搜索关注在线英语听力室公众号:tingroom,领取免费英语资料大礼包。
(单词翻译)
Most college students in the United States choose their major, or main field of study for their degree, before or during their first year.
For Saskia Fagan, making that choice was not easy.
Fagan, who is now 31 years old, grew up in Takoma Park, Maryland. From an early age, she loved animals. So when she began studying at Frostburg State University in Frostburg, Maryland in 2004, she expected to become a dog trainer.
However, Frostburg State did not offer any degree programs related1 to dog training. Fagan chose to study psychology2, instead. A few months later, she changed her major to biology.
But then she decided3 she did not want to spend her life working in a laboratory4. In her second year, she changed majors to another field of interest: fine art.
After two years of studying fine art, however, Fagan felt that she preferred art as something she did for pleasure, not for work. So she made one final change into a field called liberal5 studies. That field let her design a major based around a mix of different subjects.
Fagan finally completed her degree program in 2011 – seven years after she had started. The cost of adding extra time to earn a degree created some problems, she says. But, she adds, taking the time to find the perfect field also helped lead her to a career she has found very satisfying.
Fagan is now a map designer.
“It’s really important to know what you don’t want to do,” she told VOA. “If anything, those are great learning6 experiences, too, whether that’s a major that you tried and didn’t like or job that you had for a year and you thought, ‘This is not for me.’ If anything, those are just as valuable as knowing what path you want.”
Changing majors in the U.S.
Fagan’s experience is common in American higher education. About one third of college students in the U.S. change majors at least once. And many who do so began in science, technology, engineering7 and math – in other words, STEM8 fields.
In December, the U.S. Department of Education’s National Center for Education Statistics9 released10 a study on students who changed majors. The study looked at 25,000 college students who entered into degree programs for the first time in 2011.
By 2014, about one in three first-time students seeking bachelor’s degrees changed majors. One in ten changed majors more than once.
In addition, the study found that students in STEM fields are about 6 percent more likely to change majors than non-STEM students.
Tracy Hunt-White is one of the researchers who worked on the study. She points out that an earlier study found about one third of STEM students who changed majors left the STEM fields completely. They chose non-STEM related majors instead. The most recent study found that students who start in mathematics are the most likely to change, with 52 percent choosing another field.
Hunt-White says she could not comment on the reasons students make these changes. But National Science Teachers Association11 executive12 director David Evans says he might have some idea why. He says the reason may be, in large part, due to the differences in teaching13 styles of STEM educators at the high school and university levels.
High school math and science classes are often much smaller than they are at colleges and universities. So the students often feel they have a more personal connection to the subjects they are studying, and therefore their teachers as well, he says.
And, Evans says, many professors feel college-level STEM classes should be difficult enough to make some students want to leave those fields.
“There’s sort of a historic14 culture, often times in university education, especially in science and math, to think of the early courses … as being screening courses where the idea is you find out which students are ‘good enough’ to get through those courses,” he told VOA. “And so instead of being an educational regime15 that encourages students, it’s one that really filters16.”
Evans argues that as technology becomes a bigger part of everyday life, it is going to be only more important to understand STEM-related subjects. He says that, as a result, educators will have to learn to be more inclusive17. Also, they will need to find ways to make the material they are teaching more relatable.
Another big difference between high school and college-level STEM education is the way material is covered, Evans says. Once students enter the college level in mathematics, for example, they face much more abstract18 ideas. Evans suggests that college professors do not always do the best job of explaining how students will use these ideas in real world situations.
Also, he says, many college STEM courses test students on how well they remember these complex ideas, not how well they understand them.
The National Science Teachers Association released a series of suggestions for STEM teachers five years ago. They are for teachers at every level and discuss how to address the issues that Evans suggests make STEM fields so discouraging.
Many STEM educators across the United States have begun to follow these suggestions, he says. The goal is to make sure that plenty of Americans stay in these fields throughout their entire education.
“There’s no single thing that we could do, with one possible exception,” he said. “And that is, I think that if we could do something that would allow for … more time to be spent on STEM courses for elementary school children, that … might actually make a big difference.”
Not everyone who majors in a STEM field in college goes on to work in that field. Yet Evans feels that if they start their STEM education early enough, that might keep students like Fagan interested as they progress. Then they can bring much-needed STEM knowledge along with them on whatever career path they take.
I’m -Pete Musto. And I’m Alice Bryant.
Words in This Story
major – n. the main subject studied by a college or university student
bachelor’s degree(s) – n. a degree that is given to a student by a college or university usually after four years of study
course(s) – n. a series of classes about a particular subject in a school
screening – n. the act of examining people or things in order to decide if they are suitable for a particular purpose
regime – n. a system of management
encourage(s) – v. to make someone more determined19, hopeful, or confident
filter(s) – v. to remove something unwanted
abstract – adj. relating to or involving general ideas or qualities rather than specific people, objects, or actions
allow for – p.v. to make something possible
elementary school – n. a school in the U.S. for young children
1 related | |
adj.有关系的,有关联的,叙述的,讲述的 | |
参考例句: |
|
|
2 psychology | |
n.心理,心理学,心理状态 | |
参考例句: |
|
|
3 decided | |
adj.决定了的,坚决的;明显的,明确的 | |
参考例句: |
|
|
4 laboratory | |
n.实验室,化验室 | |
参考例句: |
|
|
5 liberal | |
adj.心胸宽阔的;自由(主义)的;慷慨的 | |
参考例句: |
|
|
6 learning | |
n.学问,学识,学习;动词learn的现在分词 | |
参考例句: |
|
|
7 engineering | |
n.工程,工程学,管理,操纵 | |
参考例句: |
|
|
8 stem | |
n.茎,干,船首,词干,血统;vt.堵住,阻止,抽去梗;vi.起源于,发生 | |
参考例句: |
|
|
9 statistics | |
n.统计,统计数字,统计学 | |
参考例句: |
|
|
10 released | |
v.释放( release的过去式和过去分词 );放开;发布;发行 | |
参考例句: |
|
|
11 association | |
n.联盟,协会,社团;交往,联合;联想 | |
参考例句: |
|
|
12 executive | |
adj.执行的,行政的;n.执行者,行政官,经理 | |
参考例句: |
|
|
13 teaching | |
n.教学,执教,任教,讲授;(复数)教诲 | |
参考例句: |
|
|
14 historic | |
adj.历史上著名的,具有历史意义的 | |
参考例句: |
|
|
15 regime | |
n.政体,政权,制度 | |
参考例句: |
|
|
16 filters | |
过滤( filter的名词复数 ); 滤光器; (香烟头上的)过滤嘴; 交通红灯指示不得直行的同时 | |
参考例句: |
|
|
17 inclusive | |
adj.(of)包括的,包含的;范围广的 | |
参考例句: |
|
|
18 abstract | |
adj.抽象的;n.摘要,梗概;vt.提取;摘录要点 | |
参考例句: |
|
|
19 determined | |
adj.坚定的;有决心的 | |
参考例句: |
|
|
本文本内容来源于互联网抓取和网友提交,仅供参考,部分栏目没有内容,如果您有更合适的内容,欢迎 点击提交 分享给大家。