CDR Sample for Materials Engineers

Materials Engineers with a Bachelor’s Degree or higher can assess their engineering qualification. Materials Engineers are the engineers who develop materials such as metals and semiconductors with striking combinations of chemical, mechanical and electrical properties that make the other advances conceivable. It is one of the most basic and essential engineering subjects. Materials Engineers are in very high demand by several reputed technical organizations in Australia. They require Materials Engineers with high skills and qualifications from Australia as well as other nations over the world.

CDR sample for Materials Engineers includes all the required reports such as Curriculum Vitae (CV), Continuing Professional Development (CPD), three Career Episodes (CE), and Summary Statement. The content of the CDR Report Samples is given below:

Curriculum Vitae (CV)

Resume on the basis of a professional template.

Continuing Professional Development (CPD)

The sample of CPD clarifies the Engineering Knowledge of the applicant – 350 words.

Materials Engineer Career Episode Sample 1

“The Fabrication and Study of PET/PTT Sheath-Core Monofilaments with Large Diameter Using a Single-Step Coaxial Melt-Spinning” – 1986 words

Materials Engineer Career Episode Sample 2

“Red Light Controllable Liquid-Crystal Soft Actuators via Low-Power Excited Up Conversion Based on Triplet- Triplet Annihilation”– 2588 words

Materials Engineer Career Episode Sample 3

“New Methods for Repairing Line Edge Roughness in Lithography Nano Patterns Using Innovatively Designed Block Copolymer with a High Level of Functionality” – 2230 words

Materials Engineer Summary Statement Sample

Detail explanation of all the competency element – 2246 words.

Materials Engineers Career Episode Sample 1

Project Name: The Fabrication and Study of PET/PTT Sheath-Core Monofilaments with Large Diameter Using a Single-Step Coaxial Melt-Spinning

In first Career Episode, the author describes the project she did when she was pursuing an undergraduate degree in Material Science and Engineering in her final year.

The name of the project was “The Fabrication and Study of PET/PTT Sheath-Core Monofilaments with Large Diameter Using a Single-Step Coaxial Melt-Spinning” and her responsibilities were:

To eradicate the molecules of water present inside the provided PET and PTT polymers.
To measure several essential parameters which help in the demonstration of the behavior of thinning shear.
To make the analysis on the effect of extrusion temperatures of the core layer along with sheath layer.
To make an analysis of the diverse material properties of the resulting monofilaments.
To conduct a particular test of evaluation dealing with the mechanical properties of PET/PTT by using the mechanical

Materials Engineers Career Episode Sample 2

Project Name: Red Light Controllable Liquid-Crystal Soft Actuators via Low-Power Excited Up Conversion Based on Triplet- Triplet Annihilation

In second Career Episode, the author explains the engineering skills she used in the project she was involved in for international liquid crystal elastomer conference.

Her duties and responsibilities in the project “Red Light Controllable Liquid-Crystal Soft Actuators via Low-Power Excited up Conversion Based on Triplet- Triplet Annihilation” were:

To learn in detail about the several aspects needed for the fulfillment of this project such as Photoisomerization of Azobenzene Chromophore, cross-linking of polymers, soft actuator materials and their behavior upon irradiation and triplet-triplet annihilation.
To obtain highly pure monomers and cross linkers through multiple steps of organic synthesis, using which azobenzene containing cross-linked crystalline polymer film (CLCP) was prepared.
To design and synthesize a novel up-conversion material system which contained “9, 10-BDPPA” as the Annihilator and Platinum (II) complex “PtTPBP” as the activator (fluorescent dye).
To perform an experiment to confirm the hypothesis that PtTPBP & BDPPA would release upconversion and the absorption of this release by the azololane moieties would result in the triggering of their trans-cis photoisomerization.
To incorporate PtTPBP and BDPPA into polyurethane that has a low transition temperature of the glass so as to fully support the possibility of low-power upconversion luminescence in applications in real life.
To integrate polyurethane consisting PtTPBP and 9, 10-BDPPA and the azotolane Cross Link Crystal Polymer film to the adhesive that was transparent to make the adhesive film by the use of spin-coating technology.
To use a thermal imaging camera so as to record thermal effect caused by CW 635 nm laser on the polymer material.

Materials Engineers Career Episode Sample 3

Project Name: New Methods for Repairing Line Edge Roughness in Lithography Nano Patterns Using Innovatively Designed Block Copolymer with a High Level of Functionality

In the third Career Episode, the author demonstrates the technical skills she used to accomplish the project she was involved in during her bachelor’s degree in Material Science and Engineering.

The name of the project was “New Methods for Repairing Line Edge Roughness in Lithography Nano Patterns Using Innovatively Designed Block Copolymer with a High Level of Functionality” and her roles were:

To acquire adequate training in relation to the Occupational Health and Safety (OH&S) particularly focused on fire safety before working in the lab.
To study the aqueous solution behavior of polymers that are already discovered using several advanced material characterization technologies.
To prepare a simple photopolymer poly (4-acetoxyrene) through the method of living polymerization.
To treat the patterns of photoresists with designed block copolymer and prepared polymers to decrease the roughness of line edge.
To incorporate a hydrophobic functional group to exposed material and achieve the so-called neutral substrate.
To prepare an OEGMA-based multi-responsive hydrogel for readily dispersing of block polymer water and self-assembling into particles with size less than 10 nanometers.