Author Archives: yoshi matsubara

Altruism Gene

Why do people show signs of altruistic (selfless/unselfish) behaviour such as donating money to a homeless person on the street, or even helping someone with their homework? You might be thinking that people are displaying these signs of empathy and generosity, simply because they care about the health of others, and believe that they should treat others the way in which they wanted to be treated. This general understanding is flawed because it provides no evidence to why some people may act selflessly, while others are only concerned about their own well-being. In order to fit the missing pieces necessary to complete the puzzle, we must take into consideration the possibility of there being an Altruism Gene. This gene variation can alter the way in which human beings undergo various tasks on a day-to-day basis.

Monkeys grooming one another is a form of altruism by Muhammad Mahdi Karim

There exist one prevalent theory that explains the evolution of altruism through natural selection. The principle of inclusive fitness, or the amount of offspring equivalents that an organism supports, was defined by W.D. Hamilton in 1964. Hamilton demonstrated that it is beneficial for these organisms to attempt to raise the fitness of other members of the population in order to pass on their genes. This is known as kin selection, and applies mainly to organisms that are genetically related. Hamilton’s Rule declares that a gene controlling altruism will only spread in a population if:

c < rb

where c is the reproductive cost to the organism displaying altruistic behaviour, r represents how closely related the altruist is to the recipient (since the recipient is more likely to share the altruism gene if it is more closely related to the altruist), and b is the degree to which the altruistic act benefits the recipient.

In a recent German study, researchers sampled DNA from 101 individuals and looked at the COMT gene, which is linked to positive emotions and possibly altruistic acts. The gene has 3 variations: Val/Val, Met/Met, and Val/Met. The researchers gave the participants a certain amount of money and told them that they could anonymously donate to a charity. They discovered that those participants with the Val/Val and Val/Met variations donated twice as much as those with the Met/Met version of the gene. This study demonstrated the link between altruism and a specific gene for the first time. 

Percentage of money donated to an impoverished child in Peru based on the COMT gene variation by Martin Reuter, et al.

Scientists have only scratched the surface in this field of study, as they believe that there are many altruism-related genes that are yet to be found. Thus, this evolutionary puzzle will require much more time until it is completed, and I believe that these findings will help us gain further insight on the nature of human beings.

– Yoshinao Matsubara

Mitigating Climate Change: Carbon Capture (Revised)

Have you heard concerns regarding climate change in the past few years? I think almost everyone has, which goes to show how serious this global issue really is.  One of the main causes of climate change is the release of excess carbon dioxide into the atmosphere, due to the burning of fossil fuels. If we could somehow reduce these greenhouse gas emissions, climate change would pose less of a threat to humanity. 

A solution to climate change

One solution that scientists have proposed in order to reduce the amount of atmospheric carbon dioxide is to capture carbon dioxide in the air and use the captured carbon dioxide as a source of chemical carbon for other processes. This process is known as “carbon capture and utilization” (CCU). Although the potential benefits of CCU are very promising, changing the carbon dioxide into a different form and using it in other chemical processes has been proven to be difficult. Although CCU has gained major traction over the past few years, it will still require a lot of time before it can be used industrially worldwide. Scientists are currently in the process of trying to find the least costly, and most efficient means of capturing carbon emissions to reduce climate change. 

Image: Carbon Capture and Utilization Process                          Source: Wikimedia Commons                                                           Relevance: Shows path of CO2 in this process

 

Carbon capture methods

One of the carbon capturing methods that has been showing promise in recent scientific studies, is the adsorption of carbon dioxide through the use of solid sorbents. Adsorption is the adhesion or the clinging of gas molecules onto a surface. In this case, the carbon dioxide molecules will stick to the solid surface of the sorbent, which leads to successful carbon capturing. The solid sorbents used in this method can be made of “porous carbonaceous materials, zeolites, alumina, silica, (or) metal-organic frameworks.” Adsorption of carbon dioxide can be categorized into two variations; physical and chemical adsorption. In physical adsorption, the transfer of carbon dioxide into the solid sorbent occurs due to the Van der Waals interactions (attraction between neutral molecules) between the sorbent and the carbon dioxide. The issue with these physical sorbents is that they have “poor selectivity for CO2 and low CO2 adsorption capacities.” A means of improving both the carbon dioxide selectivity and the carbon dioxide adsorption capacities of these sorbents is by adding basic groups to the sorbent surface, which can strengthen its interactions with the acidic carbon dioxide. Although carbon dioxide adsorption via solid sorbents is very promising, more scientific work needs to be done to improve the adsorption capabilities of sorbents.

YouTube Preview Image                                                      Video: Carbon Capture Plant in Squamish, BC

Although CCU has gained major traction over the past few years, it will still require a lot of time before it is used industrially worldwide, and this timeline is uncertain. Moving forward, scientists must also be wary of the energy consumption of these carbon capture mechanisms, as they could use “a quarter of global energy in 2100”.

– Yoshinao Matsubara

Mitigating Climate Change: Carbon Capture

Climate change is the change of weather and the rise of sea levels on the planet Earth. Climate change is an extremely relevant global issue since it can lead to flooding and extreme weather conditions which can endanger life on earth. As a result, it is of utmost importance to find solutions that can help mitigate the effects of climate change. One of the main causes of climate change is the release of excess carbon dioxide into the atmosphere, due to the burning of fossil fuels.

Image: Climate Change
Source: CC0 Public Domain

A solution to climate change

One solution that scientists have proposed in order to reduce the amount of atmospheric carbon dioxide is to capture carbon dioxide in the air and use the captured carbon dioxide as a source of chemical carbon for other processes. This process is known as “carbon capture and utilization” (CCU). Although the potential benefits of CCU are very promising, changing the carbon dioxide into a different form and using it in other chemical processes has been proven to be difficult, mainly due to the thermodynamic stability of carbon dioxide. Although CCU has gained major traction over the past few years, it will still require a lot of time before it can be used industrially worldwide. Scientists are currently in the process of trying to find the least costly, and most efficient means of capturing carbon emissions to reduce climate change. 

YouTube Preview Image                                                      Video: Carbon Capture Plant in Squamish, BC

Carbon capture methods

One of the carbon capturing methods that has been showing promise in recent scientific studies, is the adsorption of carbon dioxide through the use of solid sorbents. Adsorption is the adhesion or the clinging of gas molecules onto a surface. In this case, the carbon dioxide molecules will stick to the solid surface of the sorbent, which leads to successful carbon capturing. The solid sorbents used in this method can be made of “porous carbonaceous materials, zeolites, alumina, silica, (or) metal-organic frameworks.” Adsorption of carbon dioxide can be categorized into two variations; physical and chemical adsorption. In physical adsorption, the transfer of carbon dioxide into the solid sorbent occurs due to the van der Waals interactions between the sorbent and the carbon dioxide. The issue with these physical sorbents is that they have “poor selectivity for CO2, and low CO2 adsorption capacities.A means of improving both the carbon dioxide selectivity and the carbon dioxide adsorption capacities of these sorbents is by adding basic groups to the sorbent surface, which can strengthen its interactions with the acidic carbon dioxide. These sorbents primarily use alkalis to act as basic groups. In terms of alkali-based sorbents, scientists have been favouring the use of potassium carbonate and sodium carbonate. Although carbon dioxide absorption via solid sorbents is very promising, more scientific work needs to be done to improve the adsorption capabilities of sorbents.

Another carbon capturing method that scientists have been favouring is the separation of carbon dioxide via membranes. These membranes are selectively permeable to carbon dioxide which leads to separation of carbon dioxide from other chemicals.

All in all, the development of these innovative carbon capturing mechanisms is helping to mitigate climate change and scientists are working hard to refine these techniques. 

– Yoshinao Matsubara