DMA THERMAL ANALYSIS OF PLANT TISSUE

Slides:

Advertisements

Similar presentations

1 Anisotropic characteristics of wood dynamic viscoelastic properties Jianxiong Lu, Fucheng Bao and Jiali Jiang Key Laboratory of Wood Science and Technology.

Advertisements

Thermal Analysis Differential Scanning Calorimetry (DSC) – Measure heat absorbed or liberated during heating or cooling Thermal Gravimetric Analysis (TGA)

Dynamo-Mechanical Analysis of Materials (Polymers)

SHINSHU UNIVERSITY Shinshu University Nano Fusion Technology Research Group Study on the poly(1-butene) fibrous membrane via electrospinning Daisuke Kimura.

Preparation of Single Pulp Fibres for Dynamic Mechanical Analyses Using a Microrobotic Platform Trabzon, Steffen Baasner.

Member of the Helmholtz Association Takeshi Hirai | Institute of Energy Research | Association EURATOM – FZJ Cracking of a tungsten material exposed to.

Abcit Characterization of Polyammides. abcit 3 methods p Infrared Spectroscopy p Differential Scanning Calorimetry p Dynamic Mechanic Analysis.

Viscoelastic materials

Results References [1].Mendoza, J. D. Lab 9: Dynamic Mechanical Analysis, Iowa State University Time-Temperature Superposition (TTS) Using DMA Acknowledgments.

Molecules of Life The stuff we’re made of. Water The human body is mostly water –Lean muscle: 75% water –Blood: 83% water –Body fat: 25% water –Bone:

Four Major Types of Biological Macromolecules

Unit 19 Measurements of strain, stress, and coil mechanical properties

Cell Biology: Cell Compounds and Biological Molecules Lesson 3 – Carbohydrates and Lipids ( Inquiry into Life pg )

Characteristics of Life Growth and development Cellularity Reproduction Responsiveness Movement Require energy.

THE COMPOUNDS OF LIFE.

2.3 Carbon-Based Molecules KEY CONCEPT Carbon-based molecules are the foundation of life.

Transport in Vascular Plants Chapter 36. Transport in Plants Occurs on three levels:  the uptake and loss of water and solutes by individual cells 

© SSER Ltd.. Membrane Structure All biological membranes are composed mainly of lipid and protein molecules PHOSPHOLIPIDS – the most abundant CHOLESTEROL.

Crystallinity in Polymers

3 Physical Properties of Biomaterials CHAPTER

Are you what you eat? 1. The important Characteristics of Carbon Forms 4 covalent bonds Forms double and triple bonds Forms long chains and rings Can.

Chapter 36: Transport in Plants.

DSC Differential Scanning Calorimetry

Department of Tool and Materials Engineering Investigation of hot deformation characteristics of AISI 4340 steel using processing map.

Chemistry of Cells. Has nothing to do with being naturally occurring!!

Dynamic-Mechanical Analysis of Materials (Polymers)

Reporter: Yu-Syuan Lu Advisor: Wei-Tong Liao Date:05/18/2011.

Cell Biology: Cell Compounds and Biological Molecules Lesson 3 – Carbohydrates and Lipids ( Inquiry into Life pg )

BIOLOGY CONCEPTS & CONNECTIONS Fourth Edition Copyright © 2003 Pearson Education, Inc. publishing as Benjamin Cummings Neil A. Campbell Jane B. Reece Lawrence.

Consequences of Calcination: A characterisation of composites Ashutosh Naik.

2.3 Carbon-Based Molecules KEY CONCEPT Carbon-based molecules are the foundation of life.

A novel approach for thermomechanical analysis of stationary rolling tires within an ALE-kinematic framework A. Suwannachit and U. Nackenhorst Institute.

《Modern Research Methods in Polymer Science》

Objective: Students will be able to know and understand the meristematic tissues and permanent tissues of a plant.

Damping Capacity Investigation of some Copper based alloys through Thermal Analysis PhD student Nicanor Cimpoesu Faculty S.I.M. Iai.

BY DAVID SEHGAL. What is DMA?  DMA is a measuring instrument which is used to determine the dynamic characteristics of materials.  It applies a dynamic.

9.2: Transport in the phloem

SORPTION ISOTHERMS CONSTRUCTION & EVALUATION Jiri Blahovec, Stavros Yanniotis.

Dynamic Mechanical Properties of MWCNT/CoFe 2 O 4 Reinforced PEEK Composites Wyoming NSF/EPSCoR Undergraduate Research Fellowship, Summer 2010 Undergraduate.

Polymer Properties Exercise 4.

Thermal Analysis.

Beijing Institute of Technology

Dynamic mechanical analysis

Two Organic Biomolecules:

Linseed oil + Styrene + Divinylbenzene

Thermal Analysis Differential Scanning Calorimetry (DSC) – Measure heat absorbed or liberated during heating or cooling Thermal Gravimetric Analysis (TGA)

Roles of Models in Study of Agricultural Material

Mechanical Properties

Date of download: 11/9/2017 Copyright © ASME. All rights reserved.

Wide Frequency Dependence of Impedance, Electric Modulus and Conductivity of Lead-Free Ba0.5Sr0.5Ti(1-X)InxO3 Ceramics H.Z. Akbas1, Z. Aydin1, A.Colak1,

The 9th international Conference for Basic Sciences

Ch. 6 Biochemistry Biological Macromolecules

THERMOMECHANICAL PROPERTIES OF VEGETABLE TISSUE AT oC

Lipids Hydrophobic Not considered polymers Fats aka triglycrides

Lecture 5 Organic Compounds

CHAPTER 36 TRANSPORT IN PLANTS.

Organic Compounds Compounds that contain CARBON are called organic

Lecture 7 – Water Potential

Resource Acquisition and Transport in Vascular Plants

Dynamic-Mechanical Analysis of Materials (Polymers)

Lecture 7 – Water Potential

Organic Macromolecules Foldable Notes

Lecture 7Announcements

Biological Macromolecules Notes

ORGANIC MACROMOLECULES DENA DUPREE BIOLOGY BLOCKS 1,2,3, & 4

Characterizing and Analyzing 3D printed Smart Composites

Lecture 7 – Water Potential

Biological Macromolecules

Thermal Analysis Techniques

The Cell Membrane.

Presentation transcript:

DMA THERMAL ANALYSIS OF PLANT TISSUE Jiří Blahovec

Thermal Analysis of Materials … developed out of the scientific study of the changes in the properties of a sample which occur on heating. Haines, 2002

BASIC THERMAL METHODS Differential scanning calorimetry DSC Differential thermal analysis DTA Thermomechanical analysis TMA Dynamic mechanical Analysis DMA Dielectric thermal analysis DETA Thermogravimetry TG … study of changes in structure and mechanisms …

HOW TO APPLY THEM TO BIOOBJECTS?

SIMPLE POTATO CELLULAR STRUCTURE Symplast Apoplast Cellular walls

SCHEME OF CELLULAR MEMBRANE Polar hydrophilic side Hydrophobic sides Lipid Double Layer symmetrical Pore – Based on Proteins source of asymmetry

COMPLICATED STRUCTURE caused COMPLICATED THERMAL RESPONSE

MECHANICAL PROPERTIES and cell walls

POTATO Compression at room temperature Squeezing out ~ 3 %

POTATO Slope analysis True slopes: I Variable, flaccid tissue II about 3 MPa, quasi-elastic III (1.54±0.13) MPa, sap squeezing out

TISSUE RIGIDITY

GOOD BASIS FOR DYNAMIC MECHANICAL ANALYSIS (DMA) OF VEGETABLE TISSUE

TYPES OF LOADING

DMA PARAMETERS Specimen dimensions: length 22 mm width 8 mm thickness 3 mm Distance between jaws 4.4 mm Amplitude 1 mm (it corresponds to 3 % quasi-elastic deformation) Frequency 1 Hz Temperature Range 30-90 oC Heating Rate 1 oC/min Tissues: Potato (cork, pith and side with vascular ring), Carrot Tests were done in air with 90 % humidity !

POTATO The important starch effect

STORAGE MODULUS

LOSS MODULUS

LOSS TANGENT (LM/SM)

STORAGE MODULUS (Slope Analysis – 10 replications)

LOSS MODULUS (Slope Analysis – 10 replications)

LOSS TANGENT (Slope Analysis – 10 replications)

POTATO PITH AND CORTEX AT ROOM TEMPERATURE (a) pith (b) cortex Starch grains Protein micelles Cell wall Arranged under Karlsson & Eliasson (2003), LWT 36, 735-741.

STARCH CHANGES First Heating POTATO STARCH CHANGES First Heating Arranged under Ratnayake & Jackson (2007) Carbohydrate Polymers 67, 511-529. Gelatinization Tissue DMA Peak

POTATO STARCH CHANGES Shear Rheology X-Ray Diffraction Arranged under Ratnayake & Jackson (2007) Carbohydrate Polymers 67, 511-529. Kaur et al. (2002), Food Chemistry 79, 183-192 Shear Rheology X-Ray Diffraction Partial Crystallinity Crystallinity (%) Nearly amorphous 10 45 Partial Crystallinity 45

POTATO STARCH CHANGES Swelling Arranged under Li & Yeh (2001) J. Food Eng. 50, 141-148

CARROT A representative of standard plant tissue

ELASTIC MODULE

ELASTIC MODULE (Slope Analysis – 10 replications) Indications of further temperature dependent changes

LOSS TANGENT (Slope Analysis – 10 replications) Indications of further temperature dependent changes

CONCLUSIONS Deformation of potato tubers at temperatures higher than 60oC is controlled by starch gelatinization and swelling, DMA detects gelatinization in state in which the thermally controlled processes detected by DSC are finished, DMA is able to detect further cell wall changes connected with cell wall semi-permeability

THANK FOR YOUR ATTENTION!