Browsing by Author "Sharma, M. K."
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Item Analyzing the Effect of Lockdown on Weather Parameters Amid COVID-19 Pandemic of Mid Hill Region of Rajouri District of Jammu & Kashmir, Union Territory, India(SCIENCEDOMAIN international, 2020-09) Sharma, R.; Vikas, V.; Singh, M.; Sharma, M. K.; Panotra, N.; Sharma, C.; Kumar, D.A study was conducted in mid hill region of Rajouri district, J&K, India to analyze the impact lockdown amid covid-19 pandemic on weather parameters. Day and night temperature readings were recorded fortnightly from 1st March to 30th June 2020 from maximum and minimum thermometer, rainfall values from ordinary rain gauge, and soil temperature at different depth from soil thermometers and values were compared with data from 2017-2019 and normal. After analyzing the data statistically using “Descriptive statistics” in MS-Excel 2010, it was observed that within the period of lockdown, the change in day temperature was -6.66% from normal mean value, however night temperature was least affected as it changes 10.33% and rainfall pattern was 19.27% more from normal mean value. The average change in soil temperature in morning at 5 cm, 10 cm and 20 cm depth in lockdown was -4.65%, 3.74% and 2.65% as compared to year 2019 (1st March to 30th June) mean value and the change in soil temperature in evening at same depths was -5.14%, -11.30% and 0.3% from year 2019 (1st March to 30th June) depicting a slow change in values. With the significant sustainable pattern observed in day and soil temperature parameters and rainfall it can be concluded that lockdown might be an effective tool in reducing speed of climate change in future.Item How Plants Adapt to the Photoperiod(Sciencedomain International, 2023-04) Sharma, M. K.Plants are extremely sensitive to changes in their environment, particularly variations in photoperiod or day length. Photoperiodism refers to a plant's capacity to detect variations in day length and make use of this knowledge to control key developmental processes including flowering, growth, and dormancy. Through a process known as photoperiodism, plants can detect and react to variations in the number of daylight hours, or photoperiod. The physiological response of plants to the length of day or night is known as photoperiodism. The plant uses this physiological response to time-critical developmental events like flowering. In this essay, I will cover the current understanding of how plants respond to photoperiod and the molecular mechanisms underpinning this response. Three groups of plants' photoperiodic responses can be distinguished: short-day plants (SDPs), long-day plants (LDPs), and day-neutral plants (DNPs). Whereas LDPs bloom when the length of the day exceeds the crucial threshold, SDPs do so only when it is shorter than the critical threshold. Conversely, DNPs do not have a crucial day duration and can bloom at any day length. Many genes and biochemical processes control how a plant responds to the photoperiod. The creation and movement of the hormone florigen, which starts blooming in response to photoperiodic signals, is a crucial regulating mechanism. On the other hand, a class of photoreceptors known as phytochromes is involved in the biochemical mechanisms driving photoperiodic responses in plants. The perception of light's duration, quality, and amount is caused by phytochromes. The red-light-absorbing Pr form and the far-red-light-absorbing Pfr form are the two interconvertible states in which they can exist. The ratio of Pr to Pfr is altered by the duration of light exposure and is utilizes by plants to assess day length. Exposure to light in SDPs causes the expression of the CONSTANS (CO) gene, and the CO protein causes the expression of the FLOWERING LOCUS T (FT), a gene that encourages flowering. By exposing LDPs to light, a different gene called GI (GIGANTEA) is induced rather than CO, which is normally expressed. The FT gene's expression is encouraged by GI's interaction with the protein ZEITLUPE (ZTL), which also encourages flowering. In addition to these essential elements, several proteins and signalling pathways are also involved in photoperiodic responses in plants. For instance, to optimise the response to variations in day length, the photoperiodic pathway interacts with the circadian clock, which controls numerous physiological processes in plants. In some species, the hormone gibberellin (GA) also aids in the promotion of flowering. One essential adaptation that enables plants to synchronize their developmental processes with seasonal changes is their capacity to react to variations in day length. Phytochromes play a key role in how plants perceive the day in the complex network of proteins and signalling channels that make up the molecular mechanisms behind photoperiodic responses in plants. There is still much to learn about the diversity and complexity of the photoperiodic response across several plant groupings, even if much is known about it in particular species.