TY  - JOUR
AU  - Neilsen, Grace
AU  - Rosen, Peter F.
AU  - Dickson, Matthew S.
AU  - Popović, Marko
AU  - Schliesser, Jacob
AU  - Hansen, Lee D.
AU  - Navrotsky, Alexandra
AU  - Woodfield, Brian F.
PY  - 2021
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6070
AB  - Doped ceria materials are ionic conductors currently under investigation for use in solid oxide fuel cells, catalysts, and other applications. We measured the heat capacity of several doped ceria samples from 1.8 K to 300 K to better understand their physical properties. The samples used in this study were either singly doped with Nd or Sm, or co-doped with both Nd and Sm. This work complements an earlier detailed study of their heats of formation and ionic conductivity. Here we provide the thermodynamic functions based on theoretical fits of our heat capacity measurements including Cp,m°, Δ0TSm°, Δ0THm°, and Φm°. We also detected splitting of nuclear magnetic states, which appeared as an upturn in the heat capacity below 10 K. We observed this phenomenon in all samples and provide calculations of the local magnetic field causing the splitting.
PB  - Elsevier
T2  - The Journal of Chemical Thermodynamics
T1  - Heat capacities and thermodynamic functions of neodymia and samaria doped ceria
VL  - 158
SP  - 106454
DO  - 10.1016/j.jct.2021.106454
ER  - 

@article{
author = "Neilsen, Grace and Rosen, Peter F. and Dickson, Matthew S. and Popović, Marko and Schliesser, Jacob and Hansen, Lee D. and Navrotsky, Alexandra and Woodfield, Brian F.",
year = "2021",
abstract = "Doped ceria materials are ionic conductors currently under investigation for use in solid oxide fuel cells, catalysts, and other applications. We measured the heat capacity of several doped ceria samples from 1.8 K to 300 K to better understand their physical properties. The samples used in this study were either singly doped with Nd or Sm, or co-doped with both Nd and Sm. This work complements an earlier detailed study of their heats of formation and ionic conductivity. Here we provide the thermodynamic functions based on theoretical fits of our heat capacity measurements including Cp,m°, Δ0TSm°, Δ0THm°, and Φm°. We also detected splitting of nuclear magnetic states, which appeared as an upturn in the heat capacity below 10 K. We observed this phenomenon in all samples and provide calculations of the local magnetic field causing the splitting.",
publisher = "Elsevier",
journal = "The Journal of Chemical Thermodynamics",
title = "Heat capacities and thermodynamic functions of neodymia and samaria doped ceria",
volume = "158",
pages = "106454",
doi = "10.1016/j.jct.2021.106454"
}

Neilsen, G., Rosen, P. F., Dickson, M. S., Popović, M., Schliesser, J., Hansen, L. D., Navrotsky, A.,& Woodfield, B. F.. (2021). Heat capacities and thermodynamic functions of neodymia and samaria doped ceria. in The Journal of Chemical Thermodynamics
Elsevier., 158, 106454.
https://doi.org/10.1016/j.jct.2021.106454

Neilsen G, Rosen PF, Dickson MS, Popović M, Schliesser J, Hansen LD, Navrotsky A, Woodfield BF. Heat capacities and thermodynamic functions of neodymia and samaria doped ceria. in The Journal of Chemical Thermodynamics. 2021;158:106454.
doi:10.1016/j.jct.2021.106454 .

Neilsen, Grace, Rosen, Peter F., Dickson, Matthew S., Popović, Marko, Schliesser, Jacob, Hansen, Lee D., Navrotsky, Alexandra, Woodfield, Brian F., "Heat capacities and thermodynamic functions of neodymia and samaria doped ceria" in The Journal of Chemical Thermodynamics, 158 (2021):106454,
https://doi.org/10.1016/j.jct.2021.106454 . .

TY  - JOUR
AU  - Popović, Marko
AU  - Woodfield, Brian F.
AU  - Hansen, Lee D.
PY  - 2018
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6071
AB  - Hydrolysis of cellulose to glucose is a key reaction in renewable energy from biomass and in mineralization of soil organic matter to CO2. Conditional thermodynamic parameters, ΔhydG’, ΔhydH’, and ΔhydS’, and equilibrium glucose concentrations are reported for the reaction C6H10O5(cellulose) + H2O(l) ⇄ C6H12O6(aq) as functions of temperature from 0 to 100 °C. Activity coefficients of aqueous glucose solution were determined as a function of temperature. The reaction free energy ΔhydG’ becomes more negative as temperature increases, suggesting that producing cellulosic biofuels at higher temperatures will result in higher conversion. Also, cellulose is a major source of carbon in soil and is degraded by soil microorganisms into CO2 and H2O. Therefore, global warming will make this reaction more rapid, leading to more CO2 and accelerated global warming by a positive feedback.
PB  - Elsevier
T2  - The Journal of Chemical Thermodynamics
T1  - Thermodynamics of hydrolysis of cellulose to glucose from 0 to 100 °C: Cellulosic biofuel applications and climate change implications
VL  - 128
SP  - 244
EP  - 250
DO  - 10.1016/j.jct.2018.08.006
ER  - 

@article{
author = "Popović, Marko and Woodfield, Brian F. and Hansen, Lee D.",
year = "2018",
abstract = "Hydrolysis of cellulose to glucose is a key reaction in renewable energy from biomass and in mineralization of soil organic matter to CO2. Conditional thermodynamic parameters, ΔhydG’, ΔhydH’, and ΔhydS’, and equilibrium glucose concentrations are reported for the reaction C6H10O5(cellulose) + H2O(l) ⇄ C6H12O6(aq) as functions of temperature from 0 to 100 °C. Activity coefficients of aqueous glucose solution were determined as a function of temperature. The reaction free energy ΔhydG’ becomes more negative as temperature increases, suggesting that producing cellulosic biofuels at higher temperatures will result in higher conversion. Also, cellulose is a major source of carbon in soil and is degraded by soil microorganisms into CO2 and H2O. Therefore, global warming will make this reaction more rapid, leading to more CO2 and accelerated global warming by a positive feedback.",
publisher = "Elsevier",
journal = "The Journal of Chemical Thermodynamics",
title = "Thermodynamics of hydrolysis of cellulose to glucose from 0 to 100 °C: Cellulosic biofuel applications and climate change implications",
volume = "128",
pages = "244-250",
doi = "10.1016/j.jct.2018.08.006"
}

Popović, M., Woodfield, B. F.,& Hansen, L. D.. (2018). Thermodynamics of hydrolysis of cellulose to glucose from 0 to 100 °C: Cellulosic biofuel applications and climate change implications. in The Journal of Chemical Thermodynamics
Elsevier., 128, 244-250.
https://doi.org/10.1016/j.jct.2018.08.006

Popović M, Woodfield BF, Hansen LD. Thermodynamics of hydrolysis of cellulose to glucose from 0 to 100 °C: Cellulosic biofuel applications and climate change implications. in The Journal of Chemical Thermodynamics. 2018;128:244-250.
doi:10.1016/j.jct.2018.08.006 .

Popović, Marko, Woodfield, Brian F., Hansen, Lee D., "Thermodynamics of hydrolysis of cellulose to glucose from 0 to 100 °C: Cellulosic biofuel applications and climate change implications" in The Journal of Chemical Thermodynamics, 128 (2018):244-250,
https://doi.org/10.1016/j.jct.2018.08.006 . .

TY  - JOUR
AU  - Hansen, Lee D.
AU  - Popović, Marko
AU  - Tolley, H. Dennis
AU  - Woodfield, Brian F.
PY  - 2018
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6072
AB  - We hypothesize that concepts from thermodynamics and statistical mechanics can be used to define summary statistics, similar to thermodynamic entropy, to summarize the convergence of processes driven by random inputs subject to deterministic constraints. The primary example used here is biological evolution. We propose that evolution of biological structures and behaviors is driven by the ability of living organisms to acquire, store, and act on information and that summary statistics can be developed to provide a stochastically deterministic information theory for biological evolution. The statistical concepts that are the basis of thermodynamic entropy are also true for information, and we show that adaptation and evolution have a specific deterministic direction arising from many random events. Therefore, an information theory formulated on the same foundation as the immensely powerful concepts used in statistical mechanics will provide statistics, similar to thermodynamic entropy, that summarize distribution functions for environmental properties and organism performance. This work thus establishes foundational principles for a quantitative theory that encompasses both behavioral and biological evolution and may be extended to other fields such as economics, market dynamics and health systems.
PB  - Elsevier
T2  - The Journal of Chemical Thermodynamics
T1  - Laws of evolution parallel the laws of thermodynamics
VL  - 124
SP  - 141
EP  - 148
DO  - 10.1016/j.jct.2018.05.005
ER  - 

@article{
author = "Hansen, Lee D. and Popović, Marko and Tolley, H. Dennis and Woodfield, Brian F.",
year = "2018",
abstract = "We hypothesize that concepts from thermodynamics and statistical mechanics can be used to define summary statistics, similar to thermodynamic entropy, to summarize the convergence of processes driven by random inputs subject to deterministic constraints. The primary example used here is biological evolution. We propose that evolution of biological structures and behaviors is driven by the ability of living organisms to acquire, store, and act on information and that summary statistics can be developed to provide a stochastically deterministic information theory for biological evolution. The statistical concepts that are the basis of thermodynamic entropy are also true for information, and we show that adaptation and evolution have a specific deterministic direction arising from many random events. Therefore, an information theory formulated on the same foundation as the immensely powerful concepts used in statistical mechanics will provide statistics, similar to thermodynamic entropy, that summarize distribution functions for environmental properties and organism performance. This work thus establishes foundational principles for a quantitative theory that encompasses both behavioral and biological evolution and may be extended to other fields such as economics, market dynamics and health systems.",
publisher = "Elsevier",
journal = "The Journal of Chemical Thermodynamics",
title = "Laws of evolution parallel the laws of thermodynamics",
volume = "124",
pages = "141-148",
doi = "10.1016/j.jct.2018.05.005"
}

Hansen, L. D., Popović, M., Tolley, H. D.,& Woodfield, B. F.. (2018). Laws of evolution parallel the laws of thermodynamics. in The Journal of Chemical Thermodynamics
Elsevier., 124, 141-148.
https://doi.org/10.1016/j.jct.2018.05.005

Hansen LD, Popović M, Tolley HD, Woodfield BF. Laws of evolution parallel the laws of thermodynamics. in The Journal of Chemical Thermodynamics. 2018;124:141-148.
doi:10.1016/j.jct.2018.05.005 .

Hansen, Lee D., Popović, Marko, Tolley, H. Dennis, Woodfield, Brian F., "Laws of evolution parallel the laws of thermodynamics" in The Journal of Chemical Thermodynamics, 124 (2018):141-148,
https://doi.org/10.1016/j.jct.2018.05.005 . .

TY  - JOUR
AU  - Czerniecka-Kubicka, A.
AU  - Zarzyka, I.
AU  - Walczak, M.
AU  - Schliesser, J.
AU  - Popović, Marko
AU  - Woodfield, Brian F.
AU  - Pyda, Marek
PY  - 2017
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6075
AB  - The low-temperature heat capacity of semi-crystalline aliphatic oligo-urethane obtained from the reaction between butane-1,4-diol and hexamethylene 1,6-diisocyanate was measured using a Quantum Design PPMS (Physical Property Measurement System) in the temperature range of (2.04–292.38) K. The experimental heat capacity data below the glass transition temperature of 280.2 K (7.05 °C) were interpreted in terms of molecular motion and were linked to the vibrational spectrum of oligo-urethane structure. The presented approach applies the classical Einstein, Debye and Tarasov treatments using the ATHAS Scheme. The low-temperature solid heat capacity was estimated by separately approximating the group and skeletal heat capacities from their vibrational spectra. The group vibrational heat capacity was calculated based on the chemical structure and molecular vibrational motions (Ngr = 90) derived from infrared and Raman spectroscopy. The skeletal vibrational heat capacity contribution was estimated by a general Tarasov equation with thirty skeletal modes (Nsk = 30). The solution of this equation gave the values of characteristic Debye temperatures as: Θ1 = 493.6 K, Θ2 = 133.9 K, and Θ3 = 51.6 K. The result indicates the existence of planer (Θ2) interactions in the oligo-urethane molecules, in addition to linear (Θ1) and special (Θ3) interactions, which are attributed to a possible branched structure mixed with the linear form of the oligomer. The total vibrational heat capacity, being the sum of the group and skeletal heat capacities, was extended to higher temperatures and analysed further.

The liquid heat capacity of semi-crystalline aliphatic oligo-urethane was approximated from experimental data by a linear regression and was compared with the estimated linear contributions of polymers that have the same constituent groups and were expressed as Cp(liquid) = 0.406T + 428.5 in J·K−1·mol−1. The solid and liquid heat capacities of oligo-urethane were applied as equilibrium baselines for advanced thermal analysis of the experimental, apparent heat capacity data.

Using estimated parameters of transitions and solid and liquid heat capacities at equilibrium, the integral thermodynamic functions of enthalpy, entropy and free enthalpy as functions of temperature were calculated.
PB  - Elsevier
T2  - The Journal of Chemical Thermodynamics
T1  - Molecular interpretation of low-temperature heat capacity of aliphatic oligo-urethane
VL  - 112
SP  - 299
EP  - 307
DO  - 10.1016/j.jct.2017.05.019
ER  - 

@article{
author = "Czerniecka-Kubicka, A. and Zarzyka, I. and Walczak, M. and Schliesser, J. and Popović, Marko and Woodfield, Brian F. and Pyda, Marek",
year = "2017",
abstract = "The low-temperature heat capacity of semi-crystalline aliphatic oligo-urethane obtained from the reaction between butane-1,4-diol and hexamethylene 1,6-diisocyanate was measured using a Quantum Design PPMS (Physical Property Measurement System) in the temperature range of (2.04–292.38) K. The experimental heat capacity data below the glass transition temperature of 280.2 K (7.05 °C) were interpreted in terms of molecular motion and were linked to the vibrational spectrum of oligo-urethane structure. The presented approach applies the classical Einstein, Debye and Tarasov treatments using the ATHAS Scheme. The low-temperature solid heat capacity was estimated by separately approximating the group and skeletal heat capacities from their vibrational spectra. The group vibrational heat capacity was calculated based on the chemical structure and molecular vibrational motions (Ngr = 90) derived from infrared and Raman spectroscopy. The skeletal vibrational heat capacity contribution was estimated by a general Tarasov equation with thirty skeletal modes (Nsk = 30). The solution of this equation gave the values of characteristic Debye temperatures as: Θ1 = 493.6 K, Θ2 = 133.9 K, and Θ3 = 51.6 K. The result indicates the existence of planer (Θ2) interactions in the oligo-urethane molecules, in addition to linear (Θ1) and special (Θ3) interactions, which are attributed to a possible branched structure mixed with the linear form of the oligomer. The total vibrational heat capacity, being the sum of the group and skeletal heat capacities, was extended to higher temperatures and analysed further.

The liquid heat capacity of semi-crystalline aliphatic oligo-urethane was approximated from experimental data by a linear regression and was compared with the estimated linear contributions of polymers that have the same constituent groups and were expressed as Cp(liquid) = 0.406T + 428.5 in J·K−1·mol−1. The solid and liquid heat capacities of oligo-urethane were applied as equilibrium baselines for advanced thermal analysis of the experimental, apparent heat capacity data.

Using estimated parameters of transitions and solid and liquid heat capacities at equilibrium, the integral thermodynamic functions of enthalpy, entropy and free enthalpy as functions of temperature were calculated.",
publisher = "Elsevier",
journal = "The Journal of Chemical Thermodynamics",
title = "Molecular interpretation of low-temperature heat capacity of aliphatic oligo-urethane",
volume = "112",
pages = "299-307",
doi = "10.1016/j.jct.2017.05.019"
}

Czerniecka-Kubicka, A., Zarzyka, I., Walczak, M., Schliesser, J., Popović, M., Woodfield, B. F.,& Pyda, M.. (2017). Molecular interpretation of low-temperature heat capacity of aliphatic oligo-urethane. in The Journal of Chemical Thermodynamics
Elsevier., 112, 299-307.
https://doi.org/10.1016/j.jct.2017.05.019

Czerniecka-Kubicka A, Zarzyka I, Walczak M, Schliesser J, Popović M, Woodfield BF, Pyda M. Molecular interpretation of low-temperature heat capacity of aliphatic oligo-urethane. in The Journal of Chemical Thermodynamics. 2017;112:299-307.
doi:10.1016/j.jct.2017.05.019 .

Czerniecka-Kubicka, A., Zarzyka, I., Walczak, M., Schliesser, J., Popović, Marko, Woodfield, Brian F., Pyda, Marek, "Molecular interpretation of low-temperature heat capacity of aliphatic oligo-urethane" in The Journal of Chemical Thermodynamics, 112 (2017):299-307,
https://doi.org/10.1016/j.jct.2017.05.019 . .