Given our rapid societal change, the ability to solve problems using interdisciplinary knowledge and skills is becoming increasingly important. To support these educational needs, many international countries have adopted STEM/STEAM education as a core learning platform. However, the fundamental differences of problem-solving strategies within the STEM/STEAM disciplines influence students’ cognitive structures and problem-solving strategies. To investigate the various problem-solving strategies used by science and engineering (technology) students, the researcher recruited six high school students, three from engineering courses and three from science courses. The participant students were taught a STEM/STEAM unit, but the engineering group had only participated in the physical modeling process. After completing the STEM/STEAM lessons, the two groups were given a design task with a structure similar to the integrated lessons. To assess the mental strategies of students, the researcher used the Concurrent-Think Aloud protocol and the seven of Halfin’s codes. The results showed that the engineering students tended to use a variety of problem-solving strategies, while the science students concentrated on solution-oriented strategies. The researcher also confirmed that the engineering students showed various design iterations by revisiting the problem identification process throughout the design process. However, the science students tended to show a limited number of iterations. The design outcomes also showed that the science students yielded many innovative design ideas but failed to provide details for their design solutions. When instructing STEM/STEAM lessons, educators need to utilize authentic instructional strategies to improve students’ integrative problem-solving abilities.