This edition of the Notable Women in Science series presents modern astronomers. Many of these women are currently working in fields of research or have recently retired. As before, pages could be written about each of these women, but I have limited information to a summary of their education, work, and selected achievements. Many of these blurbs have multiple links, which I encourage you to visit to read extended biographies and learn about their current research interests.
From L to R: Anne Kinney, NASA Goddard Space Flight Center, Greenbelt, Md.; Vera Rubin, Dept. of Terrestrial Magnetism, Carnegie Institute of Washington; Nancy Grace Roman Retired NASA Goddard; Kerri Cahoy, NASA Ames Research Center, Moffett Field, Calif.; Randi Ludwig. University of Texas, Austin, Texas.
Vera Cooper Rubin was making advancements decades ahead of popularity of her research topic. She received her B.A. from Vassar College, M.A. from Cornell University, and her Ph.D. from Georgetown University in the 1940s and 50s. She continued at Georgetown University as a research astronomer then assistant professor, and then moved to the Carnegie Institution. Among her honors is her election to the National Academy of Sciences and receiving the National Medal of Science, Gold Medal of the Royal Astronomical Society.She was only the second female recipient of this medal, the first beingCaroline Herschel. She has had an asteroid and the Rubin-Ford effect named after her. She is currently enjoying her retirement.
Nancy Grace Roman has a lifetime love for astronomy. She received her B.A. from Swarthmore College and Ph.D. from the University of Chicago in the 1940s. She started her career as a research associate and instructor at Yerkes Observatory, but moved on due to a low likelihood of tenure because of her gender. She eventually moved through chief and scientist positions to Head of the Astronomical Data Center at NASA. She was the first female to hold an executive position at NASA. She has received honorary D.Sc. from several colleges and has received several awards, including the American Astronautical Society’s William Randolf Lovelace II Award and the Women in Aerospace’s LIfetime Achievement Award. She is currently continuing to inspire young girls to dream big by consulting and lecturing by invitation at venues across the U.S.
Catharine (Katy) D. Garmany researches the hottest stars. Dr. Garmany earned her B.S. from Indiana University and her M.A. and Ph.D. from the University of Virginia in the 1960s and 70s. She continued with research and teaching at several academic institutions. She has served as past president of the Astronomical Society of the Pacific and received the Annie Jump Cannon Award. She is currently associated with the National Optical Astronomy Observatory with several projects.
Elizabeth Roemer is a premier recoverer of “lost” comets. She received her B.A. and Ph.D. from University of California – Berkeley in the 1950s. She spent some time as a researcher at U.S. Observatories before going to the University of Arizonaand moving through the professorial ranks. She has received several awards, including Mademoiselle Merit Award, one of only four recipients of the Benjamin Apthorp Gould Prize from the National Academy of Sciences, and a NASA Special Award. She is currently Professor Emerita at the University of Arizona with research interests in comets and minor planets (“asteroids”), including positions (astrometry), motions, and physical characteristics, especially of those objects that approach the Earth’s orbit.
Margaret Joan Geller is a widely respected cosmologist.She received her A.B. from the University of California-Berkeley, and M.A. and Ph.D. from Princeton University in the 1970s. She moved through the professorial ranks at Harvard University and is currently an astrophysicist at the Smithsonian Astrophysical Observatory. Some of her awards include the MacArthur “Genius” Award and the James Craig Watson Award from the National Academy of Sciences. She continues to provide public education in science through written, audio, and video media.
In 1995, the majestic spiral galaxy NGC 4414 was imaged by the Hubble Space Telescope as part of the HST Key Project on the Extragalactic Distance Scale. An international team of astronomers, led by Dr. Wendy Freedman of the Observatories of the Carnegie Institution of Washington, observed this galaxy on 13 different occasions over the course of two months.
Wendy Laurel Freedman is concerned with the fundamental question”How old is the universe?”She received her B.S., M.S., and Ph.D. from the University of Toronto in the 1970s and 80s. After earning her Ph.D. she joined Observatories of the Carnegie Institution in Pasadena, California as a postdoctoral fellow and became faculty a few years later, as the first woman to join the Observatory’s permanent scientific staff. She has received several awards and honors, among them the Gruber Cosmology Prize. Her current work is focusing on the Giant Magellan Telescope and the questions it will answer.
Heidi Hammel is known as an excellent science communicator, researcher, andleader. She earned her B.S. from Massachusetts Institute of Technology and Ph.D. from the University of Hawaii in the 1980s. At NASA she led the imaging team of the Voyager 2’s encounter with Neptune and became known for her science communication for it. She returned to MIT as a scientist for nearly a decade. Among her honors, she has received Vladimir Karpetoff Award , Klumpke-Roberts Award, and the Carl Sagan Medal. She is currently at the Space Science Institute with a research focused on ground- and space-based studies of Uranus and Neptune.
Judith Sharn Young was inspired by black holes. She earned her B.A. from Harvard University and her M.S. and Ph.D. from the University of Minnesota in the 1970s. She began her academic career at the University of Massachusetts – Amherst, proceeding through the professorial ranks. She has earned several honors, including the Annie Jump Cannon Prize, the Maria Goeppert-Mayer Award, and a Sloan Research Fellowship. She is currently teaching and researching galaxies and imaging at the University of Massachusetts.
Jocelyn Bell Burnell is the discoverer of pulsars. She earned her B.Sc. from the University of Glasgow and her Ph.D. from Cambridge University in the 1960s. After her graduation, she worked at the University of Southampton in research and teaching, and continued to work in research positions at several institutions. She is well known for her discovery of pulsars, which earned her research advisor a Nobel Prize. Among her awards are the Albert A. Michelson Prize, Beatrice Tinsley Prize, Herschel Medal, Magellanic Premium, and Grote Reber Metal. She has received honorary doctorates from Williams College, Harvard University, and the University of Durham. She is currently Professor of Physics and Department Chair at the Open University, England.
Our next installment of notable women in science brings us to chemists. Many of these women were born in the early part of the 20thcentury and forged their paths in tough times. All are still inspiring others today. Presented in no particular order:
Catherine Clarke Fenselau is a pioneer in mass spectrometry. Born in 1939, her interested in science was apparent before her 10th grade. She was encouraged to attend a women’s college, which at the time gave what she called “a special opportunity for serious-minded young women.” She graduated from Bryn Mawr with her A.B. in chemistry in 1961. Her graduate work at Stanford introduced her to the technology she would become known for, receiving her Ph.D. in analytical chemistry in 1965. Dr. Fenselau and her husband took positions at the Johns Hopkins University Medical School, at which time she had two sons. Johns Hopkins was under a mandate to accept female students and have female faculty at the time. Dr. Fenselau was made aware of the disparity of the treatment of male and female faculty, when in the 1970s the equal opportunity laws came into effect and she received an unexplained 25% raise. Her research resided in mass spectrometry, specifically in its use in biology. She became known as an anti-cancer researcher. Dr. Fenselau spoke often to chemists about feminism and goals, such as equal pay, opening closed career opportunities to women, and achieving the bonuses often only awarded to men. She has worked as an editor on several scientific journals. Some of her awards include the Garvan Medal, Maryland Chemist Award, and NIH Merit Award. Having proper help at work and at home, and having supportive mentors and spouse has helped her achieve her success.
Elizabeth Amy Kreiser Weisburger is considered a real-lifemedical sleuth. Born in 1924, Dr. Weisburger was one of 10 children and schooled at home for her early education. She received her B.S. in chemistry, cum laude, Phi Alpha Epsilon from Lebanon Valley College. She received her Ph.D. in organic chemistry in 1947 from the University of Cincinnati. She married and had three children. Her research has caused her to be proclaimed a pioneer in the field of chemical carcinogenesis. She balanced her busy life of working at the NCI, committee work, giving lectures, attending meetings, writing and reviewing papers while caring for children with the aid of housekeepers and nursery childcare. Some of her awards include the Garvan Medal and the HillebrandPrize. Her life philosophy is summed up with “Don’t take life so seriously; you’ll never get out of it alive.”
Helen M. Free is a major contributor to science and science education. Born in 1923, Ms. Free attended the College of Wooster, graduating with honors and a B.S. in 1944. In 1978, she earned a M.A. from Central Michigan University. In the meantime, she worked as a chemist at Miles Laboratories. She developed clinical effective and easy to use laboratory tests. She worked her way up through the company and also held an adjunct professor position at Indiana University, South Bend. Ms. Free has used her time to be active in professional societies and has served as president for the American Association for Clinical Chemistry and the American Chemical Society. Her awards include the Garvan Medal, a Distinguished Alumni Award from Wooster, and is the first recipient ofthe Public Outreach Award bearing her name.
Jeanette Grasselli Brown is an industry researcher and director. Born in 1929, she graduated summa cum laudewith her B.S. from Ohio University in 1950 and received her M.S. in 1958 from Western Reserve University. She worked at Standard Oil of Ohio (now BP of America), and became the first woman director of corporate research there. She has received numerous awards including the Garvan Medal, Ohio Women’s Hall of Fame, and the Fisher Award in Analytical Chemistry. She has published 75 papers in scientific journals, written 9 books, and received 7 honorary Doctorate of Science degrees. She is an activist for the future of women in science.
Jean’ne Marie Shreeve is an important fluorine chemist. Born in 1933, she encountered sexism through her mother’s inability to be employed despite her training as a schoolteacher. Dr. Shreeve graduated with a B.A. from Montana State University in 1953, followed by an M.S. in 1956 from the University of Minnesota, and a Ph.D. in inorganic chemistry in 1961 from the University of Washington. After graduating, she worked her way through the professorial ranks at the University of Idaho. Besides her own research, Dr. Shreeve has devoted herself to educating other chemists. Some of her awards include U.S. Ramsey Fellow, Alfred P. Sloan Fellow, and Garvan Medal.
Joyce Jacobson Kaufman is distinguished in many fields. Born in 1929, she was reading before the age of 2 and was a voracious reader as a child. This led to her reading the biography of Marie Curie, which inspired her to be a chemist. Dr. Kaufman received her B.S., M.A., and Ph.D. in physical chemistry from Johns Hopkins University in 1949, 1959, and 1960, respectively. She married and had a daughter. Her research in the application of quantum mechanics to chemistry, biology, and medicine led to her renown in several fields. She has also spent much time in service positions. Her awards include the Martin Company Gold Medal for Outstanding Scientific Accomplishments (received 3 times), the Garvan Medal, and honored as one of ten Outstanding Women in the State of Maryland.
Madeleine M. Joullie is known for elegant research and inspirational teaching. Born in 1927, her early life in Brazil was overly-protective, so her father encouraged her to attend school in the U.S.A. She received her B.Sc. from Simmons College in 1949, and her M.Sc. and Ph.D. in chemistry in 1950 and 1953, respectively, from the University of Pennsylvania. She then worked her way through the professorial ranks at the University of Pennsylvania. Initially, only the women graduate students would work with her, and they were few and far between. She has explored many research avenues over the course of her career. Her awards include the Garvan Medal, the American Cyanamid Faculty Award, the Henry HillAward, and the Lindback Award for Distinguished Teaching.
Marjorie Caserio is a researcher, educator, author, andacademic administrator. Born in 1929, she entered university with the goal of becoming a podiatrist in order to generic income. She received several rejections from colleges due to her gender, and eventually was accepted to be the only woman in her class. She received her B.S. from Chelsea College, University of London in 1950 and an M.A. and Ph.D from Bryn Mawr in 1951 and 1956. Dr. Caserio is co-author of one of the most popular organic chemistry textbooks in the chemistry during the 1960s and 1970s. Her awards include the Garvan Medal and John S. Guggenheim Foundation Fellow.
Mary Lowe Good has won several awards and is a public servant. Born in 1931, she was supported in her aspirations by her parents. She received her B.S. in 1950 from the University of Central Arkansas, which was then the Arkansas State Teachers College. She went on to receive her M.S. and Ph.D. in inorganic and radiochemistry from the University of Arkansas in 1953 and 1955. Her career began in academic, but an appointment to the National Science Foundation by President Carter changed the course of her career. She served the International Union of Pure and Applied Chemistry, and president of the American Chemical Society and Zonta International Foundation. Some of her awards include Garvan Medal, CharlesLathrop Parsons Award, and 18 honorary doctorates.
Ruth Mary Roan Benerito is an academic and government scientist. Born in 1916, she began college at the age of 15 at Sophie Newcomb College, the women’s college of Tulane and received her B.S. in 1935. She received her M.S. from Tulane University in 1938, which she worked half-time while working another job at the same time. She taught at Tulane and its colleges before going to the University of Chicago to get her Ph.D. in 1948 in physical chemistry, again working on a part-time basis. Her career oscillated between academia and industry, earning her a large number of awards, including the Federal Women’s Award, the Southern Chemist Award, and inducted as a Fellow into the American Institute of Chemists and Iota Sigma Pi.
The Garvan Medal is an award from the American Chemical Society to recognize distinguished service to chemistry by women chemists.
The Maryland Chemist Award recognizes and honors its members for outstanding achievement in the fields of chemistry.
The NIH Merit Award is asymbol of scientific achievement in the research community.
The Hillebrand Prize is awarded for original contributions to the science of chemistry.
The Distinguished Alumni Award from Woosteris presented annually to alumni who have distinguished themselves in one of more of the following area: professional career; service to humanity; and service to Wooster.
The American Institute of Chemistsadvances the chemical sciences by establishing high professional standards of practice and to emphasize the professional, ethical, economic, and social status of its members for the benefit of society as a whole.
Iota Sigma Pi is a national honor society for women in chemistry.
Featured today are 10 more women who broke boundaries by their presence in physics. They lived from 1711 to 2000. While I again limited information to one paragraph, I tried to highlight how they got their start, what universities, family members, and scientists were supportive of them. For these women, without the support of fathers, mothers, husbands, and mentors (all male with one exception) their life in science would not have happened. While barriers are not as difficult today as they were at the times these women made their way, it is a testament to what can be done when families and scientists support each other. These women are an inspiration and I hope you look up more information for them. In addition, I’d love to hear who your favorite women in science are in the comments.
Laura Bassi (1711-78) lectured on science until a few hoursbefore her death. An Italian scientist of international fame and one of the first women physicists in western history, Dr. Bassi earned her doctorate in philosophy and science through public debate from the University of Bologna. The University of Bologna offered Dr. Bassi a position in an effort to be known as a leader in women’s education. Unfortunately, this forward step was not acceptable to much of the rest of the world’s academic community and required stipulations to Dr. Bassi teaching. However, she countered these limitations with determination and passion. Her appointment to full membership in the Bendettini Academics also deterred some naysayers of Dr. Bassi’s involvement in research and teaching. In order to further her career, she married. A married woman could achieve more than a single woman at that time. Her death in 1778 was unexpected, especially as she had participated in an Academy of Sciences lecture on a few hours before.
Margaret Eliza Maltby (1860-1944) was a recognized scientistand advocate for women in science.She overcame the education offered to women by taking extra courses in order to attend Oberlin College and receive a B.A. She studied with the Art Students’ League in New York City to explore her interest in art and then taught high school before enrolling as a “special student” at the Massachusetts Institute of Technology (MIT), receiving her B.S. Oberlin recognized this extra effort by awarding Dr. Maltby an M.S. She became a physics instructor at Wellesley College. She was encouraged in her graduate students by an AAUW fellowship to attend Göttingen University, which culminated in Dr. Maltby being the first American woman to receive a Ph.D. in physics from any German university. Dr. Maltby worked as an instructor, a researcher, and administrator in many universities and colleges in the U.S. and abroad. Her stature as a scientist was acknowledged with her entry in the first edition of AmericanMen of Science. She also was active in the AAUW, advocating for women to gain education and enter scientific fields. After her retirement from university life, she maintained her interest in the arts.
Irène Joliot-Curie (1897-1956) was a Nobel Prize Laureate for “artificial radioactivity.”Born to the woman every person thinks of as the epitome of a woman in science, Marie Curie, Irène had an extremely close relationship with her paternal grandfather. Her schooling was outside of the standard schooling type, her first years at home and her latter years in a science and math heavy co-operative school of Madame Curie’s colleagues. She received her Bachelor’s degree from the Collège Sévigné and went on to study at the Sorbonne. She received her doctorate in 1925 based on work with her mother at the Radium Institute of the Sorbonne. She married Frédéric Joliot, another research assistant of Madame Curie’s. Dr. Joliot-Curie continued her research, interrupted by a stint as Undersecretary of State for Scientific Research, one of the first high government posts to be offered to a woman. She worked as a professor for the Sorbonne and director of the Radium Institute, but was not admitted to the Academy of Sciences due to discrimination despite her work. She died, like her mother, of acute leukemia. Her scientific work was complemented by her love of physical activity and motherhood.
Katharine Burr Blodgett (1898-1979) was a woman with an amazing number of firsts. Born to a widow, she was a world citizen in her formative years, attended high school at a private school in New York City, won a scholarship to attend Bryn Mawr, and graduated second in her class there. She received her Master’s degree from the University of Chicago, then headed off to work with Nobel Laureate Irving Langmuir at General Electric (GE) and becoming the first woman research scientist there. She was able to work with Nobel Laureate Sir Ernest Rutherford and earn her Ph.D. from Cambridge University as the first woman to earn a doctorate from Cambridge. She returned to GE. During her career, she invented many applications and is credited with six patents. She achieved much when many women did not, but her work was de-valued in the media. She did earn recognition from her peers, including the ACS Garvan Medal, the Photographic Society of America Progress Medal, and a day named after her in her hometown of Schenectady, NY. In addition to her scientific life, she enjoyed gardening, civic engagement, acting, and “dart[ing] about Lake George in a fast motor boat.”
Astrophysicist Charlotte Emma Moore Sitterly (1898-1990) was an authority on sun composition. She started her career as an excellent student with extracurricular interests, attending Swarthmore College to earn her B.A. Upon graduation, she accepted a position as a mathematics computer at Princeton University Observatory, one of the few employment opportunities available to science inclined women at the time. A stint at the Mount Wilson Observatory led to results published a 1928 monograph which was considered the authoritative work on the solar spectrum for four decades. She received her Ph.D. from the University of California, Berkeley in 1931. Her work earned her the Annie J. Cannon Prize, Silver and Gold Medals from the Department of Commerce, and several honorary doctorates in the U.S. and abroad. She was the first woman elected foreign associate by the Royal Astronomical Society of London. Her enthusiasm for her work continued until her death.
Nuclear Physicist Maria Goeppert-Mayer (1906-1972) was the second woman to win the physics Nobel. Her early education was public education for girls followed by a private school founded by suffragettes. Circumstances led Dr. Goeppert-Mayer to take her exiting exams a year early, passing them she attended the University of Göttingen for her college education in mathematics. She continued to study physics at the University of Göttingen, earning her Ph.D. in 1930. She also married that year. The couple moved to America in hopes of better career trajectory for Dr. Goeppert-Mayer. Finding a position was difficult. When she had her first child, she stayed home with her for one year, then returned to research. While her positions were always part-time and not well recognized, she grew a well-respected network of collaborators. This network led to work with Hans Jensen which won her the Nobel Prize, shared with Jensen. Her network also eventually led to a full professorship position after 20 years of volunteer work. During this time, her health began to fail. She persevered with her work, publishing her last paper in 1965. The American Physical Society established an award in her honor in1985.
Gertrude Scharff Goldhaber (1911-1998) was a respected researcher.She grew up in a time in Germany where girls were expected to become schoolteachers. She had a fascination with numbers, and eventually studied physics at the University of Munich, receiving her PhD in 1935. She fled Germany during the rise of the Nazis due to being Jewish, arriving in the United States and becoming a citizen in 1944. She had a wide involvement in the various National Laboratories studying nuclear physics. She also maintained several committee positions in the science community. She was also a strong advocate for women in the science community, forming a Women in Science group at Brookhaven National Lab and supporting other similar groups elsewhere. After her retirement from research, she continued interests in the history of science, outdoor activities, and art.
Physicist, Molecular Spectroscopist Leona Woods MarshallLibby (1919-1986)Leona Woods grew up on a farm and was known for her inexhaustible energy. She attained her B.S. in chemistry from the University of Chicago when she was only 19 years old, and earned her PhD 5 years later. She worked as the only woman and youngest member of the Chicago Metallurgical Laboratory, a secret war group led by Enrico Fermi who built the world’s first nuclear fission reactor during her graduate work. Dr. Woods’ expertise was essential to the undertaking. She married another member of her team. She hid her first pregnancy until 2 days before her son’s birth. She took one week off before returning to work. Childcare was provided by her mother and sometimes Fermi’s bodyguard, John Baudino. Dr. Marshall was encouraged by Fermi as a female physicist. In the late 1950s, Dr. Marshall was divorced from her husband, pursuing her own career. In the early 1960s, Dr. Marshall moved to Colorado to work and married Willard Libby. Her mind was always considering any number of problems from many angles. She worked up until her death and was honored posthumously for her work, along with Lise Meitner, Marie Curie, and Irene Joliot-Curie.
Chien-Shiung Wu (1912-1997) was a foremost experimental physicist of modern era. She was encouraged as a girl to pursue her schooling as far as possible. This led her to teaching training, which lacked science so she taught herself physics, chemistry, and mathematics. She graduated high school with the highest grades in her class, earning her a place at the National Central University in Nanjing. She taught and did research upon graduation, then moved to the United States to pursue graduate studies. She earned her Ph.D. from the University of California – Berkeley in 1940, four years after leaving China. She was known for her expertise in nuclear fission and was consulted by top scientists. Despite this, her gender and nationality hindered her finding appropriate employment due to discrimination on both accounts. She married and started a teaching career, although she missed research. Upon the recommendation of Ernest Lawrence, she received offers from several Ivy League schools who were not accepting female students at the time. She became Princeton’s first woman instructor at that time. She was offered several positions, including back in China, but chose to remain in the U.S. to raise her son. She was unable to return to China until 1973. She worked at Columbia for many decades and earned accolades for her work.
Xide Xie (1921-2000) is a woman in China who needs no introduction. Her early life involved much moving due to war and ill health, during which she taught herself English, calculus, and physics. She graduated in 1942 with a degree from Xiamen University. She moved to the United States to receive her master’s degree from Smith College in 1949 and her Ph.D. in physics from M.I.T. in 1951. She married in England and returned to China, despite the political climate. She taught and did research at the prestigious Fudan University. During the Cultural Revolution of 1966-76, she was detained, publicly humiliated, and endured breast cancer. After this upheaval, she returned to Fudan University, growing the physics department and achieving more esteemed positions in the University and government. She had also remained connected to her family, caring for her husband through lengthy illness. Her achievements were internationally recognized.
Benedettini Academics were a select group of scholars from the Academy of Sciences created and named for Pope Benedict XIV to conduct research and present it annually at Academy meetings. This appointment escalated the prestige of the scientist above that given by being a member of the Academy of Sciences.
American Association for University Women (AAUW): Margaret Maltby received the European Fellowship from the Association of Collegiate Alumnae, which became the AAUW. This fellowship was specifically intended to help American women pursue graduate studies to circumvent rules that did not allow women to enroll in coeducational universities or earn graduate degrees.
The Nobel Prize is an international award given in several fields. It is one of the most prestigious awards for scientists in the eyes of the public.
The Garvan Medal is an award from the American Chemical Society to recognize distinguished service to chemistry by women chemists.
If you have been watching tweets from @DoubleXSci since early December, you’ll have noticed tweets about Notable Historical and Modern Women in Science. Nearly 100 women were presented over twitter. Those women will be presented in a series here on the blog with the original tweeted links and information as well as with some additional information not able to be presented in 140 characters. We hope you look up more on these women.
(1893-1975) Dr. Bilger received her PhD in chemistry from the University of Cinncinnati in 1916. She graduated and went straight into a position as head of the chemistry department at Sweet Briar College. A brief stint at the University of Cinncinnati gave her skills that she later used in her position as Chair of the Department of Chemistry at the University of Hawaii to design a new chemistry laboratory facility. Her post as University of Hawaii Department Head began in 1943 and lasted 11 years. Her research was on asymmetric nitrogen compounds, for which she won the Garvan Medal.
(1890-1972) Born in Bogota, Columbia of missionaries, she arrived in the U.S. to attend high school. Dr. Caldwell was supported by her family in her pursuit of education and science. Due to gender restrictions, Caldwell attended a women’s college and stayed on there for teaching initially. This gave her the start on what she is known for: being a role model and mentor for other women for six decades. She received her A.B in 1913 from Western College for Women, her master’s degree in 1919 from Columbia, and her PhD in 1921 from Columbia, where she stayed on to teach. She entered the relatively new at the time field of nutritional chemistry, laying the groundwork for those after her. While Caldwell was well-known for the quality of research and diligence in her work, she also maintained a work-life balance, as an avid hiker, doting aunt, and gardener.
(1880-1972) Emma Perry Carr first attended Mr. Holyoke College then transferred to and received her B.S. from the University of Chicago in 1905. After a short duration as an instructor at Mt. Holyoke, Dr. Carr returned to the University of Chicago to receive her PhD in 1910. She returned to Mt. Holyoke to become a full professor and head of the department by the age of 33, a post she held for 33 years. Dr. Carr was also a devoted aunt,a fashionable dresser, and a talented storyteller. She had a relationship with Mary Sherrill, another professor at Mt. Holyoke, whom she shared a residence with for 26 years. Emma Perry Carr was the first recipient of the Garvan Medal.
(1867-1934) Much has been written about Marie Curie. She is, perhaps, the first historical figure to come to mind when a person says “Notable Woman in Science.” She is the first person to have been a twice Nobel Laureate. Marya Sklodowska was born in Poland, and lived through the loss of her eldest sister and mother by age 11. After graduating first her in class from high school, she attended a secret university because Polish universities could not admit women. She wished to go to Paris to study, so she worked and saved her money to do so. She was the first women to receive her Licence es Sciences Physiques from the Sorbonne in 1893, graduating first in her class again. She received her Licence es Sciences Mathematiques in 1894 from the same institution. In 1903, she attained her PhD from the University of Parish, the same year she was awarded the Nobel Prize in Physics. Difficulties continued in her personal life, such as the death of her husband in 1906, her own ill health due to radiation poisoning, and her constant fight for her place in her work. She broke so many barriers, being the first woman in so many circumstances.
(1909-1997) Mary Feiser was encouraged by her parents to excel academically. She attended Bryn Mawr and received her B.S. in chemistry in 1930. She then attended Radcliffe college and worked on her master’s thesis in the lab of Louis F. Feiser at Harvard. She received her A.M. in 1931 and married in 1932. She opted to continue to work in her husband’s lab instead of pursue a PhD because of the funding and Harvard facilities. With her help, 15 papers and 17 books were published by Feiser. However, Harvard never granted her a salary nor official title for 29 years. Even at 85 years of age, Mary Feiser continued to write and publish organic chemistry books, which were well received.
(1876-1950) Dorothy Hahn received her B.A. in chemistry from Bryn Mawr and went to work at Mt. Holyoke College under the auspices of Emma Perry Carr. Together, the two women were a force producing many women chemists. While Dr. Carr ran the chemistry department, it is said Dr. Hahn ran the organic chemistry department. Dr. Hahn pursued and recieved her Ph.D. from Yale University in 1916 due to a fellowship from the AAUW (American Association of University Women). Hahn also preceeded well-known scientists Gilbert Lewis and Irving Langmuir on a theory of valence electrons. Professor Hahn was a huge influence on organic chemistry, teaching, and women in chemistry.
(1906-1995) Allene Rosaland Jeanes was born and raised in Texas. She received her A.B with highest honors from Baylor University in 1928. She graduated with her M.A. from the University of California – Berkeley in 1929. She taught for awhile in a few different colleges, then decided to return to graduate school. She attained her PhD from the University of Illinois in 1938. While she wanted to go into pharmaceutical research, opportunities were limited. She took a position at the National Institute of Health. Her research took her through several government positions and had applications in the food industry. She was honored with many awards, including the Garvan Medal and Federal Women’s Award from the U.S. Civil Service Commission.
(1879-1968) The story of Ellen Gleditsch is not well known in her native Norway nor abroad, and signifies how difficult it was for women to be recognized for their work. She received her degree in pharmacology in 1902. She worked with Marie Curie for 5 years, and received her Licencee es Sciences from the Sorbonne in 1912. She went to work at Yale University despite the animosity toward her from the men at the U.S. institutions of Yale and Harvard and received her D.Sc. form Smith College in 1914. In 1929, Oslo University became embroiled in controversy over the decision to advance Ellen Gleditsch to the position of professional chair, and it took a letter from Marie Curie to help quell the public outrage. During her time in Oslo, she also provided a home for scientists fleeing Nazi Germany. She continued to be an advocate and mentor for women in the sciences until her death at age 88.
(1912-1998) Born in Missouri, Anna Jane Harrison was raised on a farm and her childhood science education tended to be “go out and find caterpillars.” She learned about Caterpillar tractors from her father for that assignment. Her high school science teachers inspired her interest in science, so she went to the University of Missouri to earn a B.A. in chemistry in 1933, a B.S. in education in 1935, a M.A. in chemistry in 1937, and a Ph.D. in physical chemistry in 1940. She was the first woman to earn a PhD at the institution. After meeting Lucy Picket and Emma Carr at a meeting of the American Chemical Society (ACS), she went on to work at Mt. Holyoke College, carrying on the traditions established there by Emma Carr and Dorothy Hahn. She also has several more “firsts” including being the first woman to chair the Division of Chemical Education of the ACS and the first woman elected president of the ACS in the 102 year history of the organization up to then. She was honored with the honorary degree of D.Sc. from ten instutitions. She enjoyed traveling and once stated, “What I really like is to go places one isn’t supposed to go.”
The Garvan Medalis an award from the American Chemical Society to recognize distinguished service to chemistry by women chemists. Nobel Prize: From the site:
Every year since 1901 the Nobel Prize has been awarded for achievements in physics, chemistry, physiology or medicine, literature and for peace. The Nobel Prize is an international award administered by the Nobel Foundation in Stockholm, Sweden. In 1968, Sveriges Riksbank established The Sveriges Riksbank Prize in Economic Sciences in Memory of Alfred Nobel, founder of the Nobel Prize. Each prize consists of a medal, personal diploma, and a cash award.
The twitter feed from @DoubleXSci since early December has featured Notable Historical and Modern Women in Science. Nearly 100 women were presented. Those women will be presented in a series here on the blog with the original tweeted links and information as well as with some additional information not able to be presented in 140 characters. Each woman could have multiple pages written on her; however, I have limited each to a paragraph. I hope you look up more on these women.
The International Year of Chemistry 2011 recently wrapped up, so I’d like to share a little more about some historical women in chemistry.
The first historical woman in chemistry is perhaps Miriam the Alchemist, who lived in the 1st or 2nd century C.E. Her writings survived centuries. She has several aliases: Mary, Maria, and Miriam the Prophetess or Jewess. Even though she was an alchemist, which was mostly a mystical field during her time, her inventions and contributions yielded long-lived practical laboratory equipment. Miriam the Alchemist contributed major inventions and improvements to existing technology, as well as the water bath. The water bath is still in use today for many chemical experiments, as was dubbed “bain-marie” in the 14th century.
Agnes Fay Morgan (1884-1968) was a pioneer in vitamin research. She earned her B.S., M.S., and Ph.D. from the University of Chicago. She also established Iota Sigma Pi, an honor society for women chemists. Morgan received the Garvan Medal and the Borden Award and was the only one of her family to attend college. Her efforts brought both nutrition and home economics to scientific disciplines. Besides her teaching position and doing research in academia, she also was an accomplished administrator and worked with the government on many occasions. She had many firsts in her research and an enormous number of publications.
Colloid Chemist Marjorie Jean Young Vold (1913-1991) was a prolific and distinguished scientist. She earned her B.S. and Ph.D. from University of California, Berkeley. Vold balanced academic and industrial chemist careers spanning over five decades. At the age of 45, she was diagnosed with multiple sclerosis but continued her dual chemistry careers despite being confined to a wheelchair. She was the LA Times Woman of the Year and received the Garvan Medal. One month before her death, Vold submitted her final paper, which was published posthumously.
Lucy Weston Pickett (1904-1997) chose a career in chemistry over marriage. She earned her B.A. and M.A. from Mt. Holyoke College and her Ph.D. from the University of Illinois and advanced through her academic career to become department chair. She received the Garvan Medal and two honorary D.Sc. degrees. She was so influential in her career that a fund was established in her name upon her retirement, which she requested be used to bring female speakers to the department.
Mary Lura Sherrill (1888-1968) was known for synthesis of antimalarial drugs. She earned her B.A. and M.A. from Randolph-Macon College and her Ph.D. from the University of Chicago. Her academic career included becoming the chair of her department. She also received the Garvan Medal.
Chemist, Ecologist, and Home Economist Ellen Swallow Richards (1842-1911) was one of Vassar College’s first graduates, with an A.B. She earned her B.S. from MIT as its first woman graduate and her M.A. from Vassar College the same year. She had many firsts, including improving the standard of living by applying chemistry to sanitation, opening up science for women, and developing the home economics movement. Richards was also the first woman member of the American Institute of Mining and Metallurgical Engineers and first woman teacher at the MIT department of sanitary chemistry. She was awarded an honorary doctorate from Smith College.
Grace Medes (1886-1967) was a pioneer in metabolism research. She earned her B.A. and M.A. from the University of Kansas and her Ph.D. from Bryn Mawr. Her academic career progressed until she became a department head and chairman. She earned the Garvan Medal and several Distinguished Service Citations. Dr. Medes was at the forefront of cancer research and named a rare disease, tyrosinosis [PDF].
Bacteriologist and Chemist Mary Engle Pennington (1872-1952) was a food preservation pioneer. Despite completing the requirements for a B.S. degree at the University of Pennsylvania, she was granted only a Certificate of Proficiency. She earned her Ph.D. from the University of Pennsylvania. Dr. Pennington worked with the government although she hid her gender to receive her credentials. Called “ice woman” due to her advances in food preservation and refrigeration, she was known for a warm personality. Pennington was awarded numerous fellowships and was a member of many other professional organizations and honoraries, and received the Notable Service Medal and the Garvan Medal.
Pauline Beery Mack (1891-1974) was an instructor and publisher and loved chemistry. She earned her B.A. from Missouri State University, M.A. from Columbia University, Ph.D. from Pennsylvania State College, and a D.Sc. from Moravian College for Women, Western College for Women. She began the publication the Chemistry Leaflet which eventually became published by the American Chemical Society. She received the Distinguished Daughters of Pennsylvania Medal, the Garvan Medal, and the Astronauts Silver Snoopy Award. Dr. Mack also maintained a busy life outside of science, including basketball and music. She taught more than 12,000 undergraduates over her 30 years at Penn State. She was adept at securing funding for her research, no small feat for a woman in the 1930s. Mack continued into an administrative career and worked full time until she was 79.
The Garvan Medal is an award from the American Chemical Society to recognize distinguished service to chemistry by women chemists.
The Borden Award is given in recognition of distinctive research by investigators in the United States and Canada which has emphasized the nutritive significance of milk or any of its components.
LA Times Woman of the Year began as annual awards ceremony to honor women for individual achievement and was awarded from 1950 to 1976.
Lavoisier Prize (Lavoisier Medal) is awarded by the SCF to an individual or institution to distinguish the work or activities involving the chemistry honor.
Astronauts Silver Snoopy Award candidates will have made contributions toward enhancing the probability of mission success, or made improvements in design, administrative/technical/production techniques, business systems, flight and/or systems safety or identification and correction or preventive action for errors.
In this edition of Notable Women in Science, I focus on women working in physics, typically traditional physics rather than astrophysics. There is no particular reason to make this distinction other than it allows me to choose a small group of women to highlight within a parameter set. These women are listed in no particular order.
Vera E. Kistiakowsky spent much of her career as a professor at MIT. Born in 1928, she received her A.B. from Mt. Holyoke College in 1948 and her Ph.D. from the University of California – Berkeley in 1952, both degrees in chemistry. Her chosen career stemmed from advice from her father to support herself and not depend on another person to support her. Her father was a respected physical chemistry professor at Harvard and his support in her chosen activities was instrumental to her success. She entered college at the age of 15, choosing a pre-med major. She changed to chemistry due to Mt. Holyoke’s extraordinary female faculty at the time. While her degrees are in chemistry, her studies and research were physics intensive.Graduating with her Ph.D. before her newly married husband hindered her initial job opportunities. She had several positions before eventually settling into a professorship at MIT. During her tenure at MIT, she was scientifically prolific with 86 technical publications as well as highly active in feminist activities, including organizing for the National Organization of Women (NOW), Women In Science and Engineering (WISE), the Association for Women in Science (AWIS), and an ad hoc committee in the American Physical Society (APS) on women physicists to name a few.
Helen Thom Edwards is recognized for her work with the Tevatron. She was born in 1936 and received both her B.A. and Ph.D. from Cornell University in 1957 and 1966, respectively. Her interest in science was outside that of her family’s interests, so she was used to paving her own way. Her technical and mechanical acumen served her well as a group leader at the Fermilab. Dr. Edwards is a team player and insists upon acknowledging the contributions of her colleagues in her and Fermilab’s success.
[Edited, 11/26/12, 14:43 ET]: Vandana Shiva was trained in physics and the philosophy of science and now works as an environmentalist, achieving considerable global prominence. She was born in 1952 and, according to most sources, earned a B.A. in physics, a master’s in philosophy of science, and a Ph.D. in physics. When she began her training as a nuclear scientist, she encountered a hostile environment, which caused her to emigrate west. Her experiences led her to become a prominent (and extremely controversial) environmentalist and into the position of Director at the Research Foundation for Science, Technology and Natural Resources Policy in Dehradun, India. She writes books and publishes articles in the area of environmentalism. [ETA: As a commenter notes below, Shiva also has been embroiled in controversy and accused of taking an anti-scientific stance over her assertions about “terminator seeds.”]
Born in 1954, she received her B.S. and Ph.D. at Vrije University in Brussels in 1975 and 1980, respectively. Her interest in science and math was nurtured by her parents who also encouraged her independence. In 1984, she received the Louis Empain prize for physics for the work she accomplished before the age of 29. The prize was followed by tenure in her position at the Free University Brussels. She moved into a position at Rutgers and also worked at the AT&T Bell Laboratories. In 1992, she was awarded a MacArthur Foundation Fellowship followed by the Steele Prize from the American Mathematical Society in 1994. She has continued to receive honors and ovations to this day.
Janet M. Conrad researches neutrinos. She was born in 1963 and received her B.A. from Swarthmore College in 1985, her M.Sc. from Oxford University in 1987, and her Ph.D. from Harvard University in 1993. After a postdoctoral stint at Columbia University, she moved into a professor position there. In 2008, she moved to MIT. She has received many awards, including an NSF CAREER Award, an Alfred P. Sloan Research Fellow, and the Maria Goeppert-Mayer Award from the APS. She can be found involved in research and teaching at MIT, as well as communicating science to scientists and general audiences around the country.
Reka Albert blends cross and inter-disciplinary expertise. She received her B.S. and M.S. from the Babes-Bolyai University in Romania and her Ph.D. from the University of Notre Dame in 2001. After a postdoctoral position at the University of Minnesota, she joined the faculty at Pennsylvania State University, where she is currently a professor in the physics department. She has received several awards for her work, including a Sloan Research Foundation Fellowship, an NSF Career Award, and the Maria Goeppert-Mayer Award.
Louis Empain Prize is awarded every five years to a young Belgian scientists on the basis of work done before the age of 29.
MacArthur Foundation Fellowship is awarded to individuals who have shown extraordinary originality and dedication in their creative pursuits and a marked capacity for self-direction. The Steele Prize is awarded for cumulative work of mathematical contribution to the field. The NSF Career Award is a highly competitive grant awarded to early career scientists. Alfred P. Sloan Fellowships are awarded to distinguished scholars with high potential for impact in their respective fields. The Maria Goeppert-Mayer Award recognizes outstanding achievement by a woman physicist in the early years of her career. The opinions expressed in this post do not necessarily agree or conflict with those of the DXS editorial team and contributors.
Leah Gerber is an Associate Professor of ecology at Arizona State University. Her research is motivated by a desire to connect academic pursuits in conservation science to decision tools and effective conservation solutions. This approach includes a solid grounding in natural history and primary data collection, quantitative methods and an appreciation for the interactions between humans and the environment. She is keenly aware of the need for the communication of scientific results to the public and to government and non-governmental agencies. This communication is essential for the translation of scientific results into tenable conservation solutions.
DXS: First, can you give me a quick overview of what your scientific background is and your current connection to science?
LG: I learned about ecology and environmental conservation as an undergraduate and quickly became motivated to do science that impacted the real world of conservation. Learning about the impacts of humans on nature was a wake-up call for me, and inspired me to channel my feeling of concern for the demise of nature in a positive way.
From there, I have walked the tightrope between science and policy. After getting my undergraduate degree in environmental biology, I wanted to do more than just the science. So I enrolled in a masters program at the University of Washington – an interdisciplinary program called Marine Affairs. It was a great experience, but I wanted to have more substance to my science background – I wanted to know how to do the science in addition to how to apply the science.
This compelled me to enter a PhD at the University of Washington, which was largely funded by NOAA. My thesis involved trying to figure out how to make decisions about endangered species – how to determine which were endangered and which were threatened. This was a perfect project given my interest in developing tools to solve problems. After finishing my PhD, I did a postdoc at the National Center for Ecological Analysis and Synthesis (NCEAS) and developed approaches for marine reserve design and endangered species recovery. I was at NCEAS for three years before starting on the tenure track at Arizona State University. I’ve been at ASU for about 10 years now.
A major theme in my work has remained constant – that is, how to use the information we are generating in the natural and social sciences to better manage our natural world. Pre-tenure I focused a lot more on doing the science, publishing in good journals, and hoping that it made its way into good policy. Now that I am midcareer, meaning that I have a good amount of papers and tenure, I am enjoying the opportunity to work with practitioners outside of academia. For instance, I just got off the phone with someone from National Geographic regarding my recent publicationon seafood health and sustainability. In that study, we performed an analysis regarding seafood in the context of health and sustainability, to answer simple questions like, what to order when out to sushi? How do we educate about health benefits and risks? We will be organizing a workshop to help restaurant chains, grocery stores, as well as environmental NGOs identify a path forward in informing consumers about healthy and sustainable seafood choices. As a tenured professor, I feel fortunate to have the opportunity to work at the science-policy interface and to give society some science that is truly applicable.
DXS: It is too bad that you have to wait until you are more established and have tenure to go out and engage with the public, because this type of thing is just so important!
LG: Yes, I agree. There isn’t a clear path in academia when it comes to public engagement. But in recent years I have felt optimistic – the landscape within academia is starting to change, and at ASU this change is noticeable. We have a fabulous president, Michael Crow, who has really transformed ASU from just another state institution to a leader in sustainability. Part of this is the establishment of the Global Institute for Sustainability, and one of Michael Crow’s mantras is “community embeddedness.” He is really on board with this type of thing and I have seen evidence of his commitment trickle down throughout the University. For instance, when I first arrived, I had to justify and explain why I was serving on these federal recovery teams for endangered species. Now I feel that there is no justification needed. Developing solutions is not only so important for society, but should also be a key aspect of what we do at Universities.
DXS: We were introduced by another fantastic science communicator, Liz Neeley, who you met at a communications workshop. Why is it important to take part in this type of training?
LG: I met the Fantastic and Fashionable Liz through the Leopold Leadership Program, offered through the Woods Institute for the Environment at Stanford University. The Leopold Leadership training was the best professional development experience of my career, and has made me a better translator and communicator of science to policy. Pre-Leopold, I had little training in communications, and there I was, in a teaching position where I taught hundreds students. I thought to myself, well, how do I do this? The Leopold experience has solidified my commitment to teaching students about communication and engaging in policy.
One development emerging from this training is a science communication symposium at the AAAS meeting. Elena Bennett and I are giving a talk on overcoming institutional barriers for community engagement, and we will address the issues head on. We put out a survey asking others if they faced institutional barriers, and how they might work to engage more.
DXS: What ways do you express yourself creatively that may not have a single thing to do with science?
LG: I have 2 young kids, a 3yo and a 7yo. Being a mom helps me keep it real – I love that I get to enjoy the awe of discovering the world with my girls. We just got a puppy this weekend and we are having fun dressing her up and painting her nails (only partly joking). Other things that I do that are creative – truthfully, I am uninteresting – I don’t bake bread or go to the opera. I just work and take care of my kids. I practice yoga for my own sanity and also love to work in the garden. Doing these things gives me a reason to pause and step off the treadmill of keeping up with everything.
DXS: Do you find that your scientific background informs the creativity you have with your kids or your yoga practice, even though what you do may not specifically be scientific?
LG: I think there is synergy with my science and my kids and my yoga practice in helping me to accept things and be mindful – but not in any conscious way. For instance, when doing my science, the type A person that I am, I have an inclination to keep pushing, pushing, pushing. My kids and my yoga help me to shift gears and accept that things are going to happen when they happen. I try to let the kids be kids, including the associated chaos, and accept that this is a snapshot in time that they will be little. Now I find joy in that chaos. Having kids and yoga gives me a little more perspective, and the knowledge that things aren’t lined up and neatly placed in a box. It rounds me out.
DXS: Are your kids are major influencers in your career?
LG: My first child, Gabriella, was born just after I submitted my application for tenure – so it was good timing. And I was able to slow down. I quickly realized that I wasn’t able to work a 60+hour week. Before kids, I lived to work. Now, I work to live. I absolutely love my job and I feel so lucky that I have a career that I believe in and that I am actually paid to do it – it’s not just a hobby. But having kids made me chill out a little. If I get a paper rejected, I can let it go instead of lamenting about it for weeks. It has made me healthier. I don’t necessarily know if it has had positive impact on my career – time will tell. While my publication rate may be slightly smaller, I think my work now has different dimensions, and greater depth.
I am still pretty passionate about my work, and my kids know what I do and are proud of it. They share it with their classmates, and take every opportunity to wax poetic about how their mom saves animals in the ocean. They also have a built in conservation effort – my 7YO gets irritated when she can’t find a compost bin, and her new thing is to only fill her cup half way because she will only drink a little bit of water.
DXS: When you decided to have children, did your colleagues view you differently? Did they consider that you were sending your career down the tubes or was it a supportive environment?
LG: I honestly had a really positive experience. I can’t think of any negative sentiments from my colleagues, and they were actually really supportive. For instance, when I was pregnant with my first daughter, ASU did not have a maternity leave policy. Before that, you would have to take sick leave. So my colleague worked within the parameters of the unit to give me maternity leave. And then with my second daughter, our new president had established a maternity policy.
The support of my colleagues at ASU has made me feel loyal to my institution. Normally, I am loyal to people and not institutions, but overall, the support has been fabulous. Of course, with having the kids in each case, I did decline a lot of invitations – some pretty significant ones – but I did not have a desire to drag a newborn to give a talk, especially when I was nursing. And it was hard for me to do this at times, especially given my career driven nature, and I had to learn to accept that there would be other opportunities.
I had to shift it down a notch and realize that the world wasn’t going to freeze over, and that I could shift it back to high gear later. With “mommy brain”, I knew I wasn’t going to be at the top of my game at that point in my life. But I have incredible role models. Most notable is Jane Lubchenco, currently the Director of the National Oceanic and Atmospheric Administration. During the first part of her career, she shared a position with her husband – each did 50% – and they did that on purpose so they’d be able to enjoy having children and effectively take care of them. Now, she is in the National Academy, is having major scientific impacts, and she did it all despite having kids. If she can do it, why cant the rest of us?
DXS: Given your experiences as a researcher, as a mother, and now as a major science communicator, do you feel that your ability to talk to people has evolved?
LG: Absolutely. I think that the Leopold Training Program, which selects 20 academics from North America to participate in retreats to learn how to be better communicate and lead, has re-inspired all who attended. It has recharged our batteries and allowed us to make realizations that doing good science and putting it out there via scientific publication is just not enough. We also have to push it out there and make it available to a broader, more diverse population. As part of the training, we also learned about different thinking styles – super analytical or super emotional – and after I returned, I had my lab group participate in this type of exercise. And now I feel like I can better assess a persons thinking style and adjust the way I communicate accordingly.
DXS: Did you always have the ability to talk to the general public or does having kids help you to better understand some of the nuances associated with science communication?
LG: I think so. In fact, I am thinking back to when I had a paper in Sciencecome out around the time that I had my first child. It got a lot of news coverage and was featured in Time magazine. I thought it was so cool at the time, but looking back on it I realized that have come a long way. I said something to a journalist, who then asked me to translate it into “plain English.” It was a little bit of a jab.
Now, with kids, I can tell you a lot more about my research and can better see the broader impact. Talking to them helps me to do that. Here is a conversation about my research with my daughter:
L: Mama is working on figuring out how to help the whales that people like to eat. It’s a big problem because some people like to eat whales and some like to see them swimming in the ocean.
G: What we have to do is let the people eat the whales in the ocean, and buy some whales from the pet store to put back in the ocean. How much do whales cost?
L: Good idea. But you can’t buy whales at the store. They are too big. And if we take them all out of the ocean there will be none left.
G: Well instead we should ask the people to eat bad things like sharks.
L: Another good idea. But if we take sharks out there will be no predators to eat the big fish. And the whole ecosystem would collapse.=
G: Well then the people should eat other things like fish instead of whales. They should buy a fishing pole and catch a fish and eat those instead of whales.
L: What about chicken, shouldn’t people just eat chicken?
G: Mama, we can’t kill chickens. Chickens are nicer than fish, so that’s why we have to eat fish.
L: What about just eating vegetables?
G: Oh mama, some people are meat-eaters. And there are no more dinosaurs. They all got extinct. They should have saved some of the dinosaur meat in the freezer for the meat-eaters. When the dinosaurs come back, there will be enough meat to eat and people won’t want to eat whales.
The simplicity of taking myself out of my research bubble and engaging with a creative (and nonlinear?) 7YO has taught me how to be a better communicator – with the media, with my students, and with the general population.
DXS: Do you think these efforts in science communication are helping to shift other peoples perspectives about who a scientist actually is? For instance, are we changing the old crazy haired white guy stereotype?
LG: Well, I hope so. A couple of examples – again, as a mom, one of my daughters a Girl Scout and I get to help with the troop. One of the themes was to teach about environmental and conservations awareness. We did this Crayola molding experiment where we put our fingers into cold water. We then did the same thing except we put modeling clay over our fingers before putting them into the cold water and to learn about adaptations to extreme environments. Also, we play games where they simulate fishing – what if there is plastic? What happens to you if you eat that? My hope is that this shows these young girls that science is both interesting and fun.
Another thing that just happened today is that I was contacted by Martha Stewart’s office, and it seems that some of my research results will be featured in the October issue of Martha Stewart Living. The message here is that I happen to care about the ocean, but I also love sushi. I also I care about health. I am not just a nerd in a lab coat. I am a mom, I do yoga, I have wonderful friends, and here is the kind of science that I do. It seems to me that it is better to connect with others when I can give them something that is relevant to their lives instead of a more abstract ecological theory.
DXS: If you had something you could say to the younger you about getting on your chosen career path, what would you say?
LG: I feel like I have been very effective at figuring out how to get from point A to point B, but less successful at savoring the process. I think that I’d tell myself to make time to celebrate the small victories. I have also learned to identify what kind of research is most exciting, and I would tell myself to say “no” to everything that is only moderately interesting. I tell my grad students that if you don’t dive in head first, you won’t ever know. So why just not give it a try! And if it doesn’t work, move on. Also, if something isn’t making you happy, change! Academia isn’t for everyone, and there is a lot more to life than science.