Mechanistic Understanding of Polarization‐Type Potential‐Induced Degradation in Crystalline‐Silicon Photovoltaic Cell Modules

Yamaguchi, Seira; Masuda, Atsushi; Marumoto, Kazuhiro; Ohdaira, Keisuke

doi:10.1002/aesr.202200167

Cited by 3 publications

(5 citation statements)

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“…J sc and V oc decrease simultaneously in the first 120 s. This is typical behavior of the first-stage PID, PID-p, in n-FE c-Si PV modules, due to the accumulation of positive charges in SiN x and the resulting acceleration of surface recombination. 22,23,30) The modules then show different type of PID characterized by a reduction in FF alone after the PID test for 12 h. Note that the degradation of FF is not by the formation of shunting paths but by the increase in recombination current, current through the carrier recombination in the depletion layer of a p + -n junction, as confirmed in the negative bias region of Fig. 1.…”

Section: Resultsmentioning

confidence: 62%

“…The voltage-independent saturated J sc and V oc values originate from the existence of the upper limit of positive charges, in which all the K center are converted to K + centers. 22,23,30) The third-stage PID, V oc and FF reductions due to the formation of Na-based domes, is seen after the PID test at voltages of −1000 and −600 V for ∼10 2 h. The duration needed for the emergence of the third-stage PID and its degree depend on applied voltage, and the degradations are not clearly seen in the case of PID tests at voltages of −200 and −50 V. The formation of the Na-based domes requires a quantity of Na ions, and the Na ions may come from the cover glass of the modules. The voltage dependence of the third-stage PID is reasonable because more Na ions may reach the cells at higher voltage, while the domes may not be formed if the amount of Na is insufficient in the case of lower voltage.…”

Section: Resultsmentioning

confidence: 99%

“…[5][6][7][8][9][10][11][12] On the other hand, detailed studies on the PID for the n-type c-Si PV modules are insufficient and need to be investigated furthermore. [13][14][15][16][17][18][19] We have thus far investigated the PID of n-type c-Si PV modules 20) with cells such as rear-emitter, 21) front-emitter (FE), [22][23][24][25][26][27][28][29][30][31] interdigitated back-contact, 32) and Si heterojunction structures. [33][34][35][36][37] Of those, n-type FE (n-FE) c-Si PV modules have been investigated in the most detail.…”

Section: Introductionmentioning

confidence: 99%

“…18) In the n-FE c-Si PV modules, positive fixed charges are accumulated in the surface SiN x by extracting electrons from K centers by a negative bias stress. 22,23,30) This accelerates the recombination of minority carriers, electrons, on the surface of the p + emitter, resulting in simultaneous reductions in short-circuit current density (J sc ) and open-circuit voltage (V oc ). The second-stage PID of n-FE c-Si PV modules is characterized by a reduction in fill factor (FF) alone.…”

Section: Introductionmentioning

confidence: 99%

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Second-stage potential-induced degradation of n-type front-emitter crystalline silicon photovoltaic modules and its recovery

Ohdaira

Komatsu

Yamaguchi

et al. 2023

Jpn. J. Appl. Phys.

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We investigate the second-stage potential-induced degradation (PID) of n-type front-emitter (n-FE) crystalline silicon (c-Si) photovoltaic (PV) modules. The PID of n-FE c-Si PV modules is known to occur in three stages under negative bias stress. The second-stage PID is characterized by a reduction in fill factor (FF), due to the invasion of sodium (Na) into the depletion region of a p+–n junction and resulting increase in recombination current. The second-stage PID shows a curious independence on a negative bias voltage for the PID stress. This may indicate that the Na inducing the FF reduction comes not from the cover glass but originally exists on and/or near the cell surface. The FF reduction is recovered quite rapidly, within a few seconds, by applying a positive bias to the degraded cell. The recovered n-FE c-Si PV modules show more rapid degradation if they receive the negative bias stress again, which can be explained by Na remaining in the p+ emitter.

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Section: Resultsmentioning

confidence: 62%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Second-stage potential-induced degradation of n-type front-emitter crystalline silicon photovoltaic modules and its recovery

Ohdaira

Komatsu

Yamaguchi

et al. 2023

Jpn. J. Appl. Phys.

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“…We have previously proposed that the origin of the charges in SiN x is K centers. 14,20,26) K centers are Si dangling bonds backbonded to three N atoms in SiN x and can be negativelycharged (K − ), neutral (K 0 ), and positively-charged (K + ) by extracting or adding electrons. [27][28][29] By the PID stress, i.e.…”

Section: Effect Of Short-duration Prior Reverse Bias Applicationmentioning

confidence: 99%

Delay of the potential-induced degradation of n-type crystalline silicon photovoltaic modules by the prior application of reverse bias

Wu,

Tu,

Ohdaira

2023

Jpn. J. Appl. Phys.

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We investigated the influence of the pre-application of reverse bias on the potential-induced degradation (PID) of n-type front-emitter (n-FE) crystalline Si (c-Si) photovoltaic modules. Applying a prior positive reverse bias to n-FE cells delays charge-accumulation-type PID (PID-1), decreases in short-circuit current density (Jsc) and open-circuit voltage (Voc). The prior positive bias accumulation may accumulate negative charges in the SiNx, which leads to an increase in a duration for the positive charge accumulation by the PID test applying a negative bias. We also found that sufficiently long prior positive bias application results in the delay of PID-2, a fill factor (FF) reduction by the incursion of Na ions into the depletion region of the p–n junction of n-FE cells.

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A Review of Photovoltaic Module Failure and Degradation Mechanisms: Causes and Detection Techniques

Al Mahdi,

Leahy,

Alghoul

et al. 2024

Solar

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With the global increase in the deployment of photovoltaic (PV) modules in recent years, the need to explore and understand their reported failure mechanisms has become crucial. Despite PV modules being considered reliable devices, failures and extreme degradations often occur. Some degradations and failures within the normal range may be minor and not cause significant harm. Others may initially be mild but can rapidly deteriorate, leading to catastrophic accidents, particularly in harsh environments. This paper conducts a state-of-the-art literature review to examine PV failures, their types, and their root causes based on the components of PV modules (from protective glass to junction box). It outlines the hazardous consequences arising from PV module failures and describes the potential damage they can bring to the PV system. The literature reveals that each component is susceptible to specific types of failure, with some components deteriorating on their own and others impacting additional PV components, leading to more severe failures. Finally, this review briefly summarises PV failure detection techniques, emphasising the significance of electrical characterisation techniques and underlining the importance of considering more electrical parameters. Most importantly, this review identifies the most prevalent degradation processes, laying the foundation for further investigation by the PV research community through modelling and experimental studies. This allows for early detection by comparing PV performance when failures or degradation occur to prevent serious progression. It is worth noting that most of the studies included in this review primarily focus on detailing failures and degradation observed in PV operations, which can be attributed to various factors, including the manufacturing process and other external influences. Hence, they provide explanations of these failure mechanisms and causes but do not extensively explore corrective actions or propose solutions based on either laboratory experiments or real-world experience. Although, within this field of study, there are corresponding studies that have designed experiments to suggest preventive measures and potential solutions, an in-depth review of those studies is beyond the scope of this paper. However, this paper, in turn, serves as a valuable resource for scholars by confining PV failures to critically evaluate available studies for preventative measures and corrective actions.

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Mechanistic Understanding of Polarization‐Type Potential‐Induced Degradation in Crystalline‐Silicon Photovoltaic Cell Modules

Cited by 3 publications

References 51 publications

Second-stage potential-induced degradation of n-type front-emitter crystalline silicon photovoltaic modules and its recovery

Second-stage potential-induced degradation of n-type front-emitter crystalline silicon photovoltaic modules and its recovery

Delay of the potential-induced degradation of n-type crystalline silicon photovoltaic modules by the prior application of reverse bias

A Review of Photovoltaic Module Failure and Degradation Mechanisms: Causes and Detection Techniques

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