Cavity-enhanced direct frequency comb spectroscopy

Cavity-enhanced direct frequency comb spectroscopy combines broad spectral bandwidth, high spectral resolution, precise frequency calibration, and ultrahigh detection sensitivity, all in one experimental platform based on an optical frequency comb interacting with a high-finesse optical cavity. Precise control of the optical frequency comb allows highly efficient, coherent coupling of individual comb components with corresponding resonant modes of the high-finesse cavity. The long cavity lifetime dramatically enhances the effective interaction between the light field and intracavity matter, increasing the sensitivity for measurement of optical losses by a factor that is on the order of the cavity finesse. The use of low-dispersion mirrors permits almost the entire spectral bandwidth of the frequency comb to be employed for detection, covering a range of ~10% of the actual optical frequency. The light transmitted from the cavity is spectrally resolved to provide a multitude of detection channels with spectral resolutions ranging from a several gigahertz to hundreds of kilohertz. In this review we will discuss the principle of cavity-enhanced direct frequency comb spectroscopy and the various implementations of such systems. In particular, we discuss several types of UV, optical, and IR frequency comb sources and optical cavity designs that can be used for specific spectroscopic applications. We present several cavity-comb coupling methods to take advantage of the broad spectral bandwidth and narrow spectral components of a frequency comb. Finally, we present a series of experimental measurements on trace gas detections, human breath analysis, and characterization of cold molecular beams.Comment: 36 pages, 27 figure

Perfil de ácidos graxos do leite de vacas alimentadas com óleo de soja e monensina no início da lactação Milk fatty acid profile of cows fed monensin and soybean oil in early lactation

Avaliaram-se os efeitos da adição de monensina sódica combinada com óleo de soja na dieta de vacas lactantes sobre o perfil de ácidos graxos (AG) do leite na 5ª e 15ª semanas da lactação. Foram utilizadas 16 vacas multíparas cruzadas, dispostas em delineamento em blocos casualizados, em um arranjo fatorial 2 x 2 (presença ou não de monensina e presença ou não de óleo de soja). Os tratamentos consistiram das dietas: CT (controle) = sem monensina ou óleo; MN = 33 ppm de monensina; OL = 3,9% de óleo de soja; e OM = óleo e monensina. Os animais foram confinados e alimentados com 52% de silagem de milho e 48% de concentrado. Não foi verificada interação entre óleo de soja e monensina para os ácidos graxos avaliados. A monensina aumentou os AG insaturados, monoinsaturados e poliinsaturados em 9,0; 8,8; e 10,7%, respectivamente. O óleo apresentou maior impacto sobre os AG poliinsaturados, aumentando-os em 39,2; 39,3; e 24,2%, respectivamente. Também reduziu os AG de cadeias curta (43,7%) e média (49,1%) e aumentou os AG de cadeia longa (55,3%). Os isômeros trans-C18:1 foram aumentados tanto pelo óleo como pela monensina, indicando efeito aditivo para trans-10 C18:1, que foi negativamente correlacionado ao teor de gordura do leite. O isômero cis-9 trans-11 do ácido linoléico conjugado (CLA) não foi influenciado pelos tratamentos, observando-se que o óleo reduziu a atividade da delta9-desaturase. Houve interação entre tratamentos e semana da lactação sobre os AG de cadeias curta e média, C14:0, C16:0, cis-9 C18:1 e trans-10 C18:1. Os maiores efeitos sobre o perfil de AG do leite foram registrados quando monensina e óleo foram fornecidos em conjunto na dieta de vacas lactantes.<br>The objective of this trial was to evaluate the effects of dietary monensin and soybean oil on milk fatty acid (FA) profile in the 5th and 15th week of lactation of dairy cows. Sixteen multiparous crossbred dairy cows averaging 30 days in milk were assigned to a completely randomized block design in a 2 x 2 factorial arrangement (presence or absence of monensin and soybean oil). The following diets were used: control not supplemented with monensin or soybean oil (CT), 33 ppm of monensin (MN), 3.9% of soybean oil (OL) or a combination of soybean oil plus monensin (OM). Cows were confined and fed diets with 52% of corn silage and 48% of concentrate. No significant interaction between soybean oil and monensin was observed for any measured FA. Monensin increased unsaturated, monounsaturated, and polyunsaturated FA by 9.0, 8.8 and 10.7%, respectively, while supplementation with soybean oil resulted in greater responses: 39.2, 39.3, and 24.2% for the same FA. Soybean oil also reduced short chain FA (43.7%) and medium chain FA (49.1%) and increased long chain FA (55.3%) in this study. The isomers trans-C18:1 were increased by inclusion of oil and monensin in the diet indicating an additive effect for trans-10 C18:1 that was negatively correlated with milk fat content. The CLA isomer cis-9 trans-11 C18:2 was not affected by treatments but soybean oil reduced delta9-desaturase activity. There were interactions between treatment and week of lactation for short and medium chain FA, C14:0, C16:0, cis-9 C18:1 and trans-10. The combination of monensin and soybean oil in diet of lactating dairy cows was responsible for the most significant changes observed in the profile of milk FA