Title |
On the specific heat capacity enhancement in nanofluids
|
---|---|
Published in |
Discover Nano, February 2016
|
DOI | 10.1186/s11671-015-1188-5 |
Pubmed ID | |
Authors |
Reinhard Hentschke |
Abstract |
Molten salts are used as heat transfer fluids and for short-term heat energy storage in solar power plants. Experiments show that the specific heat capacity of the base salt may be significantly enhanced by adding small amounts of certain nanoparticles. This effect, which is technically interesting and economically important, is not yet understood. This paper presents a critical discussion of the existing attendant experimental literature and the phenomenological models put forward thus far. A common assumption, the existence of nanolayers surrounding the nanoparticles, which are thought to be the source of, in some cases, the large increase of a nanofluid's specific heat capacity is criticized and a different model is proposed. The model assumes that the influence of the nanoparticles in the surrounding liquid is of long range. The attendant long-range interfacial layers may interact with each other upon increase of nanoparticle concentration. This can explain the specific heat maximum observed by different groups, for which no other theoretical explanation appears to exist. |
Mendeley readers
Geographical breakdown
Country | Count | As % |
---|---|---|
Unknown | 100 | 100% |
Demographic breakdown
Readers by professional status | Count | As % |
---|---|---|
Student > Master | 18 | 18% |
Student > Ph. D. Student | 17 | 17% |
Researcher | 9 | 9% |
Student > Bachelor | 8 | 8% |
Professor | 4 | 4% |
Other | 15 | 15% |
Unknown | 29 | 29% |
Readers by discipline | Count | As % |
---|---|---|
Engineering | 35 | 35% |
Chemical Engineering | 8 | 8% |
Energy | 7 | 7% |
Materials Science | 5 | 5% |
Chemistry | 3 | 3% |
Other | 8 | 8% |
Unknown | 34 | 34% |