Researchers working at a lab at Harvard University have developed a technique that allows for taking the temperature of individual living cells. In their paper published in the journal Nature, the team describes their technique and just how precise temperature measurements taken with it can be.
The new thermometer developed by the team follows work by other researchers who have found that single atom impurities in diamond crystals (which typically are replaced with a nitrogen atom and a vacancy gap) can be ultrasensitive to changes in temperature—such fluctuations can be seen as a hindrance when attempting to use such material to hold quantum bits, but in the biological world, they can be used to very precisely measure temperature.
In their research the team at Harvard injected a single nanodiamond (a diamond just 100 nm in size) into a human cell. Once in place a green laser was shone onto the nanodiamond. Because it altered the spin state of an electron in the impurity, the light that was emitted was changed to red. The degree to which it was changed was then used to calculate the temperature of the interior of the cell. Following that experiment, the team injected two nanodiamonds into a single cell, then focused two separate green lasers onto them, then measured the red light that was emitted. This allowed them to measure the temperature difference between two locations in the same cell. Next, the team injected a nanodiamond and a gold particle into the cell. Once in place a green laser was shone onto the nanodiamond while another laser was shined onto the gold particle causing it to heat up. That heat was transferred to the rest of the cell and was subsequently measured by the nanodiamond.
Read more at: Phys.org