An Unexplored O₂‐Involved Pathway for the Decarboxylation of Saturated Carboxylic Acids by TiO₂ Photocatalysis: An Isotopic Probe Study

Abstract: The aerobic decarboxylation of saturated carboxylic acids (from C(2) to C(5)) in water by TiO(2) photocatalysis was systematically investigated in this work. It was found that the split of C(1)-C(2) bond of the acids to release CO(2) proceeds sequentially (that is, a C(5) acid sequentially forms C(4) products, then C(3) and so forth). As a model reaction, the decarboxylation of propionic acid to produce acetic acid was tracked by using isotopic-labeled H(2)(18)O. As much as ≈42% of oxygen atoms of the produced… Show more

“…The C=O stretching of ethyl lactate was weakened (1730 cm -1 and 1667 cm -1 ), accompanying two new shoulder peaks at 1780 cm -1 and 1651 cm -1 . These bands were assigned Please do not adjust margins Please do not adjust margins to the carbonyl stretching of the α-keto group of the pyruvate, 57 supporting the experimental results (Fig. S5), the surface chemisorbed oxygen of V 2 O 5 /TiO 2 could participate in the oxidation of lactate without molecular oxygen.…”

“…[55][56] Those bands decreased in intensity with rising temperature, indicating the degradation of ethyl lactate. 57 This process was also reflected by the changes of the carbonyl and carboxyl on the V 2 O 5 /TiO 2 surface (four peaks at 1730 cm -1 ,1667 cm -1 , 1566 cm -1 and 1420 cm -1 , assigned to ν (C=O), ν (C=O•••M + ), ν s (COO) and ν as (COO) vibrations, respectively). 55,[58][59] Increasing the temperature broadens those carbonyl and carboxyl peaks, where the signals of ν s (COO) and ν as (COO) were blue shifted to 1540 cm -1 and 1445 cm -1 over 250 °C.…”

“…11). Upon increasing temperature to 150 °C, we observed the characteristic bands of α-keto in pyruvate (1795 cm -1 and 1651 cm -1 ), 57] together with a red-shifted COO stretch at 1597 cm -1 . 55,62 The in situ DRIFTS were also reflected the adsorption and dissociation of ethyl lactate on V 2 O 5 /TiO 2 surface in the presence of oxygen.…”

Understanding the oxidative dehydrogenation of ethyl lactate to ethyl pyruvate over vanadia/titania

“…The C=O stretching of ethyl lactate was weakened (1730 cm -1 and 1667 cm -1 ), accompanying two new shoulder peaks at 1780 cm -1 and 1651 cm -1 . These bands were assigned Please do not adjust margins Please do not adjust margins to the carbonyl stretching of the α-keto group of the pyruvate, 57 supporting the experimental results (Fig. S5), the surface chemisorbed oxygen of V 2 O 5 /TiO 2 could participate in the oxidation of lactate without molecular oxygen.…”

“…[55][56] Those bands decreased in intensity with rising temperature, indicating the degradation of ethyl lactate. 57 This process was also reflected by the changes of the carbonyl and carboxyl on the V 2 O 5 /TiO 2 surface (four peaks at 1730 cm -1 ,1667 cm -1 , 1566 cm -1 and 1420 cm -1 , assigned to ν (C=O), ν (C=O•••M + ), ν s (COO) and ν as (COO) vibrations, respectively). 55,[58][59] Increasing the temperature broadens those carbonyl and carboxyl peaks, where the signals of ν s (COO) and ν as (COO) were blue shifted to 1540 cm -1 and 1445 cm -1 over 250 °C.…”

“…11). Upon increasing temperature to 150 °C, we observed the characteristic bands of α-keto in pyruvate (1795 cm -1 and 1651 cm -1 ), 57] together with a red-shifted COO stretch at 1597 cm -1 . 55,62 The in situ DRIFTS were also reflected the adsorption and dissociation of ethyl lactate on V 2 O 5 /TiO 2 surface in the presence of oxygen.…”

Understanding the oxidative dehydrogenation of ethyl lactate to ethyl pyruvate over vanadia/titania

“…After reaction 9, under deaerated conditions, carbon centered radicals react with photogenerated electron (reaction 10), thus preventing the formation of hydrogen [36,37], or give at a lower extent a cross termination (reaction 11):…”

In situ photodeposited nanoCu on TiO2 as a catalyst for hydrogen production under UV/visible radiation

“…To add some complication, often the net result of a primary step of a chemical reaction could be the result of both oxidative and reductive processes. For example, it was recently showed through isotopic-labeling examinations combined with DRIFTS and electrochemical experiments that, contrary to the radical Kolbe decarboxylation, the decarboxylation of saturated carboxylic acids is possible by a concerted mechanism [69]. At first step, the pristine acid is oxidized to α-keto acid by holes or (adsorbed) OH radicals without loss of carbon atoms, and then, the intermediate α-keto acid is decarboxylated to shorter-chain acid through an e CB /O 2 process, in which an oxygen atom of O 2 is selectively incorporated into product.…”

Surface-Modified Photocatalysts