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Home / Dynamic Vapor Sorption (DVS) Analysis / Literature references on water vapor sorption analysis

Literature references on water vapor sorption analysis

The ProUmid gravimetric sorption analyzer are used in many different academic and industrial applications worldwide. Below you will find a selection of published researches using our instruments.

Food Technology
Pharmaceuticals
Raman Spectroscopy
Building materials
Packaging and Polymers
Wood
Textiles and Fibres
Acheology and Conservation
Caking
Materials and Surfaces

Food Technology

Francesco Ciuffarin, et al. “Interactions of cellulose cryogels and aerogels with water and oil: Structure-function relationships.” Food Hydrocolloids 140(4):108631, 2023. DOI

Xin YiSee, et al. “More reasons to add less salt – NaCl’s unfavourable impact on glass transition and moisture sorption of amorphous maltose-NaCl blends.” Journal of Food Engineering 298, 110499, 2021. DOI

Tugce Senturk Parreidt, et al. „The Development of a Uniform Alginate-Based Coating for Cantaloupe and Strawberries and the Characterization of Water Barrier Properties.“ Foods 8, 203, 2019. DOI

JunYang, et al. “Microstructure investigation and its effects on moisture sorption in fried potato chips.” Journal of Food Engineering 214. 117-128, 2017. DOI

Li Na, Lynne S Taylor, and Lisa J Mauer “Heat transport model for the deliquescence kinetics of crystalline ingredients and mixtures.” Journal of Food Engineering 169, 298-308, 2016. DOI

MBJ Meinders and L Oliver “Viscoelastic Sorption Behavior of Starch and Gluten.” Water Stress in Biological, Chemical, Pharmaceutical and Food Systems. Springer, New York, 149-159, 2015. DOI

Mohamed K Ghorab, et al. “Water–solid interactions between amorphous maltodextrins and crystalline sodium chloride.” Food chemistry 144, 26-35, 2014. DOI

Rebecca A Lipasek, et al. “Effect of temperature on the deliquescence properties of food ingredients and blends.” Journal of Agricultural and Food Chemistry 61, 9241–9250, 2013. DOI

Adam M Stoklosa, et al. “Effects of storage conditions, formulation, and particle size on moisture sorption and flowability of powders: A study of deliquescent ingredient blends.” Food research international 49, 783-791, 2012. DOI

Anita Hirte, et al. “Does crumb morphology affect water migration and crispness retention in crispy breads?.” Journal of Cereal Science 56, 289-295, 2012. DOI

S Renzetti, et al. “Water migration mechanisms in amorphous powder material and related agglomeration propensity.” Journal of Food Engineering 110, 160-168, 2012. DOI

A Gianfrancesco, et al. “New methods to assess water diffusion in amorphous matrices during storage and drying.” Food Chemistry 132, 1664-1670, 2012. DOI

Laura Oliver and Marcel BJ Meinders “Dynamic water vapour sorption in gluten and starch films.” Journal of Cereal Science 54, 409-416, 2011. DOI

Anita Hirte, et al. “Permeability of crust is key to crispness retention.” Journal of cereal science 52, 129-135, 2010. DOI

Wolfgang Danzl and Gottfried Ziegleder “Untersuchung der Kristallisation amorpher Lactose in Milchpulver anhand Dynamischer Wasserdampfsorption.” Chemie Ingenieur Technik 80, 351-357, 2008. DOI

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Pharmaceutical Applications

Doris E Braun, et al. “The Eight Hydrates of Strychnine Sulfate.” Crystal Growth & Design 20(9), 6069-6083, 2020. DOI

Doris E Braun, et al. “Stoichiometric and Nonstoichiometric Hydrates of Brucine.” Crystal growth & design 16, 6111-6121, 2016. DOI

Maren Preis, et al. “Design and evaluation of bilayered buccal film preparations for local administration of lidocaine hydrochloride.” European Journal of Pharmaceutics and Biopharmaceutics 86, 552-561, 2014. DOI

EM Littringer, et al. “Spray drying of aqueous salbutamol sulfate solutions using the Nano Spray Dryer B-90—The impact of process parameters on particle size.” Drying Technology 31, 1346-1353, 2013. DOI

Christoph Kindermann, et al. “Electrolyte-stimulated biphasic dissolution profile and stability enhancement for tablets containing drug-polyelectrolyte complexes.” Pharmaceutical research 29, 2710-2721, 2012. DOI

Martin P Feth, et al. “Challenges in the development of hydrate phases as active pharmaceutical ingredients–An example.” European Journal of Pharmaceutical Sciences 42, 116-129, 2011. DOI

Jasper Vollenbroek, et al. “Determination of low levels of amorphous content in inhalation grade lactose by moisture sorption isotherms.” International journal of pharmaceutics 395, 62-70, 2010. DOI

Neslihan Zencirci , et al. “Temperature-and moisture-dependent phase changes in crystal forms of barbituric acid.” Thermochimica Acta 485, 33-42, 2009. DOI

Kyriakos Kachrimanis, et al. “Effects of moisture and residual solvent on the phase stability of orthorhombic paracetamol.” Pharmaceutical research 25, 1440-1449, 2008. DOI

Matthias Gorny, et al. “Quantifying the degree of disorder in micronized salbutamol sulfate using moisture sorption analysis.” Drug development and industrial pharmacy 33, 235-243, 2007. DOI

Kyriakos Kachrimanis, et al. “Dynamic moisture sorption and desorption of standard and silicified microcrystalline cellulose.” European journal of pharmaceutics and biopharmaceutics 64, 307-315, 2006. DOI

AC Schmidt, eta al. “Crystal polymorphism of local anaesthetic drugs.” Journal of thermal analysis and calorimetry 73, 397-408, 2003. DOI

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Raman Spectroscopy

Martin Philipp Feth, et al. “New technology for the investigation of water vapor sorption–induced crystallographic form transformations of chemical compounds: a water vapor sorption gravimetry–dispersive raman spectroscopy coupling.” Journal of pharmaceutical sciences 100, 1080-1092, 2011). DOI

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Building Physics / Building Material Applications

S. Godts et al., Modeled versus Experimental Salt Mixture Behavior under Variable Humidity, ACS Omega. 9, 2024, 20454–20466. DOI

Christian Pichler, et al. “Water vapor diffusion properties of Obernkirchener sandstone: Analysis of DVS data.” Construction and Building Materials, 347, 128554, 2022. DOI

Yassine Elias Belarbi, et al. “Experimental Characterization of Raw Earth Properties for Modeling Their Hygrothermal Behavior.” Buildings, 12(5), 648, 2022. DOI

Younes Zouaoui, et al. “Hygro-Thermo-Mechanical Behavior of a New Generation of Bio-Based Mortar.” Available at SSRN, 4037965, 2022. DOI

Maroua Maaroufi, et al. “Full characterization of hygrothermal, mechanical and morphological properties of a recycled expanded polystyrene-based mortar” Construction and Building Materials, 301, 124310, 2021. DOI

Farjallah Alassaad, et al. “Impact of phase change materials on lightened earth hygroscopic, thermal and mechanical properties.” Journal of Building Engineering 41, 102417, 2021. DOI

Ferhat Benmahiddine, et al. “Effect of flax shives content and size on the hygrothermal and mechanical properties of flax concrete.” Construction and Building Materials 262, 120077, 2020. DOI

Tuan Anh Phung, et al. “Hygrothermal Behaviour of Cob Material.” Earthen Dwellings and Structures. Springer, Singapore, 345-356, 2019. DOI

Sandro Weisheit, et al. “Assessment of test methods for characterizing the hydrophobic nature of surface-treated High Performance Concrete.” Construction and Building Materials 110, 145-153, 2016. DOI

Horst Stopp, et al. “Passive hygrische Klimatisierung.” Bauphysik 38, 50-61, 2016. DOI

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Packaging Materials, Polymers, Film and Foils

Sandra Kiese, et al. “Time-dependent water vapor permeation through multilayer barrier films: Empirical versus theoretical results” Thin Solid Films 672, 199-205, 2019. DOI

Martina Lindner, et al. “Hygroexpansion, Surface Roughness and Porosity Affect the Electrical Resistance of EVOH-Aluminum- Coated Paper” Coatings 9, 295, 2019. DOI

Markus Schmid, et al. “Impact of Hydrolyzed Whey Protein on the Molecular Interactions and Cross-Linking Density in Whey Protein Isolate-Based Films” International Journal of Polymer Science, 2016. DOI

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Wood

Michael Altgen, et al. “Limits in reaching the anhydrous state of wood and cellulose.” Cellulose 30, 6247–6257, 2023. DOI

Jan T Benthien, et al. “Specific Dimensional Change Behavior of LaminatedBeech Veneer Lumber (BauBuche) in Termsof Moisture Absorption and Desorption.” Fibers 8(7), 47, 2020. DOI

Ricardo Acosta, et al. “Influence of a Thermal Treatment on the Tensile Strength and Equilibrium Moisture Content of Bamboo.” BioResources 15(2), 3103-3111, 2020.

Martin Nopens, et al. “Simultaneous change of wood mass and dimension caused by moisture dynamics.” Scientific Reports 9, 10309, 2019. DOI

Alexander Murr and Roman Lackner “Analysis on the influence of grain size and grain layer thickness on the sorption kinetics of grained wood at low relative humidity with the use of water vapour sorption experiments.” Wood Science and Technology 50, 753–776, 2018. DOI

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Textile and Fibre Applications

Mustapha Nouri, et al. “The Influence of Chemical and Thermal Treatments on the Diss Fiber Hygroscopic Behaviors. Journal of Natural Fibers 19 (10): 3865–78. 2020. DOI

Loan TT Vo, et al. “All-cellulose composites from woven fabrics.” Composites Science and Technology 78, 30-40, 2013. DOI

Barbora Siroka, et al. “Characterization of cellulosic fibers and fabrics by sorption/desorption.” Carbohydrate research 343, 2194-2199 2008. DOI

Satoko Okubayashi, et al. “Moisture sorption/desorption behavior of various manmade cellulosic fibers.” Journal of applied polymer science 97, 1621-1625, 2005. DOI

Satoko Okubayashi, et al. “A kinetic study of moisture sorption and desorption on lyocell fibers.” Carbohydrate Polymers 58, 293-299, 2004. DOI

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Achaeology and Conservation

Roberta Occhipinti, et al. “Effect of atmospheric exposure on alkali activated binders and mortars from Mt. Etna volcanic precursors.” Materials Letters 315, 131940, 2022. DOI

Johanna Klügl and Giovanna Di Pietro “The interaction of water with archaeological and ethnographic birch bark and its effects on swelling, shrinkage and deformations.” Heritage Science 9, 3, 2021. DOI

Ashley Amanda Freeman, et al. “Microscale Physical and Mechanical Analyses ofDistemper Paint: A Case Study of Eidsborg StaveChurch, Norway.” Studies in Conservation, 2021. DOI

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Caking

Vaco C. Braz, et al. “Percolation-based simulation to predict caking kinetics of polydisperse amorphous powders.” Powder Technology 400, 117248, 2022. DOI

Zahra Afrassiabian and KhashayarSaleh “Caking of anhydrous lactose powder owing to phase transition and solid-state hydration under humid conditions: From microscopic to bulk behavior.” Powder Technology 363(1), 488-499, 2020. DOI

Esgar Chávez Montes, et al. “Moisture‐induced caking of beverage powders.” Journal of the Science of Food and Agriculture 91, 2582-2586, 2011. DOI

Roman M Kirsch, et al. “Direct Observation of the Dynamics of Bridge Formation between Urea Prills.” Industrial & Engineering Chemistry Research 50(20), 11728-11733, 2011. DOI

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Material and Surface Technology

Joanna J. Mikolei, et al. “Local water management in cotton linter papers with silica-based coatings.” Cellulose 31, 5855–5868, 2024. DOI

David Seelinger, et al. “Pinecone-Inspired Humidity-Responsive Paper Actuators with Bilayer Structure.” Polymers 16(10),1402, 2024. DOI

Hamze, Rana, et al. “Carnallite double salt for thermochemical heat storage.” Journal of Energy Storage 86, 11404, 2024. DOI

Kamila Piotrowska, et al. “Transformation of reflow solder flux residue under humid conditions.” Microelectronics Reliability 123, 114195, 2021. DOI

Aliakbar Khangholi, et al. “Humidity Robustness of Plasma-Coated PCBs.” Journal of Electronic Materials 49, 848–860, 2020. DOI

Aguo Cheng, et al. “The hygroscopicity of polymer microneedles on the performance of dissolving behavior for transdermal delivery.” International Journal of Polymeric Materials and Polymeric Biomaterials, 1-7, 2020. DOI

Nyah V Zarate, et al. “Effect of relative humidity on onset of capillary forces for rough surfaces.” Journal of colloid and interface science 411, 265-272, 2013. DOI

Marion Schmidt, et al. “Adhesion and barrier performance of novel barrier adhesives used in multilayered high-barrier laminates.” Journal of Adhesion Science and Technology 26, 2405-2436, 2012. DOI

FL Laksmana, et al. “Gas permeation related to the moisture sorption in films of glassy hydrophilic polymers.” Journal of applied polymer science 116, 3310-3317, 2010. DOI

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    DVS Product Advisor

    Step 1: Select temperature range

    Step 2: Select additional sensors

    Step 3: Select additional measurement methods

    Step 4: Select instrument by sample size, sample sorption capacity or the type of application.

    If you can tell us about the samples you want to analyze, the available sample quantity, the sample hygroscopicity or your area of application, we can give you a recommendation for the device that meets your requirements best.

    Step 5: What is the average sample quantity available and/or how hygroscopic are the samples?

    Tiny: <10mg, very low hygroscopicity
    Small: >10mg, low hygroscopity
    Medium: >100mg, moderate hygroscopicity
    Large: >500mg, abundant hygroscopicity

    Step 5: Which field of application is most likely to apply to your samples?

    A: Pharmaceutical pre-formulation
    B: Pharma, Food, Fine Chemicals, Cosmetics, Material characterization, Polymers, Electronics, Fibres, Paper, Wood Analytics, Textiles
    C: Building Materials (concrete, wood, insulation), Fertilizer, Permeability and Packaging testing

    Recommended Instrument(s):

    Additonal sample trays such as the Permeability kit and the requirement for tiny samples do not match. Try to deselect the additonal sample tray or to increase the sample size.

    Additonal sample trays such as the Permeability kit and the application pharmaceutical pre-formulation do not match. Try dp deselect the additonal sample tray or to select a different field of application.

    Outside view of the product SPS23-100n

    SPS23-100n

    The SPS23-100n is a highly sensitive system with a gravimetric resolution of 100 nanogram. It is designed for applications where only very small quantities of sample material are available like in pharmaceutical preformulation. Read more about the SPS23-100n...

    vapor sorption analyzer - SPS - glass lid open

    SPSx-1µ-Advance

    The SPSx-1µ Advance model shows best weighing peformance and a very high reproducibility of better than ±2µg at a gravimetric resolution of 1µg. Small and medium sized samples are measured at extremely high resolution over the full load range from 10mg up to 22g. Read more about the SPSx-1µ-Advance...

    vapor sorption analyzer - SPS - glass lid open

    SPSx-1µ-High-Load

    With its dual weight range, the SPSx-1µ High Load enables to analyze small samples at a very high resolution of 1µg (±5µg reproducibility) as well as samples heavier than 22g at a resolution of 10µg. In combination with the largest number of samples that can be measured simultaneously this system is the most versatile vapor sorption analyzer on the market. Read more about the SPSx-1µ-High-Load...

    Vapor Sorption Analyzer – SPS – Big Sample Pans

    SPS11-10µ

    The SPS11-10µ system is a robust and easy to operate multisample vapor sorption analyzer. With the large load range of the balance, the system is perfectly suited for the analysis of bulky or heavy samples and for permeability measurements. Typical fields of application are fertilizer, building materials and packaging material. Read more about the SPS11-10µ...

    Moisture Sorption Analyser - Vsorp

    Vsorp Enhanced

    The Vsorp Enhanced combines very high resolution of 1µg for small and medium samples up to 22g sample mass and 10µg for samples up to 220g sample mass. In combination with the 23 available sample positions, the Vsorp Enhanced is a powerful and versatile moisture sorption analyzer. Read more about the Vsorp Enhanced...

    Moisture Sorption Analyser - Vsorp

    Vsorp Plus

    The Vsorp Plus accomodates small and medium samples at a gravimetric resolution of 10µg for samples up to 220g sample mass. Additional samples trays such as for permeability measurements make this system a versatile moisture sorption instrument. Read more about the Vsorp Plus...

    Moisture Sorption Analyser Vsorp - 5 sample carousel

    Vsorp Basic

    The Vsorp Basic is a very robust and easy to operate multisample moisture sorption analyzer. With the huge load range of the balance and the large sample dishes, it accomodates even the biggest bulky or heavy samples. Typical fields of application fertilizer as well as building materials. Read more about the Vsorp Basic...

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      Water Vapour Sorption Analyzer SPS
      SPS11-10µSPSx-1µ High LoadSPSx-1µ AdvanceSPS23-100n

      Moisture Sorption Analyzer Vsorp
      Vsorp BasicVsorp PlusVsorp Enhanced

      Disposables, Accessories and Hardware Options
      Option Camera
      Option Raman Spectroscopy
      Permeability Kit 5 samples
      Permeability Kit 11 samples
      Permeability Kit Inverted Wet Cup
      Large Objects Kit
      Membrane Dryer
      Reference Material for Humidity Validation

      Optional Software Packages
      DVS Analysis Software
      21 CFR Part 11 compliant software package

      Humidity Generator MHG32
      MHG32Option TCOption 1000ml/min

      Humidity Generator MHG100
      MHG100

      Powder Conditioner
      Powder Conditioner

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        Please send me a quotation for

        item no.

        Description

        quantity

        package size

        100913

        sample dishes 18 mm

        box (100 pieces)

        100914

        sample dishes 33 mm

        box (100 pieces)

        100486

        sample dishes 50 mm

        box (100 pieces)

        100916

        sample dishes 86 mm

        box (100 pieces)

        101655

        distance pieces

        set (12 pieces)

        101867

        mesh cover 50 mm

        set (12 pieces)

        101596

        PTFE inserts

        set (12 pieces)

        100485

        secondary sample dishes 38 mm

        box (10 pieces)

        100910

        sample carousel 5 sample positions

        piece

        100908

        sample carousel 11 sample positions

        piece

        100909

        sample carousel 23 sample positions

        piece

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          Please send me the following Application Note / White paper

          Application Notes

          Food

          AN_20-01 Amorphous lactose in food
          AN_20-02 Amorphous fractions in sucrose and sucrose containing model food systems
          AN_20-03 Deliquescence and deliquescence lowering of food ingredients and blends
          AN_20-04 Dehydration behavior of bread crumb and crust

          Pharma

          AN_20-05 Amorphous lactose in the pharmaceutical industry
          AN_20-06 Hydrate formation of L-lysine HCl
          AN_20-09 Hydrate formation of creatine

          Building materials

          AN_20-07 Water vapor sorption of plaster
          AN_24-02 Water Vapor Permeability of Barrier Foils

          Permeability of Packaging material and Foils

          AN_12-01 Water vapor permeability of films
          AN_15-01 Water vapor sorption of product packages
          AN_24-01 Inverted-Wet-Cup: Water vapor permeability of packaging materials

          DVS Basics

          AN_17-01 Speed-vs-Accuracy
          AN_18-01 Humidity sensor calibration
          AN_18-02 MCC Reference-Certification
          AN_18-03 MCC Reference-Humidity Validation

          PowderConditioner: Moisture Equilibration

          AN_25-01 Powder Conditioner: Moisture Equilibration of Powders

          White Papers

          Universal

          WP_20-01 Amorphous content lactose

          Food

          WP_20-02 Amorphous fractions in sucrose and sucrose containing model food systems
          WP_20-03 Deliquescence and deliquescence lowering of food ingredients and blends

          Pharma

          WP_20-06 Hydrate formation of L-lysine HCl

          Permeability of Packaging material and Foils

          WP_24-03 Shelf-life calculation of dry food products

          DVS Basics

          WP_21-01 Moisture Sorption Isotherms

          DVS- Add ons
          WP_24-04 DVS in combination with in-line Raman measurements

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                Contract Analysis: Dynamic Vapor Sorption (DVS)
                Sorptions Isotherm, Sorptions KineticsPermeability, Water Vapor Transmission Rate (WVTR) of foils or packaging materials

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                MSAS Registration

                  The 12th MSAS will be held from 26th to 27th April 2023 in Ulm, Germany.

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