Building a cost-effective mechanochemical Raman system: improved spectral and time resolution for in situ reaction and rheology monitoring

Zgrablić, Goran; Senkić, Ana; Vidović, Noa; Užarević, Krunoslav; Čapeta, Davor; Brekalo, Ivana; Rakić, Mario (2025) Building a cost-effective mechanochemical Raman system: improved spectral and time resolution for in situ reaction and rheology monitoring. Physical Chemistry Chemical Physics, 27 (11). pp. 5909-5920. ISSN 1463-9076

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Abstract

Raman spectroscopy has become an indispensable tool for in operando monitoring in preparative mechanochemistry due to its ability to provide real-time, non-invasive insight into solid-state reactions. While commercial systems based on fiber Raman probes offer ease of use and plug-and-play deployment, their relatively low spectral resolution and lower sensitivity make them less suitable for the specific demands of mechanochemical reaction monitoring. To address these challenges and make this valuable methodology widely available, we describe a high-sensitivity free-optics Raman system, termed mcRS (mechanochemical Raman System), constructed from the ground up using affordable off-the-shelf optical components. The mcRS includes a free-space Raman probe and a custom-designed dispersive spectrometer utilising only lenses, paired with a low-cost industrial-grade CMOS camera as the detector. By fine-tuning the optics to minimise photon loss and achieving tighter spot sizes on the detector, the mcRS provides a 30% improvement in spectral resolution compared to previous in-house fiber-based systems for half of the cost and offers a five-fold reduction in price compared to commercial systems. This is accompanied by a five-fold improvement in time resolution and a novel feature, the possibility to simultaneously collect Raman data and monitor the rheology of the sample, which often plays an important role in mechanochemical reactions. We validated the mcRS performance by monitoring the reaction between ZnO and imidazole under neat grinding (NG) and liquid-assisted grinding (LAG) conditions, using ethanol as the liquid additive. The enhanced capabilities of the mcRS offer significant advancements in the in situ studies of mechanochemical processes, allowing for differentiation between two zeolitic imidazolate framework products based on subtle differences in the high-frequency modes (3100–3200 cm−1).

Item Type:	Article
Uncontrolled Keywords:	free-space-optics Raman spectrometer; IN situ monitoring, mechancohemistry; ZIF; polymorphism
Subjects:	NATURAL SCIENCES > Physics NATURAL SCIENCES > Chemistry
Divisions:	Division of Physical Chemistry
Projects:	Project title Project leader Project code Project type Važnost mehanokemijske reaktivnosti u prebiotičkoj kemijskoj evoluciji i njezin prijenos na održivu kemijsku proizvodnju s niskim emisijama-PREBIOMECHEM Krunoslav Užarević IP-2020-02-4702 HRZZ Mehanokemijske i bezotopinske strategije za sintezu funkcionalnih poroznih materijala s naprednim fizičko-kemijskim i katalitičkim svojstvima-MECHADVANCE Krunoslav Užarević PZS-2019-02-4129 HRZZ
Depositing User:	Ana Zečević
Date Deposited:	02 May 2025 08:35
URI:	http://fulir.irb.hr/id/eprint/9795
DOI:	10.1039/d4cp04757e

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