutes, the size of metal ion also plays a crucial role in effective complexation with solutes. Frank30 explained that cations smaller than potassium ions {e.g. Li+ (crystal/ionic radius = 0.60 Å) and Na+ (ionic radius = 0.95 Å)} or more highly charged than potassium ions {e.g. Mg2+ (ionic radius = 0.65 Å) are net “structure formers”. Thus, cosolutes such as lithium, sodium, and magnesium chlorides will behave as net “structure makers”, and the cosolute KCl on the other hand, due to large-sized potassium ions (ionic radius = 1.33 Å), behaves as slightly “structure breaker”. The structure of water changes, when ions are introduced in it. Therefore, the concept of the hydrated ion as a species is very useful.16 It has been reported that Li+ ion is more heavily hydrated (radius = 3.66 Å) than Na+ (radius = 2.80 Å) and K+ (radius = 1.87 Å) ions of the same group and Mg2+ (radius = 2.08 Å) ion of the Group II. The effective radii of hydrated ions in solution are appreciably greater than their crystal radii, and the order is reversed for monovalent ions. The X-ray31 and Raman32 studies indicate that Cl− ions (common in all the cosolutes) break down the water structure. Therefore, from above observations, it may be concluded that both the interactions between saccharides/methyl glycosides (solutes) and ions of cosolute and their dehydration make positive contributions to ΔtV2o values. The expansion coefficients (∂V2o/∂T)P and second-order derivatives (∂2V2o/∂T2)P were determined by fitting the V2o results into the equation: V2 o = νo + ν1T + ν2T 2
ηr = 1 + Bc
(5)
where c is the molarity (calculated from molality and density data) of the solution in mol·dm−3. The viscosities of saccharides and methyl glycosides in water and in LiCl(aq) solutions are given in the Supporting Information (Table S2) as a function of molalities of solute and cosolute at (288.15 to 318.15) K. The viscosities, η, of the solutions increase {3-D plot (Figure 3) of η
Figure 3. Plot of viscosity, η, vs molality, mA, for (+)-D-mannose in LiCl(aq){mB = 0.5 mol·kg−1} solutions at (288.15, 298.15, 308.15, and 318.15) K.
vs mA for (+)-D-mannose in mB = 0.5 mol·kg−1 LiCl solutions} with the concentration of cosolute (LiCl) but decrease with the rise of temperature. The strong electric fields exerted by the ions can polarize water molecules, producing additional order beyond the first hydration layer. This interaction increases the solution viscosity. The positive and negative values of the Bcoefficients of an ion in water represent the structure-making and -breaking abilities, respectively.34 The B-coefficients are positive (Table 4) for the studied systems and increase with complexity of solutes, i.e., from mono- to di- to trisaccharides. Therefore, the increase in size of solute molecules results in larger B-coefficients. The B-coefficients decrease with the rise of temperature, suggesting that hydration effects in solution are strongly sensitive to temperature. The B-coefficients at (288.15, 298.15, 308.15, and 318.15) K, respectively, for the Li+ ions in water35 are (0.152, 0.146, 0.135, and 0.129) dm3·mol−1, which
(4)
where νo, ν1, and ν2 are constants. The (∂V2o/∂T)P values of solutes studied in LiCl(aq) solutions are positive (Table S1 given as the Supporting Information) and increase with temperature, except for Fru, Glu, Cel, and Raf, where a decrease in values has been observed. The (∂V2o/∂T)P values obtained in the presence of various cosolutes22,23 follow the order: MgCl2 > KCl > LiCl, which again reflects prominent differences in the nature of hydration characteristics of studied solutes which are strongly sensitive to the nature of the cosolute as well as temperature. In 2450
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Table 4. Viscosity B-Coefficients of Saccharides and Methyl Glycosides in Water and in LiCl(aq) Solutions over the Temperature Range (288.15 to 318.15) Ka B·103/m3·mol−1 saccharide
water
c
mBb
= 0.5
(−)-D-arabinose (−)-D-ribose (+)-D-xylose (−)-D-fructose (+)-D-galactose (+)-D-glucose (+)-D-mannose (+)-cellobiose (+)-melibiose sucrose (+)-lactose monohydrate (+)-maltose monohydrate (+)-trehalose dihydrate (+)-raffinose pentahydrate (+)-methylα-D-glucopyranoside methyl α-D-xylopyranoside methyl β-D-xylopyranoside
0.314 0.332 0.370 0.482 0.489 0.498 0.508 0.912 0.920 1.035 1.090 1.128 1.329 1.543 0.496 0.330 0.336
0.328 0.339 0.379 0.509 0.523 0.547 0.547 0.965 0.972 1.176 1.196 1.239 1.463 1.693 0.506 0.333 0.341
(−)-D-arabinose (−)-D-ribose (+)-D-xylose (−)-D-fructose (+)-D-galactose (+)-D-glucose (+)-D-mannose (+)-cellobiose (+)-melibiose sucrose (+)-lactose monohydrate (+)-maltose monohydrate (+)-trehalose dihydrate (+)-raffinose pentahydrate (+)-methylα-D-glucopyranoside methyl α-D-xylopyranoside methyl β-D-xylopyranoside
0.283 0.292 0.324 0.420 0.424 0.433 0.444 0.845 0.852 0.960 1.025 1.051 1.234 1.428 0.443 0.285 0.289
0.286 0.297 0.327 0.427 0.433 0.452 0.461 0.872 0.873 1.067 1.101 1.146 1.336 1.550 0.444 0.289 0.290
1.0 T = 288.15 K 0.334 0.371 0.413 0.521 0.550 0.587 0.582 1.016 1.012 1.195 1.213 1.258 1.481 1.726 0.555 0.346 0.350 T = 308.15 K 0.290 0.308 0.354 0.437 0.461 0.487 0.493 0.903 0.905 1.081 1.112 1.153 1.346 1.579 0.468 0.292 0.298
2.0
3.0
water
mBb = 0.5
0.366 0.399 0.446 0.586 0.604 0.639 0.633 1.066 1.065 1.244 1.270 1.318 1.531 1.788 0.619 0.407 0.390
0.413 0.442 0.497 0.639 0.650 0.692 0.683 1.119 1.125 1.299 1.314 1.377 1.586 1.933 0.642 0.445 0.436
0.311 0.319 0.336 0.451 0.455 0.461 0.471 0.878 0.885 0.996 1.048 1.086 1.277 1.479 0.465 0.307 0.314
0.316 0.324 0.343 0.467 0.475 0.499 0.499 0.920 0.926 1.113 1.142 1.189 1.384 1.626 0.469 0.308 0.317
0.309 0.339 0.386 0.495 0.505 0.529 0.536 0.946 0.952 1.121 1.159 1.199 1.387 1.619 0.535 0.337 0.325
0.347 0.363 0.424 0.546 0.551 0.573 0.583 0.994 0.995 1.183 1.215 1.252 1.444 1.731 0.552 0.371 0.361
0.273 0.280 0.309 0.381 0.388 0.409 0.415 0.807 0.813 0.916 0.980 1.005 1.189 1.365 0.412 0.259 0.266
0.272 0.283 0.311 0.384 0.393 0.416 0.421 0.821 0.827 1.015 1.042 1.089 1.286 1.465 0.407 0.260 0.264
1.0 T = 298.15 K 0.323 0.343 0.372 0.479 0.507 0.532 0.533 0.959 0.968 1.126 1.158 1.199 1.400 1.650 0.508 0.316 0.324 T = 318.15 K 0.277 0.291 0.333 0.393 0.409 0.449 0.450 0.852 0.848 1.020 1.053 1.095 1.291 1.498 0.431 0.264 0.272
2.0
3.0
0.351 0.376 0.406 0.540 0.554 0.582 0.577 1.009 1.015 1.172 1.210 1.253 1.450 1.693 0.572 0.371 0.357
0.394 0.408 0.453 0.598 0.606 0.629 0.634 1.059 1.060 1.230 1.260 1.309 1.505 1.814 0.593 0.408 0.396
0.287 0.308 0.365 0.446 0.460 0.494 0.491 0.897 0.901 1.055 1.094 1.136 1.326 1.526 0.491 0.300 0.291
0.324 0.337 0.404 0.487 0.501 0.539 0.538 0.943 0.946 1.113 1.152 1.186 1.379 1.646 0.511 0.331 0.325
Standard deviations for fitting in eq 5 lie in the range of (0.001 to 0.003)·103 m3·mol−1. bmB (mol·kg−1) is the molality of LiCl in water. cReference 24. a
are fairly large in comparison to B-coefficients of K+ ions (−0.022, −0.009, 0.004, and 0.014) dm3·mol−1 and smaller than B-coefficients of Mg2+ ions (0.411, 0.385, and 0.362) dm3· mol−1, while those for Cl− ions (−0.022, −0.005, 0.004, and 0.014) dm3·mol−1 are same in three cosolutes. The Bcoefficients of Li+(aq) and Mg2+(aq) ions decrease, whereas for K+(aq) ions increase with temperature. The B-coefficients for solutes in LiCl(aq) and other metal chlorides are larger than those in water, indicating that the presence of cosolute strengthens the structure of the solution. The dB/dT is known to be a better criterion for determining the structuremaking or breaking nature of any solute. From the temperature dependence of B-coefficients, the dB/dT values have been calculated. The negative magnitude of dB/dT coefficients (Table S3) increase with complexity of solutes and concentration of cosolute, which again suggests an increase in structural order36 of the solution due to more strengthening of hydrophilic-ionic interactions.
It is evident from plots of viscosity B-coefficients of transfer, ΔtB vs mB (representative Figure 4) that, for pentoses, generally there is a sharp increase in ΔtB values after mB ≈ 0.5 mol·kg−1 (Figure 4a) and the ΔtB values decrease with temperature. For hexoses, a sharp increase in ΔtB values (Figure 4b) has been observed at all concentrations. Among the disaccharides, (+)-cellobiose (Figure 4c) and (+)-melibiose show an almost linear increase in ΔtB values over the whole concentration range of LiCl studied. However, in the remaining disaccharides, the ΔtB values show a sharp increase up to mB ≈ 0.5 mol·kg−1; then the values remain almost same up to mB ≈ 1.0 mol·kg−1, and the values sharply increase afterward (Figure 4d). The (+)-raffinose pentahydrate (trisaccharide) shows a more or less similar behavior to that of disaccharides (Figure 4e). The ΔtB values increase systematically with the complexity of the solutes in the order: Ara < Rib < Xyl < Fru < Gal < Man < Glc < Mel < Cel < Lac < Mal < Tre < Suc < Raf. The (+)-methyl α-Dglucopyranoside (Figure 4f) shows a sharp increase in ΔtB values after mB ≈ 0.5 mol·kg−1 at all temperatures. However, in 2451
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Figure 4. Viscosity B-coefficients of transfer, ΔtB, vs molalities, mB, of LiCl of (a) (+)-D-xylose, (b) (+)-D-galactose, (c) (+)-cellobiose, (d) (+)-maltose monohydrate, (e) (+)-raffinose pentahydrate, (f) (+)-methyl α-D-glucopyranoside, and (g) methyl α-D-xylopyranoside at ⧫, 288.15 K; ■, 298.15 K; ▲, 308.15 K; ×, 318.15 K.
methyl α-D-xylo- and methyl β-D-xylo-pyranosides (Figure 4g), a sharp increase in ΔtB values takes place after mB ≈ 1.0 mol· kg−1. It may be noted that the ΔtB and ΔtVo2 values are lower
in the cases of methyl glycosides than their parent saccharides, which may be due to presence of the additional methoxy, −OCH3 group. Among the pentoses and hexoses, Xyl 2452
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Na+, and K+) do not change the taste quality of solutes, but with increase in the charge of cation (Mg2+) the taste quality of solutes deviates from sweet taste. Our previous studies also suggested that with increase in size of anion, the taste quality of solutes deviates from sweet taste. The borate anion19 (B4O72−) makes some monosaccharides bitter, and phosphate anions20 (H2PO4−) make few derivatives bitter in taste, whereas chloride22,25 (Cl−) and acetate21 (CH3COO−) anions do not have any appreciable effect on the taste of the saccharides.
(1e2e3e4e), Rib(1e2e3a4e), and Glu(1e2e3e4e6e) each containing equatorial (e) −OH(4) and equatorial (e) −OH(2) groups interact strongly with cosolute, which offer greater resistance to the movement of solute molecules resulting higher ΔtB values.7,24 Interaction coefficients have been determined from transfer parameters by using the McMillan−Mayer theory of solutions37,38 as Δt Y o 2(Δt V o 2 or Δt B) = 2YABmB + 3YABBmB 2
(6)
where A and B denote the solute and cosolute, respectively. In most cases, the pair interaction coefficients, YAB (VAB or ηAB), are positive, and their magnitudes increase with complexity of solutes, whereas the triplet interaction coefficients, YABB (VABB or ηABB), have negative values, and their magnitudes decrease with the complexity of the solutes. Further the volumetric interaction coefficients increase, whereas viscometric interaction coefficients decrease with temperature in all cases (Tables S4−S5). As the magnitudes of triplet interaction coefficients are small, hence the pairwise interactions between saccharides/methyl glycosides and LiCl are most favorable. The relative weightings of the coefficients may be judged from their contributions to transfer volumes. Overall, the contributions of pair interaction coefficients for each solute are positive and increase linearly, whereas the triplet, VABB, coefficients are negative and vary nonlinearly (plots not given). This suggests that interactions occur due to the overlap of hydration spheres of the solutes and Li+/Cl− ions. Among the disaccharides, Tre has highest VAB values indicating that it interacts strongly with cosolute ions. Tre is also well-known39 for its peculiar antidesiccant properties in plants. Mal having more flexible α 1 → 4 glycosidic bond has higher VAB values than Cel having β 1 → 4 linkage. As the folding of Mal is more important due to hydrophobic interactions, so it interacts stronger with cosolute than Cel. These observations are clear manifestations of various stereochemical effects. The magnitudes of pair interaction coefficients for systems studied22,23,25 in the presence of various cosolutes follow the order: MgCl2 > NaCl > KCl > LiCl, which indicates that the 2:1 electrolyte influences the values of the volumetric and viscometric properties to a greater extent than a 1:1 electrolyte. Therefore, saccharides/methyl glycosides have stronger interactions with divalent cations (Mg2+) than univalent (Li+/K+/ Na+) cations. The taste behavior11,40 of various solutes can be analyzed on the basis of apparent massic volumes, vϕ, calculated as vϕ = V2,ϕ/M. The vϕ values (data not given) of all of the studied mono-, di-, and trisaccharides in water lie in the clean sweet taste quality range (0.61 to 0.67)·10−3 m3·kg−1. Among the derivatives, the vϕ values of Me Glu lie in the sweet (0.67 to 0.70)·10−3 m3·kg−1 range, but the values for Me α-Xyl and Me β-Xyl lie in the bitter (0.71 to 0.74)·10−3 m3 kg−1 taste range. In the presence of LiCl(aq) solutions, the values for all of the saccharides lie in the sweet (0.62 to 0.70)·10−3 m3·kg−1 taste range. However, the values of Me Glu shift to sweet−bitter at (0.68 to 0.72)·10−3 m3·kg−1, and of Me α-Xyl and Me β-Xyl are still in the bitter (0.70 to 0.75)·10−3 m3·kg−1 taste range. Similarly, we have also observed that in NaCl (aq) , 25 NaOOCCH3(aq),21 and KCl(aq)22 solutions, the vϕ values of the saccharides fall in the sweet taste range. In MgCl2(aq),23 the vϕ values of disaccharides remain in sweet, those of mono- and trisaccharides shift to sweet−bitter, and those of derivatives shift to bitter taste. This suggests that monovalent cations (Li+,
4. CONCLUSION The Vo2 and viscosity B-coefficients are positive for the studied systems and increase with complexity of solutes, i.e., from mono- to di- to trisaccharides. The magnitudes of these parameters also increase with concentration of cosolute. These along with dB/dT and (∂2V2o/∂T2)P values suggest that there is an overall structural increase of the solution in the presence of lithium chloride. The ΔtV2o values are positive for most solutes (except in few cases) and increase with the rise of temperature. However, the positive ΔtB values decrease with rise of temperature. The magnitudes of ΔtVo2 and ΔtB parameters are less in the case of methyl glycosides than their respective parent saccharides, maybe due to the hydrophobic effect of the methoxy (−OCH3) group. The comparison of the results indicate that interactions of saccharides and methyl glycosides with monovalent (Li+, Na+, K+) cations are weaker than those with divalent (Mg2+) cations. Ara and Gal containing ax −OH(4) and eq −OH(2) groups do not fit well into the structure of water; therefore, dehydration contributes more positive values to ΔtV2o than the others. Further, Tre has the highest VAB values suggesting that it interacts strongly with cosolute ions. The vϕ data indicate that monovalent ions do not change the sweet taste quality of saccharides too much; however, with an increase in the charge or size of the ion, the taste quality deviates to a large extent.
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ASSOCIATED CONTENT
S Supporting Information *
Table S1, partial molar expansion coefficients, (∂V2o/∂T)P and second-order derivatives, (∂2V2o/∂T2)P, of saccharides and methyl glycosides in LiCl(aq) solutions over the temperature range (288.15 to 318.15) K; Table S2, viscosities, η, of saccharides and methyl glycosides in LiCl(aq) solutions over the temperature range (288.15 to 318.15) K; Table S3, the dB/ dT coefficients of saccharides and methyl glycosides in LiCl(aq) solutions; Table S4, pair, VAB, and triplet, VAB, interaction coefficients of saccharides and methyl glycosides in LiCl(aq) solutions over the temperature range (288.15 to 318.15) K. Table S5, pair, ηAB, and triplet, ηABB, interaction coefficients of saccharides and methyl glycosides in LiCl(aq) solutions over the temperature range (288.15 to 318.15) K. This material is available free of charge via the Internet at http://pubs.acs.org.
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AUTHOR INFORMATION
Corresponding Author
*Tel.: +91 183 2451357. Fax: +91 183 2258819/20. E-mail:
[email protected] (P. K. Banipal). amanchahal.chem@ gmail.com (Amanpreet K. Hundal). chem.nehaaggarwal@ gmail.com (Neha Aggarwal).
[email protected] (T. S. Banipal). 2453
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Funding
(18) Fedotova, M. V. Temperature and Density Effects on Structural Features of a Dilute Aqueous Lithium Chloride Solution at Near- and Supercritical Conditions. J. Mol. Liq. 2011, 164, 39−43. (19) Banipal, P. K.; Singh, V.; Banipal, T. S. Volumetric and Viscometric Studies on Saccharide-Disodium Tetraborate (Borax) Interactions in Aqueous Solutions. J. Chem. Eng. Data 2013, 58, 2355− 2374. (20) Banipal, P. K.; Aggarwal, N.; Banipal, T. S. Study on Interactions of Saccharides and their Derivatives with Potassium Phosphate Monobasic (1:1 Electrolyte) in Aqueous Solutions at Different Temperatures. J. Mol. Liq. 2014, 196, 291−299. (21) Banipal, P. K.; Singh, V.; Banipal, T. S. Ultrasonic Studies of Some Mono-, Di-, and Trisaccharides in Aqueous Sodium Acetate Solutions at Different Temperatures. Z. Phys. Chem. 2013, 227, 1707− 1722. (22) Banipal, P. K.; Chahal, A. K.; Banipal, T. S. Studies on Volumetric Properties of Some Saccharides in Aqueous Potassium Chloride Solutions over Temperature Range (288.15 to 318.15) K. J. Chem. Thermodyn. 2009, 41, 452−483. (23) Banipal, P. K.; Chahal nee Hundal, A. K.; Banipal, T. S. Effect of Magnesium Chloride (2:1 electrolyte) on the Aqueous Solution Behavior of Some Saccharides Over the Temperature Range of 288.15−318.15 K: a Volumetric Approach. Carbohydr. Res. 2010, 345, 2262−2271. (24) Banipal, P. K.; Chahal, A. K.; Singh, V.; Banipal, T. S. Rheological Behaviour of Some Saccharides in Aqueous Potassium Chloride Solutions over Temperature Range (288.15 to 318.15) K. J. Chem. Thermodyn. 2010, 42, 1024−1035. (25) Banipal, P. K.; Banipal, T. S.; Ahluwalia, J. C.; Lark, B. S. Partial Molar Heat Capacities and Volumes of Transfer of Some Saccharides from Water to Aqueous Sodium Chloride Solutions at T = 298.15 K. J. Chem. Thermodyn. 2002, 34, 1825−1846. (26) Kell, G. S. Density, Thermal Expansivity and Compressibility of Liquid Water from 0◦ to 150◦C: Correlations and Tables for Atmospheric Pressure and Saturation Reviewed and Expressed on 1968 Temperature Scale. J. Chem. Eng. Data 1975, 20, 97−105. (27) Galema, S. A.; Hoiland, H. Stereochemical Aspects of Hydration of Carbohydrates in Aqueous Solutions; Density and Ultrasound Measurements. J. Phys. Chem. 1991, 95, 5321−5326. (28) Gurney, R. W. Ionic Processes in Solution; McGraw Hill: New York, 1953; Vol. 3, Chapter 1, pp 1−20. (29) Shahidi, F.; Ferrell, P. G.; Edwards, J. T. Partial Molar Volumes of Organic Compounds in Water. III. Carbohydrates. J. Solution Chem. 1976, 5, 807−816. (30) Frank, H. S. Covalency in the Hydrogen Bond and the Properties of Water and Ice. Proc. R. Soc. (London) 1958, A 247, 481. (31) Brady, G. W. Structure in Ionic Solutions II. J. Chem. Phys. 1958, 28, 464−469. (32) Schultz, J. W.; Hornig, D. F. The Effect of Dissolved Alkali Halides on Raman Spectrum of Water. J. Phys. Chem. 1961, 65, 2131− 2138. (33) Hepler, L. G. Thermal Expansion and Structure in Water and Aqueous Solutions. Can. J. Chem. 1969, 47, 4613−4617. (34) Wen, W.-Y. Water and Aqueous Solutions: Structure, Thermodynamics, and Transport Processes; Horne, R. A., Ed.; Wiley: New York, 1972; Chapter 15. (35) Donald, H.; Jenkins, B.; Marcus, Y. Viscosity B-Coefficients of Ions in Solution. Chem. Rev. 1995, 95, 2695−2724. (36) Tyrrell, H. J. V.; Kennerley, M. Viscosity B-coefficients between 5° and 20° for Glycolamide, Glycine, and N-Methylated Glycines in Aqueous Solution. J. Chem. Soc. (A) 1968, 2724−2728. (37) Kozak, J. J.; Knight, W.; Kauzmann, W. Solute-Solute Interactions in Aqueous Solutions. J. Chem. Phys. 1968, 68, 675−696. (38) McMillan, W. G., Jr.; Mayer, J. E. The Statistical Thermodynamics of Multicomponent Systems. J. Chem. Phys. 1945, 13, 276−305. (39) Miller, D. P.; De Pablo, J. J. Calorimetric Solution Properties of Simple Saccharides and their Significance for the Stabilization of
The authors are grateful to the Council of Scientific & Industrial Research (Scheme No.: 01/2518/11-EMR-II), New Delhi, India, for the financial support. Notes
The authors declare no competing financial interest.
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