Maciej A Zwieniecki
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Explore the profile of Maciej A Zwieniecki including associated specialties, affiliations and a list of published articles.
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82
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1282
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Recent Articles
1.
Orozco J, Guzman-Delgado P, Zwieniecki M
Nat Plants
. 2024 Oct;
10(11):1635-1642.
PMID: 39358455
The global incidence of megafires is on the rise, leading to extensive areas being shrouded in dense smoke for prolonged periods, spanning days or weeks. Here, by integrating long-term regional...
2.
Orozco J, Lauterman O, Sperling O, Paz-Kagan T, Zwieniecki M
Sci Rep
. 2024 Jan;
14(1):636.
PMID: 38182702
Climate change is expected to impact the spring phenology of perennial trees, potentially altering the suitability of land for their cultivation. In this study, we investigate the effects of climate...
3.
Marino G, Guzman-Delgado P, Santos E, Adaskaveg J, Blanco-Ulate B, Ferguson L, et al.
Front Plant Sci
. 2023 Aug;
14:1194177.
PMID: 37600173
Tree source-sink ratio has a predominant and complex impact on tree performance and can affect multiple physiological processes including vegetative and reproductive growth, water and nutrient use, photosynthesis, and productivity....
4.
Chin A, Guzman-Delgado P, Kerhoulas L, Zwieniecki M
Tree Physiol
. 2022 Oct;
43(3):418-429.
PMID: 36222161
Absorption of water across the surfaces of leaves is an ecologically important aspect of tree physiology. Variation in foliar water uptake capacity depends on environmental conditions when traits associated with...
5.
Chin A, Guzman-Delgado P, Sillett S, Kerhoulas L, Ambrose A, McElrone A, et al.
Plant Cell Environ
. 2022 Jun;
45(9):2607-2616.
PMID: 35736139
Tracheid buckling may protect leaves in the dynamic environments of forest canopies, where rapid intensifications of evaporative demand, such as those brought on by changes in light availability, can result...
6.
Zwieniecki M, Davidson A, Orozco J, Cooper K, Guzman-Delgado P
Sci Rep
. 2022 Mar;
12(1):4360.
PMID: 35288613
Successful yield in orchards is the culmination of a series of events that start with plants entering dormancy with adequate energy reserves (non-structural carbohydrates; NSC). These NSC are responsible for...
7.
Chin A, Guzman-Delgado P, Sillett S, Orozco J, Kramer R, Kerhoulas L, et al.
Am J Bot
. 2022 Mar;
109(4):564-579.
PMID: 35274309
Premise: Trees in wet forests often have features that prevent water films from covering stomata and inhibiting gas exchange, while many trees in drier environments use foliar water uptake to...
8.
Amico Roxas A, Orozco J, Guzman-Delgado P, Zwieniecki M
Tree Physiol
. 2021 Aug;
41(8):1425-1438.
PMID: 34383074
Deciduous trees mostly rely on non-structural carbohydrates (NSC-soluble carbohydrates and starch) stored prior to dormancy to sustain both spring bloom and the initial phase of spring growth prior to the...
9.
Sperling O, Zwieniecki M
Tree Physiol
. 2021 Apr;
41(10):1906-1917.
PMID: 33847365
Variable winter temperatures cause a year-to-year discrepancy in the phenology of deciduous trees. This implies that an intrinsic 'winter clock' synchronizes bloom with the progression of winter to spring. The...
10.
Guzman-Delgado P, Laca E, Zwieniecki M
Plant Cell Environ
. 2021 Mar;
44(6):1728-1740.
PMID: 33665817
Plants can absorb water through their leaf surfaces, a phenomenon commonly referred to as foliar water uptake (FWU). Despite the physiological importance of FWU, the pathways and mechanisms underlying the...