Reference terms from Wikipedia, the free encyclopedia
 

Isothermal microcalorimetry

Isothermal microcalorimetry (IMC) is a laboratory method for real-time monitoring and dynamic analysis of chemical, physical and biological processes. Over a period of hours or days, IMC determines the onset, rate, extent and energetics of such processes for specimens in small ampoules (e.g. 3–20 ml) at a constant set temperature (c. 15 °C–150 °C).

IMC accomplishes this dynamic analysis by measuring and recording vs. elapsed time the net rate of heat flow (μJ/sec = μW) to or from the specimen ampoule, and the cumulative amount of heat (J) consumed or produced.

IMC is a powerful and versatile analytical tool for four closely related reasons:

The IMC method of studying rates of processes is thus broadly applicable, provides real-time continuous data, and is sensitive. The measurement is simple to make, takes place unattended and is non-interfering (e.g. no fluorescent or radioactive markers are needed).

However, there are two main caveats that must be heeded in use of IMC:

In general, possible applications of IMC are only limited by the imagination of the person who chooses to employ it as an analytical tool and the physical constraints of the method. Besides the two general limitations (main caveats) described above, these constraints include specimen and ampoule size, and the temperatures at which measurements can be made. IMC is generally best suited to evaluating processes which take place over hours or days. IMC has been used in an extremely wide range of applications, and many examples are discussed in this article, supported by references to published literature. Applications discussed range from measurement of slow oxidative degradation of polymers and instability of hazardous industrial chemicals to detection of bacteria in urine and evaluation of the effects of drugs on parasitic worms. The present emphasis in this article is applications of the latter type—biology and medicine.

 
Note:   The above text is excerpted from the Wikipedia article Isothermal microcalorimetry, which has been released under the GNU Free Documentation License.
 

Check out these latest Nanowerk News:

 

Researchers develop a new predictive model for designing 2D perovskites

By separating dielectric-screening effects from structural distortion, the study offers practical design rules for tuning excitons in 2D perovskites.

Orbitronics breakthrough points to low-power memory

Researchers directly used orbital currents in a magnetic device, producing much stronger signals for future low-energy memory and processors.

Microscopy at the space-time limit

Ultrafast scanning tunneling microscopy reaches the quantum mechanical space-time limit for the first time.

Programmable molecular machines are getting closer

Researchers created a highly stable electrically controlled DNA origami switch that regulates molecular functions and keeps working through hundreds of thousands of cycles.

Nanozyme tags reveal where nanoparticles go in cells

A new nanozyme labeling method maps nanoparticle interactions in living cells, showing how targeting alters trafficking and could guide better nanomedicines.

Light-written magnetic memory moves closer

Researchers used laser pulses to write and read antiferromagnetic data, opening a path to faster, lower-energy memory linked to optical networks.

Laser-controlled molecules reveal hidden reaction dynamics

Synchronized infrared lasers steer molecules between structures, exposing clear spectral fingerprints and new ways to study chemical reactions.

MOF thin films reveal a denser, less porous structure than expected

Advanced diffraction and modeling show a widely studied MOF thin film is densely packed, reshaping expectations for sensors, microelectronics and magnetic storage.

Atomic-scale insights clarify hidden defect signals in carbon materials

New analysis links long-ambiguous carbon defect peaks to specific atomic structures, helping improve material design for energy and electronics.

Room-temperature photon source brings quantum security closer to deployment

A compact plug-and-play device produces single photons without cryogenic cooling, easing integration with quantum-secure communication networks.