materialscience

2nd International Conference on

Materials Science and Engineering

June 14-15, 2024

Theme: Cutting-edge technologies, innovations in materials science and engineering
Days
Hours
Minutes
Seconds
Materials Science 2024 | WEBINAR

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Submit your abstract and get Early Bird Registration Slot only at $99…

Why to choose Sciencezo Planet

Webinar & Conferences

WHAT WE DO?

Sciencezo Planet Conferences organizes conferences, meetings, seminars and workshops with the ingenious and peerless speakers throughout the world providing you and your organization with a broad range of networking opportunities to capitalize on the knowledge of practicing members across several disciplines to understand the impact of science in modern world.

WHO WE ARE?

Sciencezo Planet Conferences provides an opportunity for leading academicians, scientists, researchers, doctors, medical practitioners, nurses and various industry professionals from around the world to network and have scientific discussion on the latest advancements and interlinked domains in science, medicine and health.

WHAT IS OUR VISION?

Sciencezo Planet is proficient in organizing conferences, meetings, seminars and workshops with the ingenious and peerless speakers throughout the world providing you and your organization with a broad range of networking opportunities to globalize your research and create your own identity in the scientific community.

WHAT IS OUR MISSION?

Our main mission is to make our conferences highly successful with high quality interactive technical sessions with recent research findings of the latest and futuristic trends exposed as we focus on providing workshops and symposiums organized through well-established industrial and academic tie-ups with various professional bodies.

Confirmed

Speakers

Pham Trung Kien

Ho Chi Minh City University of Technology, Vietnam
Ho Chi Minh City University of Technology, Vietnam

Wei Chen

University of Texas at Arlington, USA
University of Texas at Arlington, USA

Feng Wu

Kunming University of Science and Technology, China
Kunming University of Science and Technology, China

Murtadha Zahi

Samawa investment University, Iraq
Samawa investment University, Iraq

Thomas George

Karunya Deemed University, India
Karunya Deemed University, India

Scientific

Sessions

Microstructure refers to the small-scale structure and arrangement of materials at the microscopic level, typically on the order of micrometers to nanometers. This can include features such as grain size, distribution of phases or inclusions, and defects like voids or cracks. Microstructure plays a significant role in determining the physical, mechanical, and chemical properties of a material, as well as its performance in various applications.

Advanced electron microscopy (EM) refers to a range of techniques that utilize electron beams to image and analyze materials at the nanoscale. Compared to traditional light microscopy, EM has much higher resolution, allowing for the observation of atomic-level details.

Heat-treatment is a process of heating and cooling a material in a controlled manner to alter its physical and mechanical properties. It is often used to improve the material’s hardness, strength, ductility, and other properties for specific applications. The heat-treatment process typically involves heating the material to a specific temperature, holding it at that temperature for a set time, and then cooling it at a controlled rate. The specific parameters used in heat-treatment depend on the material being treated and the desired properties.

Corrosion is a natural process that occurs when a material reacts with its environment, such as water or air, and undergoes a chemical or electrochemical reaction that results in the deterioration of its properties. Corrosion can lead to a range of issues, from aesthetic damage to the material to significant structural failure, making it a significant concern in various industries.

Additive manufacturing, also known as 3D printing, is a process of creating three-dimensional objects by layering materials, typically using a digital model as a guide. Unlike traditional manufacturing methods, which involve cutting or shaping a material to create a final product, additive manufacturing builds up a part layer by layer, allowing for more intricate designs and greater customization.

Metal joining technologies refer to the methods used to combine two or more pieces of metal into a single, cohesive structure. Advances in metal joining technologies have led to improvements in efficiency, durability, and cost-effectiveness in a wide range of industries, from aerospace and automotive to electronics and construction.

Surface engineering refers to the process of modifying the surface properties of a material to improve its performance, durability, or functionality. Surface engineering can involve changing the material’s composition, texture, or structure, as well as adding a coating or modifying the surface chemistry. The goal of surface engineering is to enhance the material’s surface properties without altering its bulk properties

Failure analysis is the process of investigating the causes of a material or component failure, with the goal of understanding how and why it failed and how to prevent similar failures in the future. Failure analysis typically involves examining the failed material or component, analyzing the conditions under which it failed, and identifying any design or manufacturing defects that may have contributed to the failure.

Non-destructive evaluation (NDE) is a set of techniques used to inspect materials and components without damaging them. NDE techniques are typically used to detect defects, such as cracks or voids, that could lead to failure if left undetected. Some examples of NDE techniques include ultrasonic testing, X-ray inspection, and magnetic particle inspection. NDE techniques are commonly used in industries like aerospace, automotive, and manufacturing to ensure the quality and safety of materials and components.

Ferrous process metallurgy refers to the study and manipulation of the physical, chemical, and mechanical properties of iron and steel alloys. This field encompasses a wide range of processes, including production, refining, and shaping of iron and steel products.

The process of ferrous metallurgy involves several steps, including:

  1. Iron production: Iron is typically produced from iron ore in a blast furnace, where the ore is melted and reduced with carbon to produce pig iron.

  2. Steelmaking: Pig iron is refined into steel through various methods, such as basic oxygen furnace (BOF) or electric arc furnace (EAF), where impurities are removed and the desired properties are introduced.d.

Nonferrous extractive metallurgy refers to the extraction and purification of metals from ores that do not contain iron, such as copper, aluminum, nickel, and zinc. The process of nonferrous extractive metallurgy involves several steps, including:

  1. Ore preparation: The ore is crushed and ground into a fine powder to increase the surface area for chemical reactions.

  2. Mineral processing: The ore is then separated from the gangue minerals using various techniques, such as flotation, gravity separation, or magnetic separation.

The design and development of advanced alloys involves creating materials with improved properties, such as increased strength, ductility, corrosion resistance, and wear resistance. Advanced alloys are used in various industries, including aerospace, automotive, medical, and energy, where high-performance materials are essential.

Green steel technologies refer to the production of steel in an environmentally sustainable and socially responsible manner. This involves reducing greenhouse gas emissions, minimizing the use of non-renewable resources, and promoting circularity in the steel production process.

Hydrogen can potentially play a significant role in steel making as a green energy source, as its use in the steel-making process can significantly reduce greenhouse gas emissions. Hydrogen can be used as a reducing agent in the blast furnace or as a direct energy source in the electric arc furnace (EAF).

Materials informatics is an interdisciplinary field that combines materials science, data science, and computer science to develop and apply methods for materials discovery, design, and optimization. It involves the use of data-driven approaches, such as machine learning, to accelerate the discovery and development of new materials with desired properties.

Causes and Consequences of Genomic Instability 

Conference

Schedule

DAY-1

June 14, 2024
  • 09:00-09:30 Opening Ceremony and Introduction
  • 09:30-10:30 Keynote Session I
  • 10:30-11:00 Refreshment Break
  • 11:00-12:30 Keynote Session II
  • 12:30-13:30 Lunch
  • 13:30-15:00 Break Out Session I
  • 15:00-15:30 Refreshment Break
  • 15:30-18:00 Break Out Session II
Webnair

DAY-2

June 15, 2024
  • 09:00-09:30 Opening Ceremony and Introduction
  • 09:30-10:30 Keynote Session I
  • 10:30-11:00 Refreshment Break
  • 11:00-12:30 Keynote Session II
  • 12:30-13:30 Lunch
  • 13:30-15:00 Break Out Session I
  • 15:00-15:30 Refreshment Break
  • 15:30-18:00 Break Out Session II
Webnair

Important

Dates

Abstract Submission

March 30, 2024

March 30, 2024

First round submission deadline: March 30, 2024

Early Bird Registration (Open)

March 30, 2024

March 30, 2024

Early bird registration deadline: March 30, 2024

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