Mario José Molina-Pasquel Henríquez[a] (19 March 1943 – 7 October 2020)[7] was a Mexican physical chemist. He played a pivotal role in the discovery of theAntarctic ozone hole, and was a co-recipient of the 1995Nobel Prize in Chemistry for his role in discovering the threat to the Earth'sozone layer fromchlorofluorocarbon (CFC) gases. He was the first Mexican-born scientist to receive a Nobel Prize in Chemistry and the third Mexican-born person to receive a Nobel prize.[8][9][10]
Molina was born in Mexico City to Roberto Molina Pasqual and Leonor Henriquez. His father was a lawyer and diplomat who served as an ambassador to Eritrea, Australia and the Philippines.[12] His mother was a family manager. With considerably different interests than his parents, Mario Molina went on to make one of the biggest discoveries in environmental science.
Mario Molina attended both elementary and primary school in Mexico.[13] However, before even attending high school, Mario Molina had developed a deep interest in chemistry. As a child he converted a bathroom in his home into his own little laboratory, using toy microscopes and chemistry sets. Ester Molina, Mario's aunt, and an already established chemist, nurtured his interests and aided him in completing more complex chemistry experiments.[12] At this time, Mario knew he wanted to pursue a career in chemistry, and at the age of 11, he was sent to a boarding school in Switzerland atInstitut auf dem Rosenberg, where he learnt to speak German. Before this, Mario had initially wanted to become a professional violinist, but his love for chemistry triumphed over that interest.[13] At first Mario was disappointed when he arrived at the boarding school in Switzerland due to the fact that most of his classmates did not have the same interest in science as he did.[14]
Molina's early career consisted of research at various academic institutions. Molina went on to earn his bachelor's degree in chemical engineering at theNational Autonomous University of Mexico (UNAM) in 1965. Following this, Molina studied polymerization kinetics at theAlbert Ludwig University of Freiburg, West Germany,[13] for two years. Finally, he was accepted for graduate study at the University of California, Berkeley. After earning his doctorate he made his way to UC Irvine.[15] He then returned to Mexico where he kickstarted the first chemical engineering program at his alma mater. This was only the beginning of his chemistry endeavors.
Mario Molina began his studies at theUniversity of California at Berkeley in 1968, where he would obtain his PhD in physical chemistry. Throughout his years at Berkeley, he participated in various research projects such as the study of molecular dynamics using chemical lasers and investigation of the distribution of internal energy in the products of chemical and photochemical reactions.[13] Throughout this journey is where he worked with his professor and mentorGeorge C. Pimentel who grew his love for chemistry even further.[13] After completing his PhD in physical chemistry, in 1973, he enrolled in a research program at UC Berkeley, withSherwood Rowland. The topic of interest was Chlorofluorocarbons (CFCs) . The two would later on make one of the largest discoveries in atmospheric chemistry. They developed their theory of ozone depletion, which later influenced the mass public to reduce their use of CFCs. This kickstarted his career as a widely known chemist.
Between 1974 and 2004, Molina variously held research and teaching posts at University of California, Irvine, theJet Propulsion Laboratory atCaltech, and theMassachusetts Institute of Technology (MIT), where he held a joint appointment in the Department of Earth Atmospheric and Planetary Sciences and the Department of Chemistry.[5] On 1 July 2004, Molina joined the Department of Chemistry and Biochemistry atUniversity of California, San Diego, and the Center for Atmospheric Sciences at theScripps Institution of Oceanography.[16]In addition he established a non-profit organization, which opened the Mario Molina Center for Strategic Studies in Energy and the Environment (Spanish:Centro Mario Molina para Estudios Estratégicos sobre Energía y Medio Ambiente) in Mexico City in 2005. Molina served as its director.[17]
Molina served on the board of trustees for Science Service, now known asSociety for Science & the Public, from 2000 to 2005.[18] He also served on the board of directors of theJohn D. and Catherine T. MacArthur Foundation (2004–2014),[19] and as a member of the MacArthur Foundation's Institutional Policy Committee and its Committee on Global Security and Sustainability.[20]
Molina was nominated to thePontifical Academy of Sciences as of 24 July 2000.[21] He served as a co-chair of the Vatican workshop and co-author of the reportWell Under 2 Degrees Celsius: Fast Action Policies to Protect People and the Planet from Extreme Climate Change (2017) withVeerabhadran Ramanathan andDurwood Zaelke. The report proposed 12 scalable and practical solutions which are part of a three-lever cooling strategy tomitigate climate change.[22][23]
In 2020, Mario Molina contributed to research regarding the importance of wearing face masks amid the SARS-COV-2 pandemic. The research article titled "Identifying airborne transmission as the dominant route for the spread of COVID-19" was published in theProceedings of the National Academy of Sciences of the United States of America Journal in collaboration with Renyi Zhang, Yixin Li, Annie L. Zhang and Yuan Wang.[31]
Molina joined the lab of Professor F. Sherwood Rowland in 1973 as a postdoctoral fellow. Here, Molina continued Rowland's pioneering research into "hot atom" chemistry, which is the study of chemical properties of atoms with excess translational energy owing to radioactive processes.[32][33]
This study soon led to research into chlorofluorocarbons (CFCs), apparently harmless gases that were used in refrigerants, aerosol sprays, and the making of plastic foams.[34] CFCs were being released by human activity and were known to be accumulating in the atmosphere. The basic scientific question Molina asked was "What is the consequence of society releasing something to the environment that wasn't there before?"[33]
Rowland and Molina had investigated compounds similar to CFCs before. Together they developed the CFC ozone depletion theory, by combining basic scientific knowledge about the chemistry of ozone, CFCs and atmospheric conditions with computer modelling. First Molina tried to figure out how CFCs could be decomposed. At lower levels of the atmosphere, they were inert. Molina realized that if CFCs released into the atmosphere do not decay by other processes, they will continually rise to higher altitudes. Higher in the atmosphere, different conditions apply. The highest levels of the stratosphere are exposed to the sun's ultraviolet light. A thin layer of ozone floating high in the stratosphere protects lower levels of the atmosphere from that type of radiation.[34]
Molina theorized that photons from ultraviolet light, known to break down oxygen molecules, could also break down CFCs, releasing a number of products includingchlorine atoms into the stratosphere. Chlorine atoms (Cl) areradicals: they have an unpaired electron and are very reactive. Chlorine atoms react easily with ozone molecules (O3), removing one oxygen atom to leave O2 andchlorine monoxide (ClO).[34][35]
Cl· +O 3 → ClO· +O 2
ClO is also a radical, which reacts with another ozone molecule to release two more O2 molecules and a Cl atom.
ClO· +O 3 → Cl· + 2O 2
The radical Cl atom is not consumed by this pair of reactions, so it remains in the system.[34][35]
Molina and Rowland predicted that chlorine atoms, produced by this decomposition of CFCs, would act as an ongoingcatalyst for the destruction of ozone. When they calculated the amounts involved, they realized that CFCs could start a seriously damaging chain reaction to the ozone layer in the stratosphere.[36][32][33]
Rowland and Molina's findings were disputed by commercial manufacturers and chemical industry groups, and a public consensus on the need for action only began to emerge in 1976 with the publication of a review of the science by theNational Academy of Sciences. Rowland and Molina's work was further supported by evidence of the long-term decrease in stratospheric ozone over Antarctica, published byJoseph C. Farman and his co-authors inNature in 1985. Ongoing work led to the adoption of theMontreal Protocol (an agreement to cut CFC production and use) by 56 countries in 1987, and to further steps towards the worldwide elimination of CFCs from aerosol cans and refrigerators. By establishing this protocol, the amount of CFCs being emitted into the atmosphere decreased significantly, and while doing so, it has paced the rate of ozone depletion and even slowed climate change.[39][40] It is for this work that Molina later shared theNobel Prize in Chemistry in 1995 withPaul J. Crutzen andF. Sherwood Rowland.[36] The citation specifically recognized him and his co-awardees for "their work in atmospheric chemistry, particularly concerning the formation and decomposition of ozone."[41]
Following this in 1985, afterJoseph Farman discovered a hole in the ozone layer in Antarctica, Mario Molina led a research team to further investigate the cause of rapid ozone depletion in Antarctica. It was found that the stratospheric conditions in Antarctica were ideal for chlorine activation, which ultimately causes ozone depletion.[12]
After the successful implementation of theMontreal Protocol, Molina's continued advocacy for climate action helped shape global environmental policies. His work also contributed to the development of international climate agreements, such as theParis Agreement in 2015, which aimed to limit global temperature rise and reduce emissions, including those of harmful chemicals like CFCs.[42]
Molina received numerous awards and honors,[5][6] including sharing the 1995 Nobel Prize in chemistry with Paul J. Crutzen and F. Sherwood Rowland for their discovery of the role ofCFCs inozone depletion.[1]
Molina won the 1987Esselen Award of the Northeast section of the American Chemical Society, the 1988Newcomb Cleveland Prize from the American Association for the Advancement of Science, the 1989NASA Medal for Exceptional Scientific Advancement and the 1989 United Nations Environmental ProgrammeGlobal 500 Award. In 1990,The Pew Charitable Trusts Scholars Program in Conservation and the Environment honored him as one of ten environmental scientists and awarded him a $150,000 grant.[5][48][49]In 1996, Molina received the Golden Plate Award of theAmerican Academy of Achievement.[50] He received the 1998Willard Gibbs Award from the Chicago Section of the American Chemical Society[51] and the 1998 American Chemical Society Prize for Creative Advances in Environment Technology and Science.[52] In 2003, Molina received the 9th AnnualHeinz Award in the Environment.[53]
On 8 August 2013, US president Barack Obama announced Molina as a recipient of thePresidential Medal of Freedom,[55] saying in the press release:
Mario Molina is a visionary chemist and environmental scientist. Born in Mexico, Dr. Molina came to [The United States] to pursue his graduate degree. He later earned the Nobel Prize in Chemistry for discovering how chlorofluorocarbons deplete the ozone layer. Dr. Molina is a professor at the University of California, San Diego; Director of the Mario Molina Center for Energy and Environment; and a member of the President's Council of Advisors on Science and Technology.[4]Molina was one of twenty-two Nobel Laureates who signed the thirdHumanist Manifesto in 2003.[56]
Molina married fellow chemist Luisa Y. Tan in July 1973. They met each other when Molina was pursuing his PhD at theUniversity of California, Berkeley. They moved toIrvine, California in the fall of that year.[69] The couple divorced in 2005.[40] Luisa Tan Molina is now the lead scientist of the Molina Center for Strategic Studies in Energy and the Environment inLa Jolla, California.[70] Their son, Felipe Jose Molina, was born in 1977.[13][71] Molina married his second wife, Guadalupe Álvarez, in February 2006.[13]
Molina died on 7 October 2020, aged 77, due to a heart attack.[72][40]
^abcd"Mario Molina".Science History Institute. 12 December 2017. Archived fromthe original on 25 October 2018. Retrieved25 October 2018.
^abHolleman, Arnold Frederick; Aylett, Bernhard J.; Brewer, William; Eagleson, Mary; Wiberg, Egon (2001).Inorganic chemistry (1st English ed.). Academic Press. p. 462.
