INVESTIGADORES
BIERBRAUER Karina Lilian
artículos
Título:
New Route to the Synthesis of Difluorodioxirane from FC(O)OF
Autor/es:
KARINA L. BIERBRAUER; JORGE CODNIA; MARIA L. AZCARATE; GUSTAVO A. ARGÜELLO
Revista:
Inorganic Chemistry
Editorial:
ACS publications
Referencias:
Año: 2001 vol. 40 p. 2922 - 2924
Resumen:
Fluoroformyl hypofluorite has long been considered an
unstable molecule1 because the impurities present in the products
during synthesis were responsible for its decomposition. Even
though FC(O)OF is well-characterized spectroscopically, its
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
though FC(O)OF is well-characterized spectroscopically, its
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
during synthesis were responsible for its decomposition. Even
though FC(O)OF is well-characterized spectroscopically, its
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
though FC(O)OF is well-characterized spectroscopically, its
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
1 because the impurities present in the products
during synthesis were responsible for its decomposition. Even
though FC(O)OF is well-characterized spectroscopically, its
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
though FC(O)OF is well-characterized spectroscopically, its
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
Even
though FC(O)OF is well-characterized spectroscopically, its
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
its
photochemical study deserves special interest. Studies on
infrared multiphoton (IRMP) excitation using a pulsed CO2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
2 laser
have been undertaken in this paper. The results obtained show
that the main reaction path goes through a heterogeneous
reaction whose ultimate fate is the catalytic isomerization of
FC(O)OF to F2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.
in the probable formation of O3 by CF2 in the stratosphere.
2CO2, a stable isomer proposed as an intermediate
in the probable formation of O3 by CF2 in the stratosphere.3 by CF2 in the stratosphere.
Difluorodioxirane is the only known dioxirane that may be
isolated as a pure substance and that may be thermally stabilized
in the gas phase at room temperature. It