Combined Calorimeter and Spectrophotometer for Observing Biological Reactions

A stopped-flow fast reaction apparatus is described which permits chemical reactions with rate constants of 50 sec−1, or less, to be followed both spectrophotometrically and calorimetrically. The thermal detector is a single copper-constantan thermocouple, 5μ thick, with a response time of 3 msec. U...

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Published in:Review of Scientific Instruments
Main Authors: Berger, Robert L., Stoddart, L. Charles
Format: Article in Journal/Newspaper
Language:English
Published: AIP Publishing 1965
Subjects:
Instrumentation
Carbonic acid
Online Access:http://dx.doi.org/10.1063/1.1719332
https://pubs.aip.org/aip/rsi/article-pdf/36/1/78/11106081/78_1_online.pdf
id craippubl:10.1063/1.1719332
record_format openpolar
spelling craippubl:10.1063/1.1719332 2024-02-11T10:02:52+01:00 Combined Calorimeter and Spectrophotometer for Observing Biological Reactions Berger, Robert L. Stoddart, L. Charles 1965 http://dx.doi.org/10.1063/1.1719332 https://pubs.aip.org/aip/rsi/article-pdf/36/1/78/11106081/78_1_online.pdf en eng AIP Publishing Review of Scientific Instruments volume 36, issue 1, page 78-84 ISSN 0034-6748 1089-7623 Instrumentation journal-article 1965 craippubl https://doi.org/10.1063/1.1719332 2024-01-26T09:40:46Z A stopped-flow fast reaction apparatus is described which permits chemical reactions with rate constants of 50 sec−1, or less, to be followed both spectrophotometrically and calorimetrically. The thermal detector is a single copper-constantan thermocouple, 5μ thick, with a response time of 3 msec. Using a bandpass of 0 to 80 cps, the signal-to-noise ratio is 1:1 for a heat change of 100 μcal/ml. The apparatus is housed in a 30×30-cm aluminum cylinder which is temperature stable to ±0.00001°C; reactants can be brought to within 0.001°C of equilibrium in less than 1 h. Acrylic light pipes are employed in the optical detection system to conduct a monochromatic light beam to the observation tube and to conduct the transmitted light to a photomultiplier. Solenoid valves control the mixer inputs; a third solenoid valve stops the flow in 2 msec. The thermal system and calorimeter were analyzed mathematically and two computer programs developed which make corrections for the response time of the system, correct the data for heat diffusion from the observation tube during the reaction, and calculate the first-order rate constant. The dehydration of carbonic acid was used as a test reaction. Experiments run at 3.8, 18, 24.1, and 36.9°C, using 0.04 molar NaHCO3 and 0.02 M HCl gave results thermally of 3.12, 15.8, 22.7, 49 sec−1 and optically of 3.15, 15.1, 20.6, for the rate constant and 2100, 1413, 970, and 460 cal/mole for ΔH. Article in Journal/Newspaper Carbonic acid AIP Publishing Review of Scientific Instruments 36 1 78 84
institution Open Polar
collection AIP Publishing
op_collection_id craippubl
language English
topic Instrumentation
spellingShingle Instrumentation
Berger, Robert L.
Stoddart, L. Charles
Combined Calorimeter and Spectrophotometer for Observing Biological Reactions
topic_facet Instrumentation
description A stopped-flow fast reaction apparatus is described which permits chemical reactions with rate constants of 50 sec−1, or less, to be followed both spectrophotometrically and calorimetrically. The thermal detector is a single copper-constantan thermocouple, 5μ thick, with a response time of 3 msec. Using a bandpass of 0 to 80 cps, the signal-to-noise ratio is 1:1 for a heat change of 100 μcal/ml. The apparatus is housed in a 30×30-cm aluminum cylinder which is temperature stable to ±0.00001°C; reactants can be brought to within 0.001°C of equilibrium in less than 1 h. Acrylic light pipes are employed in the optical detection system to conduct a monochromatic light beam to the observation tube and to conduct the transmitted light to a photomultiplier. Solenoid valves control the mixer inputs; a third solenoid valve stops the flow in 2 msec. The thermal system and calorimeter were analyzed mathematically and two computer programs developed which make corrections for the response time of the system, correct the data for heat diffusion from the observation tube during the reaction, and calculate the first-order rate constant. The dehydration of carbonic acid was used as a test reaction. Experiments run at 3.8, 18, 24.1, and 36.9°C, using 0.04 molar NaHCO3 and 0.02 M HCl gave results thermally of 3.12, 15.8, 22.7, 49 sec−1 and optically of 3.15, 15.1, 20.6, for the rate constant and 2100, 1413, 970, and 460 cal/mole for ΔH.
format Article in Journal/Newspaper
author Berger, Robert L.
Stoddart, L. Charles
author_facet Berger, Robert L.
Stoddart, L. Charles
author_sort Berger, Robert L.
title Combined Calorimeter and Spectrophotometer for Observing Biological Reactions
title_short Combined Calorimeter and Spectrophotometer for Observing Biological Reactions
title_full Combined Calorimeter and Spectrophotometer for Observing Biological Reactions
title_fullStr Combined Calorimeter and Spectrophotometer for Observing Biological Reactions
title_full_unstemmed Combined Calorimeter and Spectrophotometer for Observing Biological Reactions
title_sort combined calorimeter and spectrophotometer for observing biological reactions
publisher AIP Publishing
publishDate 1965
url http://dx.doi.org/10.1063/1.1719332
https://pubs.aip.org/aip/rsi/article-pdf/36/1/78/11106081/78_1_online.pdf
genre Carbonic acid
genre_facet Carbonic acid
op_source Review of Scientific Instruments
volume 36, issue 1, page 78-84
ISSN 0034-6748 1089-7623
op_doi https://doi.org/10.1063/1.1719332
container_title Review of Scientific Instruments
container_volume 36
container_issue 1
container_start_page 78
op_container_end_page 84
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