Equity for women and underrepresented minorities in STEM: Graduate experiences and career plans in chemistry


Equity for women and underrepresented minorities in
STEM: Graduate experiences and career plans
in chemistry
Jean Stockarda, Celeste M. Rohlfingb, and Geraldine L. Richmondc,1

aDepartment of Planning, Public Policy and Management, University of Oregon, Eugene, OR 97403; bCommittee on the Advancement of Women Chemists
(COACh), University of Oregon, Eugene, OR 97403; and cDepartment of Chemistry, University of Oregon, Eugene, OR 97403

Contributed by Geraldine L. Richmond, November 20, 2020 (sent for review October 7, 2020; reviewed by Arthur Bienenstock and Victor McCrary, Jr.)

Recent events prompted scientists in the United States and
throughout the world to consider how systematic racism affects
the scientific enterprise. This paper provides evidence of inequities
related to race–ethnicity and gender in graduate school experi-
ences and career plans of PhD students in the top 100 ranked de-
partments in one science, technology, engineering, and math
(STEM) discipline, chemistry. Mixed-model regression analyses
were used to examine factors that might moderate these differ-
ences. The results show that graduate students who identified as a
member of a racial/ethnic group traditionally underrepresented in
chemistry (underrepresented minorities, URM) were significantly
less likely than other students to report that their financial support
was sufficient to meet their needs. They were also less likely to
report having supportive relationships with peers and postdocs.
Women, and especially URM women, were significantly less likely
to report supportive relationships with advisors. Despite their
more negative experiences in graduate school, students who iden-
tified as URM expressed greater commitment to finishing their
degree and staying in the field. When there was at least one fac-
ulty member within their departments who also identified as URM
they were also more likely than other students to aspire to a uni-
versity professorship with an emphasis on research. Men were
significantly more likely than women to express strong commit-
ment to finishing the PhD and remaining in chemistry, but this
difference was stronger in top-ranked departments. Men were
also more likely than women to aspire to a professorship with
an emphasis on research, and this difference remained when indi-
vidual and departmental-level variables were controlled.

graduate student experience | underrepresented minorities |
URM | women

Fifty years ago, the field of chemistry was overwhelminglypopulated by white men, but, in recent decades, has become
more diverse. Since 2000, women have received about half of the
bachelor’s degrees and over a third of the PhDs. The representation
of those who identify as underrepresented minorities (URM), in-
cluding African Americans, Latinx, and Native Americans, has also
increased, reaching 22% of bachelor’s and 12% of PhD degrees
awarded in 2016 (1). These percentages, however, are far less than
their representation within the US population (∼30%). Moreover,
representation in faculties at research-intensive colleges and uni-
versities has remained lower than would be expected given the
number of PhD recipients. By 2016, only a little more than one-
fourth of tenure-track professors at the assistant and associate ranks
in top-ranked departments were women. Substantially fewer (6%)
identified as URM (2–6).
Research has highlighted the importance of the educational

process in increasing the representation of women and URM in
science, technology, engineering, and math (STEM) (7, 8), but
less research has focused on the nature of graduate school ex-
periences and their relationship to career plans within a specific
STEM discipline (9). In this paper, we begin to fill this gap by
looking at the extent to which graduate school experiences and

career plans of chemistry graduate students differ by gender or
identification as URM, and factors that might moderate, or help
explain, these differences. Data came from a 2013 survey of
chemistry graduate students sponsored by the American Chem-
ical Society (ACS) (10) and publicly available data on chemistry
departments. The sample was restricted to doctoral students
enrolled in the 100 departments in the United States that receive
the largest share of research funding and who had been enrolled
in their departments from 1 to 5 y. It included 1,375 graduate
students, with an average of 13.8 students in each department
(range 1–53).
We found disturbing patterns of inequitable graduate experi-

ences and career plans. On average, women, and especially those
who identified as URM, reported significantly fewer positive
interactions with their advisors than other students. URM stu-
dents were less likely to report that financial support for their
graduate studies was adequate to meet their needs. This differ-
ence in financial support was slightly smaller, but remained, in
even the most prestigious and resource-rich departments. URM
students, and especially men, were significantly less likely to re-
port receiving interpersonal support that they desired. Women
were significantly less likely than men to be committed to fin-
ishing their PhD and staying in chemistry, but this pattern was
strongest among students in larger or more prestigious depart-
ments. Women were also significantly less likely to aspire to
professorships with an emphasis on research, rather than

Significance

On June 10, 2020, as part of the Black Lives Matter movement,
scientists in the United States and throughout the world
paused to consider how systematic racism affects the scientific
enterprise. As a result, many academic departments are now
assessing policies and practices that may contribute to this
situation. This paper provides evidence of the nature of ineq-
uities related to race–ethnicity and gender in graduate school
experiences and career plans of PhD students in one science,
technology, engineering, and math (STEM) discipline, chemis-
try. The results can help promote understanding of the prob-
lems and guide efforts toward equity within STEM and,
potentially, other academic areas. In turn, these changes
can strengthen the scientific enterprise and the well-being
of society.

Author contributions: J.S. designed and conducted the analysis; and J.S., C.M.R., and
G.L.R. wrote the paper.

Reviewers: A.B., Stanford University; and V.M., University of the District of Columbia.

The authors declare no competing interest.

This open access article is distributed under Creative Commons Attribution License 4.0
(CC BY).
1To whom correspondence may be addressed. Email: richmond@uoregon.edu.

This article contains supporting information online at https://www.pnas.org/lookup/suppl/
doi:10.1073/pnas.2020508118/-/DCSupplemental.

Published January 11, 2021.

PNAS 2021 Vol. 118 No. 4 e2020508118 https://doi.org/10.1073/pnas.2020508118 | 1 of 7

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teaching, and this association was not moderated by any of the
control variables we introduced. Although the results are con-
cerning to US chemistry departments, the findings have relevance
to graduate student equity issues across the STEM disciplines and
other areas of academe.

Background
A relatively large literature has examined variables associated
with students’ persistence in STEM degree programs. Factors
often cited as important include strong relationships with an ac-
ademic advisor or mentor (7, 11), support from peers and co-
workers, and a “sense of belonging” or “community” (7, 11–19).
Researchers have documented the way in which subtle negative
interactions, incivilities, or “microaggressions” can negatively im-
pact student experiences and plans (20–24), and have stressed the
importance of promoting true inclusion rather than simple nu-
merical diversity (25). Based on this literature, we examined stu-
dents’ perceptions of their relationships with advisors and peers.
There are also documented differences in student experiences

and outcomes between departments and universities with varying
levels of prestige and different faculty composition. Both women
and students identifying as URM appear less likely to finish
STEM degrees in more prestigious schools (3, 15, 26). For stu-
dents who identify as URM, the presence of faculty who also
have this identification appears important. A study of chemistry
doctoral programs found that departments with more faculty
members identified as URM had a greater increase over time in
the percentage of URM students receiving PhDs. However, this
study also found a slight negative association between the rep-
resentation of women faculty and PhDs awarded to women (3).
Previous studies have also reported lower levels of financial sup-
port for URM students (11, 27). Based on this literature, we ex-
amined variations in students’ experiences across departments
with different characteristics as well as differences in financial
support related to gender or identification as URM. Note that
these studies, as well as our own, underrepresent PhD programs in
historically Black colleges and universities (HBCUs) as most fall
outside of the top 100 institutions as ranked by research funding.
Individual characteristics other than gender and identification

as URM can, of course, influence graduate experiences and ca-
reer plans. Researchers have noted the way in which retention in
graduate programs is enhanced by support from significant
others, especially family members (11), and higher socioeco-
nomic status (28, 29). In addition, individual values and

preferences have been found to influence aspirations (30). It is
possible that women chemists have more often opted for non-
academic careers because they prefer work environments that
allow greater freedom to pursue family and other personal in-
terests. Thus, we included measures of these variables in our
analysis to see if any differences related to gender or identifi-
cation as URM might be moderated, or lessened, when these
variables were considered.

Materials and Methods
The Study of the ACS Data Was Reviewed and Deemed Exempt by the
University of Oregon Human Subjects Office. The ACS summary of the sur-
vey responses (10) noted significant bivariate results related to gender and
identification as URM but did not attempt to examine why differences
appeared or test hypotheses regarding the association of graduate experi-
ences with factors related to the students and their departments. Our work
was designed to fill this gap and was based on the assumption that effective
actions to address inequities require understanding the underlying dynamics.

Our analysis of the data obtained from the ACS focused on three measures
of the graduate school experience: quality of relationship with the advisor,
support received from other graduate students and postdocs, and perceived
adequacy of financial support; and two measures of career-related plans:
commitment to finishing the PhD degree and staying in chemistry, and in-
tent to pursue a career as a professor in a research-oriented university. To
test for moderating effects, we examined the impact of six individual-level
variables (years in the program, parental education, marital/partnered sta-
tus, having dependents, value attached to having a well-paid and secure
career, and value attached to having a job with flexibility for family and
personal interests) and four department-level variables (a composite mea-
sure of the size and prestige of the department, diversity of the university,
proportion of women on the faculty, and any department faculty who
identified as URM).

We used mixed-model regression analyses, a powerful statistical method
for examining associations among variables measured on two levels of
analysis (individual students and their departments). We examined a series
of increasingly more complex models, looking at 1) the extent to which
experiences and plans differed by gender and identification as URM, and 2)
if these differences were moderated by the individual and department-level
control variables. The analysis included tests of interaction effects, or the
ways in which the “intersection” (31) of gender and URM might result in
different experiences. The final, best-fitting models were determined
through standard model fit procedures. (SI Appendix gives details on the
underlying theoretical model, methodology, and results.)

Results
Slightly more than half (52%) of the graduate students who
responded to the ACS survey were men. Nine percent identified

Fig. 1. Average standardized (z) scores, measures of graduate experiences by gender and identification as URM. Note: The sample included 63 women
identified as URM, 64 men identified as URM, 590 women not identified as URM, and 658 men not identified as URM.

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as URM, and this percentage was similar for men and women.
On average, students had been in their programs for about two
and a half years. Slightly more than one-fourth were first-
generation college students, but this percentage was significantly
higher for students who identified as URM. About two-fifths were
married or partnered but less than one-tenth indicated that they
had dependents. On average, students indicated that obtaining a
secure and well-paid job was relatively important (4.0 on the
5-point scale), and students who identified as URM were signifi-
cantly more likely to express this view. Students were slightly less
likely to attach value to family-related and other personal aspects
of their future jobs (3.7 on the 5-point scale). Women and those
who identified as URM were more likely to attach greater value to
these elements. There were no gender differences in the contex-
tual measures. That is, women and men were, on average, in
schools of similar rank, similar levels of diversity, and with similar
proportions of women and URM faculty. Students who did or did
not identify as URM were in schools with similar levels of campus
and faculty diversity. But, those who identified as URM were
significantly less likely to be in larger and more prestigious de-
partments. In total, 38% of the students were in schools within the
top quartile of our measure of departmental size and prestige
compared to 30% in departments in the bottom half of this
measure. (Details in SI Appendix, Table S1.)

Graduate School Experiences. Fig. 1 shows average values on the
measures of graduate school experiences for men and women
who did or did not identify as URM. Because the measures had
slightly different scales, we transformed the values to standard-
ized (z) scores. By definition, standardized scores have a mean of
zero and an SD of 1, and thus the values for each variable are
comparable. The horizontal line in the graph represents the
overall average (zero) for the total group. When a bar associated
with a group falls below that line it indicates experiences that
were less favorable than the overall average. The average values
for each group can also be compared, yielding the difference, in
SD units, between average scores for students in two groups.
(Details in SI Appendix, Table S2.)
Advisor–student relationships. The survey asked an extensive series
of 22 questions about students’ experiences with their advisors in
areas such as involvement in research, availability, encourage-
ment, and fair treatment. Because responses to these measures
were highly correlated, we combined them into an additive scale
(Cronbach’s alpha = 0.94). Some students (9% of the total)
reported that they had two advisors and the scale score for these
students was the average of the ratings given to the two advisors.
Generally, students reported that their advisors were slightly

supportive (an average of 3.6 on the 5-point scale). However,
men were more likely than women to say that their advisors were
supportive, and this gender difference was greater among those
identifying as URM (a significant interaction effect). Women
identifying as URM reported the most negative experiences (an
average z score in Fig. 1 of −0.38), while men identifying as
URM reported, on average, the most positive (an average z score
in Fig. 1 of +0.23). We found similar differences in each of the
22 individual items in the scale. Women identifying as URM
were least likely to report that their advisors encouraged them to
take challenges or pursue their goals, advocated for them, gave
credit for their contributions, created a “fair environment,” gave
regular feedback, engaged them in writing proposals and giving
presentations, helped develop professional relationships, or in-
dicated that they were satisfied with the student’s work.
Our multivariate statistical analyses indicated that the more

negative experiences of URM women could not be explained by
the other variables we examined. In other words, no matter
what year the students were in their graduate program, the ed-
ucational level of their parents, their marital status, the value
attached to different aspects of their careers, the size and

prestige of their department, the diversity of their university, or
the composition of their faculty, the URM women were signifi-
cantly more likely than other students to report negative expe-
riences with their advisors. Women who did not identify as URM
had the next most negative experiences (details in SI Appendix,
Tables S3–S5).
Support from peers and postdocs. A series of survey questions asked
the students about the extent to which they desired and received
“support and advice” regarding their “professional development
and career” from others. We focused on support from other
graduate students and postdocs, the two groups with which they
would be most likely to interact on a day-to-day basis, and
combined these indicators into a 3-point scale with the highest
value indicating that students received as much support as they
wanted from both sources and the lowest indicating that they did
not receive this level of support from either source.
On average, non-URM men were most likely to report that

they received the support they desired, followed by non-URM
women. Students who identified as URM, and especially URM
men, were less likely to report receiving such support. (The in-
teraction effect was statistically significant.) Almost a quarter of
URM men (24%), compared to 16% of the URM women and
12–13% of the non-URM students, reported that they did not
receive desired support from either fellow graduate students or
postdocs. Less than half of the URM men, but almost two-thirds
of the non-URM men, reported that they received the support
they wanted from both sources. Our multivariate analyses indi-
cated that this pattern was not moderated by any of the indi-
vidual or department-level factors. (Details in SI Appendix,
Tables S3–S6.)
Financial support. In addition to questions regarding advisor rela-
tions and support from others, students were asked to indicate
the extent to which they agreed or disagreed with the following
statement: “The funding for my graduate studies is adequate to
meet the cost of living where I live.” Responses could range on a
5-point scale from strongly disagree to strongly agree. On aver-
age, there were no differences between men and women in an-
swers to this query. However, there were significant differences
between students who identified as URM and those who did not.
Students who identified as URM were more than twice as likely
as other students to indicate that their financial support was not
adequate (35% versus 16% responding disagree or strongly
disagree). The z score associated with URM men was especially
low: −0.51 or greater than one-half of an SD below the overall
mean. The students were also asked to report what percentage of
their support came from sources such as teaching assistantships
(TA), research assistantships (RA), fellowships, and personal
resources including other employment, support from family
members, and loans. Reflecting the inadequacy of formal grad-
uate stipends, the percentage of support from personal resources
was over twice as large for URM students as for other students
(7.1% versus 3.2%, t = 3.86, P < 0.001).
The results of our multivariate analyses indicated that the

difference between URM and other students in perceived ade-
quacy of support was not moderated by students’ individual
characteristics, such as marital status or having dependents; the
extent to which they received support from TAs, RAs or fel-
lowships; nor by the composition of departmental faculty or di-
versity of their universities. It was, however, moderated by
departmental prestige and size. The gap in reported adequacy of
funding between URM and other students was less in depart-
ments that were larger and had more research funding, but did
not disappear. Fig. 2 illustrates these results by displaying the
average value on this measure, predicted by our best-fitting
statistical model, for URM and non-URM students in schools
at various levels of size and prestige. The values in the figure
show the average for each group that would be predicted if they
were equivalent on each of the variables included in the analysis,

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including both individual and departmental characteristics. (Details
in SI Appendix, Tables S3, S4, and S7–S9.)
Taken together, our findings regarding graduate school ex-

periences support earlier research and theoretical understand-
ings. Women’s less satisfactory relationships with advisors could
be due to gender-biased assumptions regarding women’s roles in
STEM. The inequities encountered by URMs could be due to
institutional racism. The lack of personal support from peers
illustrates the ways in which implicit biases and a lack of true
inclusion can permeate social interactions in daily life (20–25).
The greater difficulties with funding can be linked to an almost
10-fold difference in net worth between non-Hispanic whites and
minority groups that are underrepresented within STEM (SI
Appendix, Table S14). Even though departments and funding
agencies generally have well-established and seemingly univer-
salistic student funding policies, URM students could be far less
likely to have back-up financial resources and be more likely to
face expectations from others, such as family members, for fi-
nancial assistance. While our analysis controlled for family
background and having dependents, it is unlikely that these
control variables were adequate to fully capture the true scope of
financial disparities. At present, graduate students are paid at
levels far less than they might earn outside academe and the
impact of this low level of funding appears to be far greater for
URM students than for others.

Career Plans. In the second part of our analysis we examined
students’ career-related plans and the extent to which any dif-
ferences related to gender and identification as URM were
moderated by characteristics of the students, their departments,
and their graduate experiences. We first looked at students’
commitment to finishing the PhD and remaining within the
chemical sciences. Men were significantly more likely than
women to express high commitment; within each gender group,
those who identified as URM were more likely to do so. (The
standard scores, or z scores, associated with this measure were
0.25 for URM men, 0.07 for non-URM men, 0.003 for URM
women, and −0.11 for non-URM women.) Our multivariate
analyses indicated that gender differences, but not those related

to URM status, were moderated by other variables, specifically
the size and prestige of the department and the quality of the
relationship that students had with their advisors. Students who
had more supportive advisors expressed significantly greater
commitment to the field and their degree, and this association
was similar for men and women. In contrast, the association
between the prestige of the department and commitment varied
for men and women, as illustrated in Fig. 3. There was no gender
difference in commitment in the less prestigious and smaller
departments, but striking differences in the more prestigious
schools, where women were significantly less likely to be com-
mitted to completing the PhD and remaining in chemistry.
(Again, the values depicted in Fig. 3 control for, or equalize,
other variables related to commitment. Additional details in
SI Appendix, Tables S10–S12.)
The second measure of career plans involved students’ career

aspirations, focusing on the area in which women have been most
underrepresented––tenure-track professorships at research uni-
versities. The highest value of this measure indicated students
were very interested in completing a postdoc and becoming a
professor with an emphasis on research, and the lowest value
indicated no plans for either pursuit. [The phrasing of the
question differentiated “professor (emphasis on research)” from
“professor (emphasis on teaching)” as well as “researcher (not
professor) in college/university.”] The pattern of differences by
gender and identification as URM paralleled those with the
measure of commitment. Men were significantly more likely than
women to aspire to a postdoc and professorship; and, within each
gender group, those who identified as URM were more likely
than other students to express these aspirations. (The standard
scores, or z scores, associated with this measure were 0.52 for
URM men, 0.19 for non-URM men, −0.19 for URM women,
and −0.25 for non-URM women.)
Multivariate analyses indicated that students were significantly

more likely to aspire to a professorship emphasizing research
when they were first-generation college students, attached less
importance to a job that allowed time for family and other in-
terests, had a more supportive advisor, and expressed greater
commitment to finishing their degree and staying in chemistry.

Fig. 2. Estimated average values, perceived adequacy of financial support by prestige/size of department and identification as URM, controlling for other
individual and departmental variables. Note: Perceived adequacy of support measured on a 5-point scale with 5 indicating strongly agree. Mean values
estimated from the best-fitting mixed-model regression and included controls for gender, marital status, dependents, value attached to a high paying job,
diversity of university, and presence of URM faculty in the department. Estimated means for the measure of departmental prestige and size calculated at the
midpoint of each range shown. Horizontal line indicates the average value for all students. Thirty percent of the students (361 non-URM and 47 URM) were in
the 50 departments in the bottom half of the prestige/size distribution of departments; 33% (401 non-URM and 44 URM) in the 25 departments in the second
quartile; and 38% (486 non-URM and 36 URM) in the 25 departments in the highest quartile. Additional details in SI Appendix.

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career plans in chemistry

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Yet, even when all of these variables were equalized, women
were less likely than men to express this aspiration. At the same
time, however, the multivariate results revealed that the ten-
dency for students who identified as URM to more often plan to
become a professor at a research-oriented university was highly
dependent on the composition of their departmental faculty. As
illustrated in Fig. 4, in departments with at least one faculty
member identified as URM, the URM students were more likely
than others to express strong aspirations to a postdoc and

professorship in a research-oriented department. In contrast,
URM students in departments without any professors identified
as URM were slightly less likely than other students to express
these aspirations. The difference between non-URM students in
the two types of departments was much smaller. (Details in SI
Appendix, Tables S10–S12.) (As noted above, our study of the
ACS survey data underrepresents PhD chemistry programs in
HBCUs as most fall outside of the top 100 institutions as ranked
by research funding.)

Fig. 3. Estimated average values, commitment to finishing degree and staying in chemistry by prestige/size of department and gender, controlling for other
individual and departmental variables. Note: Commitment was measured on a 3-point scale, with 3 indicating strongest commitment. Mean values estimated
from results of the best-fitting mixed-model regression and included controls for identification as URM, years in the graduate program, marital status, value
attached to a high-paying job, value attached to a job allowing time for family and other interests, quality of advisor, and presence of URM faculty in the
department. Within all departments both men and women students reported greater commitment when they also reported more supportive advisors.
Horizontal line is the average scale score for all students. Thirty percent of the students (183 women and 225 men) were in the 50 departments in the bottom
half of the prestige/size distribution of departments; 32% (206 women and 239 men) in the 25 departments in the second quartile; and 38% (264 women and
258 men) in the 25 departments in the highest quartile. Additional details in SI Appendix.

Fig. 4. Estimated average values, career aspirations by identification as URM and presence of URM on faculty, controlling for other individual and de-
partmental variables. Note: Aspirations for a faculty position at a research-oriented institution measured on a 4-point scale with the highest value indicating
greatest commitment. Estimates derived from results of mixed model regression that included controls for gender, parental education, value placed on a job
allowing time for personal interests and family, supportive relations with advisor, support from peers and postdocs, and commitment to finishing degree and
staying in the chemical sciences. The horizontal line is the average for the total group. Among the URM students, 81% were in departments with at least one
URM faculty. Among the non-URM students, 74% were in such departments. Seventy of the 100 departments had at least one URM faculty member. Ad-
ditional details in SI Appendix.

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https://www.pnas.org/lookup/suppl/doi:10.1073/pnas.2020508118/-/DCSupplemental
https://www.pnas.org/lookup/suppl/doi:10.1073/pnas.2020508118/-/DCSupplemental
https://doi.org/10.1073/pnas.2020508118


Our analysis of students’ career plans illustrates the important
role of both a supportive advisor and departmental-related var-
iables in students’ career plans, supporting previous literature
reviewed above. Net of other variables, students who had more
supportive advisors were more likely to plan to finish their de-
gree, stay in chemistry, and aspire to a postdoctoral position and
an academic career at a research-oriented university. Yet the
positive effect of an advisor on women’s commitment was muted
in larger and more prestigious departments, where the gender
gap in commitment was significantly stronger. The racial/ethnic
composition of departments’ faculties was especially important
in explaining the aspirations of URM students, paralleling earlier
research on chemistry departments (3). We suggest that these
results highlight the ways in which those concerned with graduate
students’ career plans need to address both the actions of indi-
vidual faculty as well as the nature of departmental culture and
composition.

Conclusion
For many years, members of the scientific community have
stressed the importance of diversity and inclusion within the
scientific enterprise by finding and building on scientific interests
and talents from all segments of the population (23, 32, 33).
Graduate schools are the major path to producing a diverse and
inclusive scientific workforce. Yet, as illustrated in this paper,
graduate school experiences can mirror inequities in other areas
of the society and potentially work against achieving this goal.
The academic world projects an aura of universality, meritoc-
racy, and respect for all, regardless of their individual charac-
teristics. However, the results of this analysis suggest that the
reality for those who are traditionally underrepresented appears
to be quite different. In their academic departments and labo-
ratories, these underrepresented students may encounter subtle,
insidious, and continual social and psychological hostilities and
devaluation. Amazingly, despite this situation, students who
identify as URM are more likely to plan to persist in their degree
programs and the discipline, and to aspire to careers as professors
who emphasize research as well as teaching. This commitment

suggests extraordinary individual courage and devotion to their
science.
The ACS is commended for commissioning the data-gathering

effort that led to this paper. It could be tempting for some to
dismiss the findings described above as unique to one discipline, or
to STEM but not to other areas. Given the deep roots of sys-
tematic racism and sexism within our society, it would seem un-
likely that the results reported here are so limited. At the very
least, this is an empirical question and one that requires concerted
attention throughout the scientific and academic world. Thus, we
hope that researchers replicate this work in a wider range of in-
stitutions, including HBCUs and those with less research funding,
in other STEM fields, and in other academic disciplines. SI Ap-
pendix includes an extended discussion of possible future research
as well as the implications of our findings for changing policies and
practices. However, it is important to note that ample resources
are available to assist chemistry departments and faculty who wish
to address these findings, including minority technical organiza-
tions such as the National Organization for the Professional Ad-
vancement of Black Chemists and Chemical Engineers (34) and
the Society for Advancement of Chicanos/Hispanics and Native
Americans in Science (35).
In June 2020, many scientists in the United States and throughout

the world expressed their commitment to uncovering and addressing
inequities within their disciplines and to demonstrating that Black and
brown lives matter within laboratories, hallways, faculty offices, and
the everyday life of academe and the larger scientific enterprise (36).
We hope that the findings summarized in this paper can help guide
corrective actions, not just within chemistry, but throughout academia.

Data Availability. Data is available at https://coach.uoregon.edu/
coach-research-publications-and-articles.

ACKNOWLEDGMENTS. This material is based upon work supported by the
US Department of Energy, Office of Science, Office of Basic Energy under
Award DE-FG02-03ER46061. We greatly appreciate and thank the ACS for
administering the survey and sharing the data with us.

1. Calculated from data in National Science Foundation, Integrated postsecondary ed-
ucation data system. (2020). https://www.nsf.gov/statistics/srvyipeds/. Accessed 4 No-

vember 2020.
2. V. J. Kuck, C. H. Marzabadi, J. P. Buckner, S. A. Nolan, A review and study on

graduate training and academic hiring of chemists. J. Chem. Educ. 84, 277–284

(2007).
3. S. L. Laursen, T. J. Weston, Trends in Ph.D. Productivity and diversity in top-50 U.S.

chemistry departments: An institutional analysis. J. Chem. Educ. 91, 1762–1776

(2014).
4. Oxide, Open chemistry collaborative in diversity equity. Demographics Data. (2020).

http://oxide.jhu.edu/2/demographics. Accessed 4 November 2020.
5. Royal Society of Chemistry, Breaking the Barriers: Women’s Retention and Progres-

sion in the Chemical Sciences (The Royal Society of Chemistry, London, 2018).
6. L. Wang, S. L. Rovner, New survey on minority chemistry professors released. C&E

News (18 May 2015), Articles, 93.
7. M. Ferreira, Gender issues related to graduate student attrition in two science de-

partments. Int. J. Sci. Educ. 25, 969–989 (2003).
8. C. Riegle-Crumb, B. King, Y. Irizarry, Does STEM stand out? Examining racial/

ethnic gaps in persistence across postsecondary fields. Educ. Res. 48, 133–144

(2019).
9. K. D. Gibbs Jr, J. McGready, J. C. Bennett, K. Griffin, Biomedical science Ph.D. career

interest patterns by race/ethnicity and gender. PLoS One 9, e114736 (2014).
10. C. Kuniyoshi, J. Sostaric, M. Kirchhoff, ACS graduate student survey (American

Chemical Society, Washington, DC, 2013).
11. M. Ong, C. Wright, L. L. Espinosa, G. Orfield, Inside the double bind: A syn-

thesis of empirical research on undergraduate and graduate women of color

in science, technology, engineering, and mathematics. Harv. Educ. Rev. 81,

172–208 (2011).
12. M. J. Chang, J. Sharkness, S. Hurtado, C. B. Newman, What matters in college for

retaining aspiring scientists and Engineers from underrepresented racial groups.
J. Res. Sci. Teach. 51, 555–580 (2014).

13. N. Curtin, A. J. Stewart, J. M. Ostrove, Fostering academic self-concept: Advisor sup-

port and sense of belonging among international and domestic graduate students.
Am. Educ. Res. J. 50, 108–137 (2013).

14. N. Dasgupta, Ingroup experts and peers as social vaccines who inoculate the self-
concept: The stereotype inoculation model. Psychol. Inq. 22, 231–246 (2011).

15. L. L. Espinosa, Pipelines and pathways: Women of color in undergraduate STEM

majors and the college experiences that contribute to persistence. Harv. Educ. Rev. 81,
209–240 (2011).

16. T. Figueroa, “Underrepresented racial/ethnic minority graduate students in science,

technology, engineering, and math (STEM) disciplines: A cross-institutional analysis of
their experiences,” Unpublished Dissertation, University of California, Los Angeles, CA
(2015).

17. C. Good, A. Rattan, C. S. Dweck, Why do women opt out? Sense of belonging and
women’s representation in mathematics. J. Pers. Soc. Psychol. 102, 700–717
(2012).

18. K. L. Lewis, J. G. Stout, S. J. Pollock, N. D. Finkelstein, T. A. Ito, Fitting in or opting out:
A review of key social-psychological factors influencing a sense of belonging for
women in physics. Phys. Rev. Phys. Educ. Res. 12, 020110 (2016).

19. C. N. Stachl, A. M. Baranger, Sense of belonging within the graduate community of a
research-focused STEM department: Quantitative assessment using a visual narrative
and item response theory. PLoS One 15, e0233431 (2020).

20. A. J. Anderson, B. Sanchez, C. Reyna, H. Rasgado-Flores, “It just weighs in the back

of your mind”: Microaggressions in science. J. Women Minor. Sci. Eng. 26, 1–30
(2020).

21. K. N. Miner, I. Diaz, A. N. Rinn, Incivility, psychological distress, and math self-concept

among women and students of color in STEM. J. Women Minor. Sci. Educ. 23, 211–230
(2017).

22. C. A. Moss-Racusin, J. F. Dovidio, V. L. Brescoll, M. J. Graham, J. Handelsman, Science

faculty’s subtle gender biases favor male students. Proc. Natl. Acad. Sci. U.S.A. 109,
16474–16479 (2012).

23. C. Puritty et al., Without inclusion, diversity initiatives may not be enough. Science

357, 1101–1102 (2017).
24. D. Verdin, A. Godwin, Exploring Latina first-generation college students’ multiple

identities, self-efficacy, and institutional integration to inform achievement in engi-

neering. J. Women Minor. Sci. Eng. 24, 261–290 (2018).
25. Q. M. Roberson, Disentangling the meanings of diversity and inclusion in organiza-

tions. Group Organ. Manage. 31, 212–236 (2006).

6 of 7 | PNAS Stockard et al.
https://doi.org/10.1073/pnas.2020508118 Equity for women and underrepresented minorities in STEM: Graduate experiences and

career plans in chemistry

D
o
w

n
lo

a
d
e
d
 a

t 
C

a
rn

e
g
ie

 M
e
llo

n
 U

n
iv

e
rs

ity
 o

n
 A

p
ri
l 5

, 
2
0
2
1
 

https://www.pnas.org/lookup/suppl/doi:10.1073/pnas.2020508118/-/DCSupplemental
https://www.pnas.org/lookup/suppl/doi:10.1073/pnas.2020508118/-/DCSupplemental
https://coach.uoregon.edu/coach-research-publications-and-articles
https://coach.uoregon.edu/coach-research-publications-and-articles
https://www.nsf.gov/statistics/srvyipeds/
http://oxide.jhu.edu/2/demographics
https://doi.org/10.1073/pnas.2020508118


26. A. L. Griffith, Persistence of women and minorities in STEM field majors: Is it the
school that matters? Econ. Educ. Rev. 29, 911–922 (2010).

27. M. Estrada et al., Improving underrepresented minority student persistence in STEM.
CBE Life Sci. Educ. 15, es5 (2016).

28. A. O. Haller, A. Portes, Status attainment processes. Sociol. Educ. 46, 51–91
(1973).

29. A. M. Santiago, M. K. Einarson, Background characteristics as predictors of academic
self-confidence and academic self-efficacy among graduate science and engineering
students. Res. High. Educ. 39, 163–198 (1998).

30. S. Beyer, Why are women underrepresented in computer science? Gender differences
in stereotypes, self-efficacy, values, and interests and predictors of future CS course-
taking and grades. Comput. Sci. Educ. 24, 153–192 (2014).

31. P. H. Collins, Intersectionality as Critical Social Theory (Duke University Press, Durham,
NC, 2019).

32. R. J. Burke, M. C. Mattis, Eds., Women and Minorities in Science, Technology, Engi-
neering, and Mathematics: Upping the Numbers (Edward Elgar Publishing Limited,
Cheltenham, UK, 2007).

33. K. W. Phillips et al., How diversity makes us smarter. Sci. Am. 311, 42–47
(2014).

34. National Organization for the Professional Advancement of Black Chemists and
Chemical Engineers (2020). https://www.nobcche.org/. Accessed 4 November
2020.

35. Society for Advancement of Chicanos/Hispanics and Native Americans in Science
(2020). https://www.sacnas.org/. Accessed 4 November 2020.

36. N. Subbaraman, Thousands of scientists worldwide to go on strike for black lives.
Nature, New (2020). https://idp.nature.com/authorize?response_type=cookie&client_
id=grover&redirect_uri=https%3A%2F%2Fwww.nature.com%2Farticles%2Fd41586-
020-01721-x. Accessed 9 June 2020.

Stockard et al. PNAS | 7 of 7
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career plans in chemistry

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C
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a
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e
g
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e
llo

n
 U

n
iv

e
rs

ity
 o

n
 A

p
ri
l 5

, 
2
0
2
1
 

https://www.nobcche.org/
https://www.sacnas.org/
https://idp.nature.com/authorize?response_type=cookie&client_id=grover&redirect_uri=https%3A%2F%2Fwww.nature.com%2Farticles%2Fd41586-020-01721-x
https://idp.nature.com/authorize?response_type=cookie&client_id=grover&redirect_uri=https%3A%2F%2Fwww.nature.com%2Farticles%2Fd41586-020-01721-x
https://idp.nature.com/authorize?response_type=cookie&client_id=grover&redirect_uri=https%3A%2F%2Fwww.nature.com%2Farticles%2Fd41586-020-01721-x
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