top of page

WHAT PATHS?

PATHWAYS

Physical Science & Engineering

Students interested in engineering find themselves immersed in creativity, science, technology, and problem-solving. Engineering demands a solid foundation in science, math, engineering technology, and computing. Prospective engineers can forsee themselves inventing, designing, analyzing, building and testing machines, complex systems, structures and materials to fulfill functional objectives and requirements while considering the limitations imposed by practicality, regulation, safety and cost.

AT A GLANCE  

IS THIS YOU?

  • I like the environment and would like to protect it.

  • I like contributing to my community through my work.

  • I like the satisfaction of completing projects.

  • I like to problem solve.

  • I like working with my hands.

  • I like to use my creativity to design and build things.

  • I am entrepreneurial.

  • I aspire to become self-reliant.

  • I find technology exciting.

  • I want to have a variety of tasks and locations in my work.

Kids in Art Class
CONDUCTING
Research
Living Room Sketch
PIONEERING NEW Discoveries
Image by Christian Joudrey
DESIGNING WITH COMPUTER Software
Anchor 1
Anchor 1

Explore the Different Possibilities

Check out the specific concentrations within this interest cluster, with information regarding specific careers, as well as potential majors to pursue in college!

Aerospace, Aeronautical and Space

This ever-growing field features the design and operation of air and spacecraft, including the intricacies of how flight works.

Potential Majors

CONCENTRATION IN
Agricultural Engineering

Apply engineering science to agricultural production and farming. Combines elements of mechanical, civil, and chemical engineering with animal and plant biology.

Potential Majors

CONCENTRATION IN
Biomedical Engineering

Apply engineering principles and technology to the field of medicine, creating new and improved medical treatments for patients. Tissue engineering, while also considered a specialization within biotechnology, is one such example of biomedical engineering in action.

Potential Majors

CONCENTRATION IN
Civil Engineering

Deals primarily with the design, construction and maintenance of bridges, roads, canals, and the like. As a point of interest, this engineering discipline was enshrined to distinguish itself from military engineering. It is considered the second-oldest discipline, after military.

Potential Majors

CONCENTRATION IN
Computer Engineering

Combines computer science and electronic engineering. Computer engineers design both computer software and computer hardware, in addition to developing solutions for the integration of the two.

Potential Majors

CONCENTRATION IN
Electrical Engineering

The study and application of electromagnetism, electronics, and electricity. It's a broad-based discipline that encompasses the design and implementation of various electronic / electrical systems such as circuits, generators, motors, and transformers.

Potential Majors

CONCENTRATION IN
Environmental Engineering

The application of scientific principles to environmental improvement. Generally speaking, this discipline attempts to provide healthy air, water and land for safe habitation. Additionally, this particular discipline attempts to find ways to reverse environmental damages caused by pollution.

Potential Majors

CONCENTRATION IN
Industrial Engineering

Development and ongoing improvement of integrated systems. Industrial engineers seek to minimize waste and maximize efficiency by tweaking current production systems.

Potential Majors

CONCENTRATION IN
Manufacturing Engineering

Deals almost exclusively with the design and maintenance of different manufacturing processes, tools, equipment and machines. Lean manufacturing principles are one such example of scientific manufacturing in action.

Potential Majors

CONCENTRATION IN
Material Engineering

Concerned with the properties of matter and its application to science and technology. This generally refers to the study of the structure of materials at the molecular level, and includes elements of applied physics and chemistry. Nanotechnology is one such example of materials engineering in action.

Potential Majors

CONCENTRATION IN
Mechanical Engineering

Primarily concerned with the design, production and use of tools and machines. Mechanical engineers are the inventors and builders of the machines that will shape our future.

Potential Majors

CONCENTRATION IN
Physics

For the student that seeks to explore and explain fundamental questions that range from understanding the origin of the universe, including string theory, cosmology, and astrophysics, to understanding the visible world of colloids and the world on an ever diminishing scale, from the mesoscale to the nanoscale, condensed matter, and atomic, molecular and particle physics.

Potential Majors

CONCENTRATION IN
Structural Engineering

For the future engineering aiming to analyze, design, simulate, visualize, optimize, monitor and assess the behavior and environmental interactions of structures and structural materials from a holistic perspective, including those used in civil, geotechnical, aerospace, naval, marine, energy, and biological applications.

Potential Majors

CONCENTRATION IN
​Nuclear Engineering

Primarily concerned with finding practical applications of nuclear energy. This includes the development and maintenance of nuclear reactors, power plants, and weapons.

Potential Majors

CONCENTRATION IN

ROADMAPS

Anchor 1

Connect with Alumni or a Senior Mentor

Check out how our alumni students and current seniors are pursuing this pathway! Learn about what it takes. To learn more about an alumni's journey, check out their roadmap.

Zoe Monterola
Class of 2021
Undergraduate student
Materials Science Engineering with concentration in Tech Management, UCLA, 2025
Cristian Rene Cardenas
Class of 2011
Development professional for an international nonprofit high tech accelerator
Biotechnology, UC Davis, Bioscience, Keck Graduate Institute
Anthony Mouchawar
Class of 2020
Undergraduate student
Biomedical Engineering, Emphasis in Molecular-Cellular Engineering, USC
Diana Renteria
Class of 2018
Undergraduate student
Biological Engineering, Massachusetts Institute of Technology
Olaolu Dada
Class of 2019
Undergraduate student
Computer Science, Georgia Institute of Technology
Tyler Moroso
Class of 2016
Undergraduate student
Electrical Engineering & Computer Science, MIT
Kusal Uprety
Class of 2020
Undergraduate Student
Aerospace Engineering, UCSD
Andrew Euredjian
Class of 2017
Undergraduate student
Robotics Engineering/Computer Science, Worcester Polytechnic Institute
Shane Monney
Class of 2021
Undergraduate student
Mechanical Engineering, UCLA
Robin Kim
Class of 2020
Undergraduate Student
Civil Engineering, UC Berkeley
Scout Heid
Class of 2013
Product Design Engineer at Amazon
Mechanical Engineering, UC Berkeley, minor in EECS & Experimental Controls
Katelyn Sulett
Class of 2020
Undergraduate student
Aerospace/Astrophysics Engineer, CalTech
Anchor 1
GENERAL ADVICE FOR THIS PATHWAY

Engineering is a calculus-based curriculum. If you want to get into top engineering schools, it's important to have a solid foundation in math. 

If you take any SAT Subject Tests, it’s important to take and get a high 700 on the SAT Math II Subject Test (preferably 800) to demonstrate you’re strong in Math beyond what’s covered on the SAT or ACT. Getting a perfect or high score Physics or any other science Subject Test as well isn’t required, but it also will help your application.

The key to getting accepted to selective engineering institutions is to build up a “spike” in a certain area. For engineering schools, this area is math and/or science.

bottom of page